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Thyristor Product Catalog
Teccor Electronics 1800 Hurd Drive Irving, Texas 75038 United States of America Phone: +1 972-580-7777 Fax: +1 972-550-1309 Website: http://www.teccor.com E-mail: power.techsales@teccor.com
(c)2002 Teccor Electronics Thyristor Product Catalog
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Teccor Electronics reserves the right to make changes at any time in order to improve designs and to supply the best products possible. The information in this catalog has been carefully checked and is believed to be accurate and reliable; however, no liability of any type shall be incurred by Teccor for the use of the circuits or devices described in this publication. Furthermore, no license of any patent rights is implied or given to any purchaser. Teccor Electronics is the proprietor of the QUADRAC(R) trademark. is a registered trademark of Underwriters Laboratories, Inc. All other brand names may be trademarks of their respective companies. To conserve space in this catalog, the trademark sign ((R)) is omitted.
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Contents
Product Selection Guide Product Descriptions - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - vi Circuit Requirement Diagram - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - vii Product Packages - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - viii Description of Part Numbers- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - x Quality and Reliability Assurance - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - xii Standard Terms and Conditions - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - xiv Data Sheets V-I Characteristics of Thyristor Devices - - - - - - - - - - - - - - - - - - - - - - - - E0-2 Electrical Parameter Terminology - - - - - - - - - - - - - - - - - - - - - - - - - - - - E0-3 Electrical Specifications Sensitive Triacs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - E1 Triacs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - E2 QUADRACs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - E3 Alternistor Triacs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - E4 Sensitive SCRs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - E5 SCRs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - E6 Rectifiers - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - E7 Diacs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - E8 SIDAC - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - E9 Mechanical Specifications Package Dimensions - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - M1 Lead Form Dimensions - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - M2 Packing Options - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - M3 Application Notes Fundamental Characteristics of Thyristors - - - - - - - - - - - - - - - - - - - AN1001 Gating, Latching, and Holding of SCRs and Triacs - - - - - - - - - - - - - AN1002 Phase Control Using Thyristors- - - - - - - - - - - - - - - - - - - - - - - - - - - AN1003 Mounting and Handling of Semiconductor Devices - - - - - - - - - - - - - AN1004 Surface Mount Soldering Recommendations - - - - - - - - - - - - - - - - - AN1005 Testing Teccor Semiconductor Devices Using Curve Tracers - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - AN1006 Thyristors Used As AC Static Switches and Relays - - - - - - - - - - - - AN1007 Explanation of Maximum Ratings and Characteristics for Thyristors - AN1008 Miscellaneous Design Tips and Facts - - - - - - - - - - - - - - - - - - - - - - AN1009 Thyristors for Ignition of Fluorescent Lamps - - - - - - - - - - - - - - - - - - AN1010 Appendix Cross Reference Guide - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - A1 Part Numbers Index- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - A27
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(c)2002 Teccor Electronics Thyristor Product Catalog
Product Selection Guide
Product Descriptions - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - P 2 Circuit Requirement Diagram - - - - - - - - - - - - - - - - - - - - - - - - - - - - - P 3 Product Packages - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - P 4 Description of Part Numbers - - - - - - - - - - - - - - - - - - - - - - - - - - - - - P 6 Quality and Reliability Assurance - - - - - - - - - - - - - - - - - - - - - - - - - P 8 Standard Terms and Conditions - - - - - - - - - - - - - - - - - - - - - - - - - P 10
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Product Descriptions
Thyristors
A thyristor is any semiconductor switch with a bi-stable action depending on p-n-p-n regenerative feedback. Thyristors are normally two- or three-terminal devices for either unidirectional or bidirectional circuit configurations. Thyristors can have many forms, but they have certain commonalities. All thyristors are solid state switches that are normally open circuits (very high impedance), capable of withstanding rated blocking/off-state voltage until triggered to on state. When triggered to on state, thyristors become a low-impedance current path until principle current either stops or drops below a minimum holding level. After a thyristor is triggered to on-state condition, the trigger current can be removed without turning off the device. Thyristors are used to control the flow of electrical currents in applications including: * Home appliances (lighting, heating, temperature control, alarm activation, fan speed) * Electrical tools (for controlled actions such as motor speed, stapling event, battery charging) * Outdoor equipment (water sprinklers, gas engine ignition, electronic displays, area lighting, sports equipment, physical fitness)
Sensitive SCRs
Teccor's sensitive gate SCRs are silicon-controlled rectifiers representing the best in design, performance, and packaging techniques for low- and medium-current applications. Anode currents of 0.8 A to 10 A rms can be controlled by sensitive gate SCRs with gate drive currents ranging from 12 A to 500 A. Sensitive gate SCRs are ideally suited for interfacing to integrated circuits or in applications where high current load requirements and limited gate drive current capabilities exist. Examples include ignition circuits, motor controls, and DC latching for alarms in smoke detectors. Sensitive gate SCRs are available in voltage ratings to 600 V ac.
SCRs
Teccor's SCR products are half-wave, silicon-controlled rectifiers that represent the state of the art in design and performance. Load current capabilities range from 1 A to 70 A rms, and voltages from 200 V to 1000 V may be specified to meet a variety of application needs. Because of its unidirectional switching capability, the SCR is used in circuits where high surge currents or latching action is required. It may also be used for half-wave-type circuits where gate-controlled rectification action is required. Applications include crowbars in power supplies, camera flash units, smoke alarms, motor controls, battery chargers, and engine ignition. Surge current ratings are available from 30 A in the TO-92 packaging to 950 A in the TO-218X package.
Sensitive Triacs
Teccor's sensitive gate triacs are AC bidirectional silicon switches that provide guaranteed gate trigger current levels in Quadrants I, II, III, and IV. Interfacing to microprocessors or other equipment with single polarity gate triggering is made possible with sensitive gate triacs. Gate triggering currents of 3 mA, 5 mA, 10 mA, or 20 mA may be specified. Sensitive gate triacs are capable of controlling AC load currents from 0.8 A to 8 A rms and can withstand operating voltages from 200 V to 600 V.
Rectifiers
Teccor manufactures 15 A to 25 A rms rectifiers with voltages rated from 200 V to 1000 V. Due to the electrically isolated TO-220 package, these rectifiers may be used in common anode or common cathode circuits using only one part type, thereby simplifying stock requirements.
Triacs
Teccor's triac products are bidirectional AC switches, capable of controlling loads from 0.8 A to 35 A rms with 10 mA, 25 mA, and 50 mA IGT in operating Quadrants I, II and III. Triacs are useful in full-wave AC applications to control AC power either through full-cycle switching or phase control of current to the load element. These triacs are rated to block voltage in the "OFF" condition from 200 V minimum with selected products capable of 1000 V operation. Typical applications include motor speed controls, heater controls, and incandescent light controls.
Diacs
Diacs are trigger devices used in phase control circuits to provide gate pulses to a triac or SCR. They are voltage-triggered bidirectional silicon devices housed in DO-35 glass axial lead packages and DO-214 surface mount packages. Diac voltage selections from 27 V to 45 V provide trigger pulses closely matched in symmetry at the positive and negative breakover points to minimize DC component in the load circuit. Some applications include gate triggers for light controls, dimmers, power pulse circuits, voltage references in AC power circuits, and triac triggers in motor speed controls.
Quadrac
Quadrac devices, originally developed by Teccor, are triacs and alternistor triacs with a diac trigger mounted inside the same package. These devices save the user the expense and assembly time of buying a discrete diac and assembling in conjunction with a gated triac. The Quadrac is offered in capacities from 4 A to 15 A rms and voltages from 200 V ac to 600 V ac.
Sidacs
Sidacs represent a unique set of thyristor qualities. The sidac is a bidirectional voltage triggered switch. Some characteristics of this device include a normal 95 V to 330 V switching point, negative resistance range, latching characteristics at turn-on, and a low onstate voltage drop. One-cycle surge current capability up to 20 A makes the sidac an ideal product for dumping charged capacitors through an inductor in order to generate high-voltage pulses. Applications include light controls, high-pressure sodium lamp starters, power oscillators, and high-voltage power supplies.
Alternistor Triacs
The Teccor alternistor is specifically designed for applications required to switch highly inductive loads. The design of this special chip effectively offers the same performance as two thyristors (SCRs) wired inverse parallel (back-to-back). This new chip construction provides the equivalent of two electrically-separate SCR structures, providing enhanced dv/dt characteristics while retaining the advantages of a single-chip device. Teccor manufactures 6 A to 40 A alternistors with blocking voltage rating from 200 V to 1000 V. Alternistors are offered in TO-220, TO-218, and TO-218X packages with isolated and non-isolated versions. http://www.teccor.com P-2 +1 972-580-7777
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Circuit Requirement Diagram
BILATERAL VOLTAGE SWITCH RECTIFIER REVERSE BLOCKING THYRISTOR BIDIRECTIONAL THYRISTOR BILATERAL VOLTAGE TRIGGER
SIDAC *
RECTIFIER *
DIAC *
GATE CURRENT 12-500 A 10-50 mA
GATE CONTROL DIAC TRIGGER DIRECT
OPTIONS SCR (Sensitive) * SCR * INTERNAL EXTERNAL
QUADRANT OPERATION (See Quadrant Chart on Data Sheet) I II III I II III IV
DIACS * QUADRAC *
GATE CURRENT 10-100 mA
GATE CURRENT 3-20 mA
ALTERNISTOR TRIAC * * For detailed information, see specific data sheet in product catalog.
TRIAC *
SENSITIVE TRIAC *
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Product Packages
Isolated Mounting Tab Package Code
G Y S C E L K J P
Product Type Sensitive Triac
Current (Amps)
0.8 1 4 6 8 0.8 1 4 6 8 10 15 25 35 4 6 8 10 15 6 8 10 12 16 25 30 35 40 0.8 1.5 4 6 8 10 1 6 8 10 12 15 16 20 25 35 40 55 65 70 15 20 25
DO-15
DO-35
DO-214
Compak

TO-92 *

TO-220
TO-218
TO-218X
TO-3 Fastpak

Triac
Quadrac
Alternistor

Sensitive SCR
SCR
*
Rectifier Diac Sidac
* No center lead on TO-92 Sidacs.
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Product Packages
Non-isolated Mounting Tab
F R M W D V N
Package Code
TO-202
TO-220
TO-218
TO-218X
TO-252 D-Pak
TO-251 V-Pak
TO-263 D2Pak
Current (Amps)
0.8 1 4 6 8 0.8 1 4 6 8 10 15 25 35 4 6 8 10 15 6 8 10 12 16 25 30 35 40 0.8 1.5 4 6 8 10 1 6 8 10 12 15 16 20 25 35 40 55 65 70 15 20 25
Product Type Sensitive Triac

Triac
Quadrac

Alternistor

Sensitive SCR

SCR

Rectifier Diac Sidac
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Description of Part Numbers
Sensitive Triac
L
Device Type L = Sensitive Triac Voltage Rating 20 = 200 V 40 = 400 V 60 = 600 V Current Rating X8 = 0.8 A N=1A 01 = 1 A 04 = 4 A 06 = 6 A 08 = 8 A Package Type Blank = Compak (Surface Mount) D = TO-252 (Surface Mount) E = TO-92 (Isolated) F = TO-202 (Non-islolated) L = TO-220 (Isolated) V = TO-251 (Non-islolated)
Triac and Alternistor
04 F 5 12 X
Special Options V = 4000 V Isolation (TO-220 Package Only) Lead Form Dimensions TO-202 TO-220 TO-92 Gate Variations 3 = 3 mA (Q I, II, III, IV) 5 = 5 mA (Q I, II, III, IV) 6 = 5 mA (Q I, II, III) 6 = 10 mA (Q IV) 8 = 10 mA (Q I, II, III) 8 = 20 mA (Q IV)
20
Q
Device Type Q = Triac or Alternistor Voltage Rating 20 = 200 V 40 = 400 V 60 = 600 V 80 = 800 V K0 = 1000 V Current Rating X8 = 0.8 A 01 = 1 A 04 = 4 A 06 = 6 A 08 = 8 A 10 = 10 A 12 = 12 A 15 = 15 A 25 = 25 A 30 = 30 A 35 = 35 A 40 = 40 A
20
04
F
3
1
X
Special Options V = 4000 V Isolation (TO-220 Package Only) Lead Form Dimensions TO-202 TO-220 TO-92 TO-218X TO-218
Gate Variation DH3 and VH3 = 10mA (Q I, II, III) 3 = 10 mA (Q I, II, III) H3 = 20mA (Q I, II, III) 4 = 25 mA (Q I, II, III) H4 = 35 mA (Q I, II, III) * 5 = 50 mA (Q I, II, III) H5 = 50 mA (Q I, II, III) * 6 = 80 mA (Q I, II, III) * 7 = 100 mA (Q I, II, III) * * NOTE: Alternistor device; no Quadrant IV operation
Quadrac
Q
Device Type Q = Quadrac Voltage Rating 20 = 200 V 40 = 400 V 60 = 600 V Current Rating 04 = 4 A 06 = 6 A 08 = 8 A 10 = 10 A 15 = 15 A
20
04
L
T
H
52
X
Special Options V = 4000 V Isolation (TO-220 Package Only) Lead Form Dimensions TO-220 Alternistor Gate Variation T = Internal Diac Trigger Package Type L = TO-220 (Isolated)
Package Type D = TO-252 (Surface Mount) E = TO-92 (Isolated) F = TO-202 (Non-isolated) J = TO-218X (Isolated) K = TO-218 (Isolated) L = TO-220 (Isolated) N = TO-263 (Surface Mount) P = Fastpak (Isolated) R = TO-220 (Non-isolated) V = TO-251 (Non-isolated) W = TO-218X (Non-isolated)
Sensitive SCR
S
Device Type S = Sensitive SCR Voltage Rating 20 = 200 V 40 = 400 V 60 = 600 V Current Rating X8 = 0.8 A N=1A 06 = 6 A 08 = 8 A 10 = 10 A
20
06
F
S2
21
X
Special Options V = 4000 V Isolated (TO-220 Package Only) Lead Form Dimensions TO-202 TO-220 Gate Variations S1 = 50 A S2 = 200 A S3 = 500 A Device Type TCR = TO-92 (Isolated) EC = TO-92 (Isolated) T = TO-202 (Non-isolated) 2N = JEDEC (Isolated) Current Rating for TCR 22 = 1.5 A Current Rating for EC 103 = 0.8 A Current Rating for T 106 = 4 A (IGT = 200 A) 107 = 4 A (IGT = 500 A) Current Rating for 2N 5xxx = 0.8 A
EC
103
D
1
75
Lead Form Dimensions TO-92 TO-202 Gate Current (for EC series only) None = 200 A 1 = 12 A 2 = 50 A 3 = 500 A Voltage Rating for TCR -4 = 200 V -6 = 400 V -8 = 600 V Voltage Rating for EC and T B = 200 V D = 400 V M = 600 V Voltage Rating for 2N 5064 = 200 V 6565 = 400 V
Package Type Blank = Compak (Surface Mount) D = TO-252 (Surface Mount) F = TO-202 (Non-islolated) L = TO-220 (Isolated) V = TO-251 (Non-islolated)
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Description of Part Numbers
SCR
S
Device Type S = Non-sensitive SCR Voltage Rating 20 = 200 V 40 = 400 V 60 = 600 V 80 = 800 V K0 = 1000 V Current Rating 01 = 1 A 06 = 6 A 08 = 8 A 10 = 10 A 12 = 12 A 15 = 15 A 16 = 16 A 20 = 20 A 25 = 25 A 35 = 35 A 55 = 55 A 65 = 65 A 70 = 70 A
Sidac
20 08 F 12 X
Special Options V = 4000 V Isolation (TO-220 Package Only) Lead Form Dimensions TO-202 TO-220 TO-92 TO-218X TO-218 Package Type D = TO-252 (Surface Mount) E = TO-92 (Isolated) F = TO-202 (Non-isolated) J = TO-218X (Isolated) K = TO-218 (Isolated) L = TO-220 (Isolated) M = TO-218 (Non-isolated) N = TO-263 (Surface Mount) R = TO-220 (Non-isolated) V = TO-251 (Non-isolated) W = TO-218X (Non-isolated)
Device Type K = Sidac Voltage Rating 105 = 95 V to 113 V 110 = 104 V to 118 V 120 = 110 V to 125 V 130 = 120 V to 138 V 140 = 130 V to 146 V 150 = 140 V to 170 V 200 = 190 V to 215 V 220 = 205 V to 230 V 240 = 220 V to 250 V 250 = 240 V to 280 V 300 = 270 V to 330 V
K
105
0
E
70
Lead Form Dimensions TO-202 TO-92 Package Type E = TO-92 (Isolated) F = TO-202 (Non-islolated) G = DO-15X (Isolated) S = DO-214 (Surface Mount) Current Rating 0=1A
Rectifier
D
Device Type D = Rectifier Voltage Rating 20 = 200 V 40 = 400 V 60 = 600 V 80 = 800 V K0 = 1000 V Current Rating 15 = 15 A 20 = 20 A 25 = 25 A
20
15
L
55
V
Special Options V = 4000 V Isolation Lead Form Dimensions TO-220 Package Type L = TO-220 (Isolated)
Diac
HT
Device Type HT = Diac Trigger in DO-35 ST = Diac Trigger in DO-214
32
91
Lead Form Dimensions DO-35 Voltage Rating 32 = 27 V to 37 V 35 = 30 V to 40 V 40 = 35 V to 45 V 32A / 5761 = 28 V to 36 V 32B / 5761A = 30 V to 34 V 34B = 32 V to 36 V 36A / 5762 = 32 V to 40 V 36B = 34 V to 38 V
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Quality and Reliability
It is Teccor's policy to ship quality products on time. We accomplish this through Total Quality Management based on the fundamentals of customer focus, continuous improvement, and people involvement. In support of this commitment, Teccor applies the following principles: * Employees shall be respected, involved, informed, and qualified for their job with appropriate education, training, and experience. * Customer expectations shall be met or exceeded by consistently shipping products that meet the agreed specifications, quality levels, quantities, schedules, and test and reliability parameters. * Suppliers shall be selected by considering quality, service, delivery, and cost of ownership. * Design of products and processes will be driven by customer needs, reliability, and manufacturability. It is the responsibility of management to incorporate these principles into policies and systems. It is the responsibility of those in leadership roles to coach their people and to reinforce these principles. It is the responsibility of each individual employee to follow the spirit of this statement to ensure that we meet the primary policy -- to ship quality products on time. All products must first undergo rigid quality design reviews and pass extensive environmental life testing. Teccor uses Statistical Process Control (SPC) with associated control charts throughout to monitor the manufacturing processes. Only those products which pass tests designed to assure Teccor's high quality and reliability standards, while economically satisfying customer requirements, are approved for shipment. All new products and materials must receive approval of QRA prior to being released to production. The combination of reliability testing, process controls, and lot tracking assures the quality and reliability of Teccor's devices. Since even the best control systems cannot overcome measurement limitations, Teccor designs and manufactures its own computerized test equipment. Teccor's Reliability Engineering Group conducts ongoing product reliability testing to further confirm the design and manufacturing parameters.
Quality Assurance
Incoming Material Quality
Teccor "Vendor Analysis" programs provide stringent requirements before components are delivered to Teccor. In addition, purchased materials are tested rigidly at incoming inspection for specification compliance prior to acceptance for use.
Process Controls
From silicon slice input through final testing, we use statistical methods to control all critical processes. Process audits and lot inspections are performed routinely at all stages of the manufacturing cycle.
Parametric Testing
All devices are 100% computer tested for specific electrical characteristics at critical processing points.
Final Inspection
Each completed manufacturing lot is sampled and tested for compliance with electrical and mechanical requirements.
Reliability Testing
Random samples are taken from various product families for ongoing reliability testing.
Finished Goods Inspection
Product assurance inspection is performed immediately prior to shipping.
Design Assurance
The design and production of Teccor devices is a demanding and challenging task. Disciplined skills coupled with advanced computer-aided design, production techniques, and test equipment are essential elements in Teccor's ability to meet your demands for the very highest levels of quality.
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Quality and Reliability
Reliability Stress Tests
The following table contains brief descriptions of the reliability tests commonly used in evaluating Teccor product reliability on a periodic basis. These tests are applied across product lines depending on product availability and test equipment capacities. Other tests may be performed when appropriate.
Test Type High Temperature AC Blocking High Temperature Storage Life Temperature and Humidity Bias Life
Typical Conditions
TA = 100 C to 150 C, Bias @ 100% Rated VDRM, t = 24 hrs to 1000 hrs TA = 150 C, t = 250 to 1000 hrs TA = 85 C to 95 C, rh = 85% to 95% Bias @ 80% Rated VDRM (320 VDC max) t = 168 to 1008 hrs TA = -65 C to 150 C, cycles = 10 to 500
Test Description
Evaluation of the reliability of product under bias conditions and elevated temperature Evaluation of the effects on devices after long periods of storage at high temperature
Standards
MIL-STD-750, M-1040
MIL-STD-750, M-1031
Evaluation of the reliability of non- EIA / JEDEC, JESD22-A101 hermetic packaged devices in humid environments
Temperature Cycle [Air to Air]
Evaluation of the device's ability to withstand the exposure to extreme temperatures and the forces of TCE during transitions between temperatures
MIL-STD-750, M-1051, EIA / JEDEC, JESD22-A104
Thermal Shock [Liquid to Liquid] Autoclave Resistance to Solder Heat Solderability
TA = 0 C to 100 C, ttxfr = 10 s, cycled = 10 to 20
Evaluation of the device's ability MIL-STD-750, M-1056 to withstand the sudden changes in temperature and exposure to extreme temperatures
TA = 121 C, rh = 100%, P = 15 psig, Accelerated environmental test to EIA / JEDEC, JESD22-A102 evaluate the moisture resistance t = 24 hrs to 168 hrs of plastic packages TA = 260 C, t = 10 s Evaluation of the device's ability MIL-STD-750, M-2031 to withstand the temperatures as seen in wave soldering operations Evaluation of the solderability of device terminals after an extended period MIL-STD-750, M-2026, ANSI-J-STD-002
Steam aging = 1 hr to 8 hrs, Tsolder = 245 C, Flux = R
Flammability Test
For the UL 94V0 flammability test, all expoxies used in Teccor encapsulated devices are recognized by Underwriters Laboratories
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Standard Terms and Conditions
Supplier shall not be bound by any term proposed by Buyer in the absence of written agreement to such term signed by an authorized officer of Supplier. (1) PRICE: (A) Supplier reserves the right to change product prices at any time but, whenever practicable, Supplier will give Buyer at least thirty (30) days written notice before the effective date of any price change. Unless Supplier has specifically agreed in writing, signed by an authorized officer of Supplier, that a quoted price shall not be subject to change for a certain time, all products shipped on or after the effective date of a price change may be billed at the new price level. (B) Whenever Supplier agrees to a modification of Buyer's order (which modification must be in writing and signed by an authorized officer of Supplier), Supplier reserves the right to alter its price, whether or not such price was quoted as "firm." (C) Prices do not include federal, state or local taxes, now or hereafter enacted, applicable to the goods sold. Taxes will be added by Supplier to the sales prices whenever Supplier has legal obligation to collect them and will be paid by Buyer as invoiced unless Buyer provides Supplier with a proper tax exemption certificate. (2) PRODUCTION: Supplier may, at its sole discretion and at any time, withdraw any catalog item from further production without notice or liability to Buyer. (3) INTEREST: (A) All late payments shall bear interest thirty (30) days after the due date stated on the invoice until paid at the lower of one and one-half percent per month or the maximum rate permitted by law. All interest becoming due shall, if not paid when due, be added to principal and bear interest from the due date. At Supplier's option, any payment shall be applied first to interest and then to principal. (B) It is the intention of the parties to comply with the laws of the jurisdiction governing any agreement between the parties relating to interest. If any construction of the agreement between the parties indicates a different right given to Supplier to demand or receive any sum greater than that permissible by law as interest, such as a mistake in calculation or wording, this paragraph shall override. In any contingency which will cause the interest paid or agreed to be paid to exceed the maximum rate permitted by law, such excess will be applied to the reduction of any principal amount due, or if there is no principal amount due, shall be refunded.
(4) TITLE AND DELIVERY: Title to goods ordered by Buyer and risk of loss or damage in transit or thereafter shall pass to Buyer upon Supplier's delivery of the goods at Supplier's plant or to a common carrier for shipment to Buyer. (5) CONTINGENCIES: Supplier shall not be responsible for any failure to perform due to causes reasonably beyond its control. These causes shall include, but not be restricted to, fire, storm, flood, earthquake, explosion, accident, acts of public enemy, war rebellion, insurrection, sabotage, epidemic, quarantine restrictions, labor disputes, labor shortages, labor slow downs and sit downs, transportation embargoes, failure or delays in transportation, inability to secure raw materials or machinery for the manufacture of its devices, acts of God, acts of the Federal Government or any agency thereof, acts of any state or local government or agency thereof, and judicial action. Similar causes shall excuse Buyer for failure to take goods ordered by Buyer, from the time Supplier receives written notice from Buyer and for as long as the disabling cause continues, other than for goods already in transit or specially fabricated and not readily saleable to other buyers. Supplier assumes no responsibility for any tools, dies, and other equipment furnished Supplier by Buyer. (6) LIMITED WARRANTY AND EXCLUSIVE REMEDY: Supplier warrants all catalog products to be free from defects in materials and workmanship under normal and proper use and application for a period of twelve (12) months from the date code on the product in question (or if none, from the date of delivery to Buyer.) With respect to products assembled, prepared, or manufactured to Buyer's specifications, Supplier warrants only that such products will meet Buyer's specifications upon delivery. As the party responsible for the specifications, Buyer shall be responsible for testing and inspecting the products for adherence to specifications, and Supplier shall have no liability in the absence of such testing and inspection or if the product passes such testing or inspection. THE ABOVE WARRANTY IS THE ONLY WARRANTY EXTENDED BY SUPPLIER, AND IS IN LIEU OF AND EXCLUDES ALL OTHER WARRANTIES AND CONDITIONS, EXPRESSED OR IMPLIED (EXCEPT AS PROVIDED HEREIN AS TO TITLE), ON ANY GOODS OR SERVICES SOLD OR RENDERED BY SUPPLIER, INCLUDING ANY IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. THIS WARRANTY WILL NOT CREATE WARRANTY COVERAGE FOR ANY ITEM INTO WHICH ANY PRODUCT SOLD BY SUPPLIER MAY HAVE BEEN INCORPORATED OR ADDED.
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P - 10
Standard Terms and Conditions
SUPPLIER'S ENTIRE LIABILITY AND BUYER'S EXCLUSIVE REMEDY UNDER THIS WARRANTY SHALL BE, AT SUPPLIER'S OPTION, EITHER THE REPLACEMENT OF, REPAIR OF, OR ISSUANCE OF CREDIT TO BUYER'S ACCOUNT WITH SUPPLIER FOR ANY PRODUCTS WHICH ARE PROPERLY RETURNED BY BUYER DURING THE WARRANTY PERIOD. All returns must comply with the following conditions: (A) Supplier is to be promptly notified in writing upon discovery of defects by Buyer. (B) Buyer must obtain a Return Material Authorization (RMA) number from the Supplier prior to returning product. (C) The defective product is returned to Supplier, transportation charges prepaid by Buyer. (D) Supplier's examination of such product discloses, to its satisfaction, that such defects have not been caused by misuse, neglect, improper installation, repair, alteration, or accident. (E) The product is returned in the form it was delivered with any necessary disassembly carried out by Buyer at Buyer's expense. IN NO EVENT SHALL SUPPLIER, OR ANYONE ELSE ASSOCIATED IN THE CREATION OF ANY OF SUPPLIER'S PRODUCTS OR SERVICES, BE LIABLE TO BUYER FOR INCIDENTAL OR CONSEQUENTIAL DAMAGES OF ANY NATURE INCLUDING LOSS OF PROFITS, LOSS OF USE, BUSINESS INTERUPTION, AND THE LIKE. BUYER ACKNOWLEDGES THAT THE ABOVE WARRANTIES AND LIMITATIONS THEREON ARE APPROPRIATE AND REASONABLE IN EFFECTUATING SUPPLIER'S AND BUYER'S MUTUAL INTENTION TO CONDUCT AN EFFICIENT TRANSACTION AT PRICES MORE ADVANTAGEOUS TO BUYER THAN WOULD BE AVAILABLE IN THE PRESENCE OF OTHER WARRANTIES AND ASSURANCES. (7) PATENTS: Buyer shall notify Supplier in writing of any claim that any product or any part of use thereof furnished under this agreement constitutes an infringement of any U.S. patent, copyright, trade secret, or other proprietary rights of a third party. Notice shall be given within a reasonable period of time which should in most cases be within ten (10) days of receipt by Buyer of any letter, summons, or complaint pertaining to such a claim. At its option, Supplier may defend at its expense any action brought against Buyer to the extent that it is based on such a claim. Should Supplier choose to defend any such claim, Supplier may fully participate in the defense, settlement, or appeal of any action based on such claim. Should any product become, or in Supplier's opinion be likely to become, the subject of an action based on any such claim, Supplier may, at its option, as the Buyer's exclusive remedy, either procure for the Buyer the right to continue using the product, replace the product or modify the product to make it noninfringing. IN NO EVENT SHALL SUPPLIER BE LIABLE FOR ANY INCIDENTAL OR CONSEQUENTIAL DAMAGES BASED ON ANY CLAIM OF INFRINGEMENT. Supplier shall have no liability for any claim based on modifications of a product made by any person or entity other than Supplier, or based on use of a product in conjunction with any other item, unless expressly approved by Supplier. Supplier does not warrant goods against claims of infringement which are assembled, prepared, or manufactured to Buyer's specifications. (8) NON-WAIVER OF DEFAULT: Each shipment made under any order shall be treated as a separate transaction, but in the event of any default by Buyer, Supplier may decline to make further shipments without in any way affecting its rights under such order. If, despite any default by Buyer, Supplier elects to continue to make shipments, its action shall not constitute a waiver of that or any default by Buyer or in any way affect Supplier's legal remedies for any such default. At any time, Supplier's failure to exercise any right to remedy available to it shall not constitute a waiver of that right or remedy. (9) TERMINATION: If the products to be furnished under this order are to be used in the performance of a Government contract or subcontract, and the Government terminates such contract in whole or part, this order may be canceled to the extent it was to be used in the canceled portion of said Government contract and the liability of Buyer for termination allowances shall be determined by the then applicable regulations of the Government regarding termination of contracts. Supplier may cancel any unfilled orders unless Buyer shall, upon written notice, immediately pay for all goods delivered or shall pay in advance for all goods ordered but not delivered, or both, at Supplier's option. (10) LAW: The validity, performance and construction of these terms and conditions and any sale made hereunder shall be governed by the laws of the state of Texas. (11) ASSIGNS: This agreement shall not be assignable by either Supplier or Buyer. However, should either Supplier or Buyer be sold or transferred in its entirety and as an ongoing business, or should Supplier or Buyer sell or transfer in its entirety and as an ongoing concern, any division, department, or subsidiary responsible in whole or in part for the performance of this Agreement, this Agreement shall be binding upon and inure to the benefit of those successors and assigns of Supplier, Buyer, or such division, department, or subsidiary. (12) MODIFICATION OF STANDARD TERMS AND CONDITIONS: No attempted or suggested modification of or addition to any of the provisions upon the face or reverse of this form, whether contained or arising in correspondence and/or documents passing between Supplier and Buyer, in any course of dealing between Supplier or Buyer, or in any customary usage prevalent among businesses comparable to those of Supplier and/or Buyer, shall be binding upon Supplier unless made and agreed to in writing and signed by an officer of Supplier. (13) QUANTITIES: Any variation in quantities of electronic components, or other goods shipped over or under the quantities ordered (not to exceed 5%) shall constitute compliance with Buyer's order and the unit price will continue to apply.
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Notes
Data Sheets
E0
V-I Characteristics of Thyristor Devices - - - - - - - - - - - - - - - - - - - - - E0-2 Electrical Parameter Terminology - - - - - - - - - - - - - - - - - - - - - - - - - E0-3 Sensitive Triacs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - Triacs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - QUADRACs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - Alternistor Triacs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - Sensitive SCRs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - SCRs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - Rectifiers - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - Diacs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - SIDAC - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - E1 E2 E3 E4 E5 E6 E7 E8 E9
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V-I Characteristics of Thyristor Devices
+I
Voltage Drop (VT) at Specified Current (iT)
+I IT
Latching Current (IL)
IH
Off-state Leakage Current - (IDRM) at Specified VDRM Minimum Holding Current (IH)
RS
IS IDRM IBO +V VBO VS VDRM
-V
+V
-V
Specified Minimum Off-state Blocking Voltage (VDRM)
RS =
(VBO - VS) (IS - IBO)
VT
-I
V-I Characteristics of Triac Device
Breakover Voltage
-I
V-I Characteristics of Sidac Device with Negative Resistance
+I
+I
Voltage Drop (VT) at Specified Current (iT)
10 mA
Latching Current (IL)
V
Reverse Leakage Current - (IRRM) at Specified VRRM
Off - State Leakage Current - (IDRM) at Specified VDRM
Minimum Holding Current (IH)
Breakover Current IBO
-V
+V
-V
+V
Specified Minimum Reverse Blocking Voltage (VRRM)
Specified Minimum Off - State Blocking Voltage (VDRM)
Breakover Voltage VBO
Reverse Breakdown Voltage
-I
Forward Breakover Voltage
-I
V-I Characteristics of SCR Device V-I Characteristics of Bilateral Trigger Diac
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E0 - 2
(c)2002 Teccor Electronics Thyristor Product Catalog
Electrical Parameter Terminology
Thyristor
di/dt (Critical Rate-of-rise of On-state Current) - Maximum
value of the rate-of-rise of on-state current which a thyristor can withstand without deleterious effect
tgt (Gate-controlled Turn-on Time) - Time interval between
the 10% rise of the gate pulse and the 90% rise of the principal current pulse during switching of a thyristor from the off state to the on state
dv/dt (Critical Rate-of-rise of Off-state Voltage or Static dv/dt) - Minimum value of the rate-of-rise of principal voltage
which will cause switching from the off state to the on state
dv/dt(c) Critical Rate-of-rise of Commutation Voltage of a Triac (Commutating dv/dt) - Minimum value of the rate-of-rise
of principal voltage which will cause switching from the off state to the on state immediately following on-state current conduction in the opposite quadrant
tq (Circuit-commutated Turn-off Time) - Time interval between the instant when the principal current has decreased to zero after external switching of the principal voltage circuit and the instant when the SCR is capable of supporting a specified principal voltage without turning on VBO (Breakover Voltage) - Principal voltage at the breakover
point
VDRM (Repetitive Peak Off-state Voltage) - Maximum allow-
I t (RMS Surge (Non-repetitive) On-state Fusing Current) -
Measure of let-through energy in terms of current and time for fusing purposes point
2
able instantaneous value of repetitive off-state voltage that may be applied across a bidirectional thyristor (forward or reverse direction) or SCR (forward direction only)
IBO (Breakover Current) - Principal current at the breakover
VGT (Gate Trigger Voltage) - Minimum gate voltage required to produce the gate trigger current VRRM (Repetitive Peak Reverse Voltage) - Maximum allowable instantaneous value of a repetitive reverse voltage that may be applied across an SCR without causing reverse current avalanche
IDRM (Repetitive Peak Off-state Current) - Maximum leakage current that may occur under the conditions of V DRM IGT (Gate Trigger Current) - Minimum gate current required to
switch a thyristor from the off state to the on state maintain the thyristor in the on state
VS (Switching Voltage) - Voltage point after V BO when a sidac switches from a clamping state to on state
the on state
IH (Holding Current) - Minimum principal current required to IPP (Peak Pulse Current) - Peak pulse current at a short time duration and specified waveshape
current that may occur under the conditions of V RRM from the clamping state to on state
VT (On-state Voltage) - Principal voltage when the thyristor is in
IRRM (Repetitive Peak Reverse Current) - Maximum leakage IS (Switching Current) - Current at VS when a sidac switches
Diode Rectifiers
IF(AV) (Average Forward Current) - Average forward conduction current
IT(RMS) (On-state Current) - Anode cathode principal current that may be allowed under stated conditions, usually the fullcycle RMS current ITSM (Surge (Non-repetitive) On-state Current) - Peak single
cycle AC current pulse allowed
leakage current that may occur at rated V RRM rent
IFM (Maximum (Peak) Reverse Current) - Maximum reverse IF(RMS) (RMS Forward Current) - RMS forward conduction curIFSM (Maximum (Peak) Forward (Non-repetitive) Surge Current) - Maximum (peak) forward single cycle AC surge cur-
PG(AV) (Average Gate Power Dissipation) - Value of gate
rent allowed for specified duration
power which may be dissipated between the gate and main terminal 1 (or cathode) average over a full cycle
VFM (Maximum (Peak) Forward Voltage Drop) - Maximum
PGM (Peak Gate Power Dissipation) - Maximum power which may be dissipated between the gate and main terminal 1 (or cathode) for a specified time duration RJA (Thermal Resistance, Junction-to-ambient) - Temperature difference between the thyristor junction and ambient divided by the power dissipation causing the temperature difference under conditions of thermal equilibrium Note: Ambient is defined as the point where temperature does not change as a result of the dissipation.
(peak) forward voltage drop from the anode to cathode at stated conditions reverse blocking voltage that may be applied to the rectifier
VR (Reverse Blocking Voltage) - Maximum allowable DC VRRM (Maximum (Peak) Repetitive Reverse Voltage) - Maximum peak allowable value of a repetitive reverse voltage that may be applied to the rectifier
RJC (Thermal Resistance, Junction-to-case) - Temperature difference between the thyristor junction and the thyristor case divided by the power dissipation causing the temperature difference under conditions of thermal equilibrium
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E0 - 3
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Notes
l Se
ec
te
U.
L.
G O 1639 EC #E7 R
d P
Fi le
k ac
ag
* es
Z NI
ED
E1
TO-92 *TO-220 Isolated
3-lead Compak
TO-202
TO-252 D-Pak
MT2
TO-251 V-Pak
MT1
G
Sensitive Triacs
(0.8 A to 8 A)
E1
General Description
Teccor's line of sensitive gate triacs includes devices with current capabilities through 8 A. Voltage ranges are available from 200 V to 600 V. This line features devices with guaranteed gate control in Quadrants II and IV as well as control in the commonly used Quadrants I and III. Four-quadrant control devices require sensitive gate triacs. They can be controlled by digital circuitry where positive-only or negative-only pulses must control AC current in both directions through the device. Note that triacs with low IGT values in Quadrants II and IV will have lower dv/dt characteristics. The sensitive gate triac is a bidirectional AC switch and is gate controlled for either polarity of main terminal voltage. It is used primarily for AC switching and phase control applications such as motor speed controls, temperature modulation controls, and lighting controls. The epoxy TO-92 and TO-220 configurations feature Teccor's electrically-isolated construction where the case or mounting tab is internally isolated from the semiconductor chip and lead attachments. Non-isolated epoxy TO-202 packages are available as well as TO-251 and surface mount TO-252 (D-Pak). Tapeand-reel capability and tube packing also are available. See "Packing Options" section of this catalog. All Teccor triacs have glass-passivated junctions. This glassing process prevents migration of contaminants and ensures longterm device reliability with parameter stability. Variations of devices covered in this data sheet are available for custom design applications. Consult factory for more information.
Features
* * * * * Electrically-isolated packages Glass-passivated junctions ensure long device reliability and parameter stability Voltage capability -- up to 600 V Surge capability -- up to 80 A Four-quadrant gating guaranteed
Compak Sensitive Gate Triac
* * * * Surface mount package -- 0.8 A and 1 A series New small profile three-leaded Compak package Packaged in embossed carrier tape with 2,500 devices per reel Can replace SOT-223
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E1 - 1
Sensitive Triacs
Data Sheets
Part No. IT(RMS)
(11)
MT2
MT2
Isolated
Non-isolated
VDRM
(1)
IGT
(3) (6) (9)
IDRM
(1) (14)
G
MT2 G MT2
MT1
MT1 G
MT2
MT2
MT1
MT1 MT2
G
MT1
G MT2
MT1
G MT2
mAmps Volts MIN 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 QI 3 3 3 5 5 5 5 5 5 10 10 10 3 3 3 5 5 5 5 5 5 10 10 10 3 3 3 5 5 5 5 5 5 10 10 10 QII QIII MAX 3 3 3 3 3 3 5 5 5 5 5 5 5 5 5 5 5 5 10 10 10 10 10 10 3 3 3 3 3 3 5 5 5 5 5 5 5 5 5 5 5 5 10 10 10 10 10 10 3 3 3 3 3 3 5 5 5 5 5 5 5 5 5 5 5 5 10 10 10 10 10 10 QIV 3 3 3 5 5 5 10 10 10 20 20 20 3 3 3 5 5 5 10 10 10 20 20 20 3 3 3 5 5 5 10 10 10 20 20 20
TO-92 MAX L2X8E3 L4X8E3 L6X8E3 L2X8E5 L4X8E5 L6X8E5 L2X8E6 L4X8E6 L6X8E6 L2X8E8 L4X8E8 L6X8E8 L201E3 L401E3 L601E3 L201E5 L401E5 L601E5 L201E6 L401E6 L601E6 L201E8 L401E8 L601E8
Compak
TO-220
TO-252 D-Pak
TO-202
TO-251 V-Pak
0.8 A
See "Package Dimensions" section for variations. (12) L2X3 L4X3 L6X3 L2X5 L4X5 L6X5
1A
L2N3 L4N3 L6N3 L2N5 L4N5 L6N5
4A
L2004L3 L4004L3 L6004L3 L2004L5 L4004L5 L6004L5 L2004L6 L4004L6 L6004L6 L2004L8 L4004L8 L6004L8
L2004D3 L4004D3 L6004D3 L2004D5 L4004D5 L6004D5 L2004D6 L4004D6 L6004D6 L2004D8 L4004D8 L6004D8
L2004F31 L4004F31 L6004F31 L2004F51 L4004F51 L6004F51 L2004F61 L4004F61 L6004F61 L2004F81 L4004F81 L6004F81
L2004V3 L4004V3 L6004V3 L2004V5 L4004V5 L6004V5 L2004V6 L4004V6 L6004V6 L2004V8 L4004V8 L6004V8
mAmps TC = TC = 25 C 110 C MAX 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.1 0.01 0.2 0.01 0.2 0.01 0.2 0.01 0.2 0.01 0.2 0.01 0.2 0.01 0.2 0.01 0.2 0.01 0.2 0.01 0.2 0.01 0.2 0.01 0.2
See "General Notes" on page E1 - 4 and "Electrical Specification Notes" on page E1 - 5.
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E1 - 2
(c)2002 Teccor Electronics Thyristor Product Catalog
Data Sheets
Sensitive Triacs
VTM
(1) (4)
VGT
(2) (5) (15)
IH
(1) (7)
IGTM
(13)
PGM
(13)
PG(AV)
ITSM
(8) (10)
dv/dt(c)
(1) (10)
dv/dt
(1)
tgt
(9)
I2t
di/dt
Volts TC = 25 C MAX 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6
Volts TC = 25 C MAX 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
Amps mAmps MAX 5 5 5 10 10 10 10 10 10 15 15 15 5 5 5 10 10 10 10 10 10 15 15 15 5 5 5 10 10 10 10 10 10 15 15 15 Amps 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 Watts 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 15 15 15 15 15 15 15 15 15 15 15 15 Watts 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 60/50 Hz 10/8.3 10/8.3 10/8.3 10/8.3 10/8.3 10/8.3 10/8.3 10/8.3 10/8.3 10/8.3 10/8.3 10/8.3 20/16.7 20/16.7 20/16.7 20/16.7 20/16.7 20/16.7 20/16.7 20/16.7 20/16.7 20/16.7 20/16.7 20/16.7 40/33 40/33 40/33 40/33 40/33 40/33 40/33 40/33 40/33 40/33 40/33 40/33 Volts/Sec TYP 0.5 0.5 0.5 1 1 1 1 1 1 2 2 2 0.5 0.5 0.5 1 1 1 1 1 1 1 1 1 0.5 0.5 0.5 1 1 1 1 1 1 2 2 2
Volts/Sec TC = 100 C TYP 20 15 10 20 15 10 30 25 20 35 30 25 20 20 10 20 20 10 30 30 20 35 35 25 25 25 15 25 25 15 30 30 20 35 35 25
Sec TYP 2.8 2.8 2.8 3 3 3 3 3 3 3.2 3.2 3.2 2.8 2.8 2.8 3 3 3 3 3 3 3.2 3.2 3.2 2.8 2.8 2.8 3 3 3 3 3 3 3.2 3.2 3.2
Amps2Sec 0.41 0.41 0.41 0.41 0.41 0.41 0.41 0.41 0.41 0.41 0.41 0.41 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 6.6 6.6 6.6 6.6 6.6 6.6 6.6 6.6 6.6 6.6 6.6 6.6
Amps/Sec 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 50 50 50 50 50 50 50 50 50 50 50 50
See "General Notes" on page E1 - 4 and "Electrical Specification Notes" on page E1 - 5.
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E1 - 3
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Sensitive Triacs
Data Sheets
Part No. IT(RMS)
(11)
MT2
Isolated
Non-isolated
VDRM
(1)
IGT
(3) (6)
IDRM
(1) (14)
MT2
G MT2 MT1
MT1 MT2
G
MT1
G MT2
TO-220 MAX
TO-252 D-Pak
TO-251 V-Pak
Volts MIN 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600
QI 5 5 5 5 5 5 10 10 10 5 5 5 10 10 10
6A
8A
See "Package Dimensions" section for variations. (12) L2006L5 L2006D5 L2006V5 L4006L5 L4006D5 L4006V5 L6006L5 L6006D5 L6006V5 L2006L6 L2006D6 L2006V6 L4006L6 L4006D6 L4006V6 L6006L6 L6006D6 L6006V6 L2006L8 L2006D8 L2006V8 L4006L8 L4006D8 L4006V8 L6006L8 L6006D8 L6006V8 L2008L6 L2008D6 L2008V6 L4008L6 L4008D6 L4008V6 L6008L6 L6008D6 L6008V6 L2008L8 L2008D8 L2008V8 L4008L8 L4008D8 L4008V8 L6008L8 L6008D8 L6008V8
mAmps QII QIII MAX 5 5 5 5 5 5 5 5 5 5 5 5 10 10 10 10 10 10 5 5 5 5 5 5 10 10 10 10 10 10
QIV 5 5 5 10 10 10 20 20 20 10 10 10 20 20 20
mAmps TC = 25 C TC = 110 C MAX 0.02 0.5 0.02 0.5 0.02 0.5 0.02 0.5 0.02 0.5 0.02 0.5 0.02 0.5 0.02 0.5 0.02 0.5 0.02 0.5 0.02 0.5 0.02 0.5 0.02 0.5 0.02 0.5 0.02 0.5
Specified Test Conditions
di/dt -- Maximum rate-of-change of on-state current; IGT = 50 mA with 0.1 s rise time dv/dt -- Critical rate-of-rise of off-state voltage at rated VDRM gate open dv/dt(c) -- Critical rate-of-rise of commutation voltage at rated VDRM and IT(RMS) commutating di/dt = 0.54 rated IT(RMS)/ms; gate unenergized I2t -- RMS surge (non-repetitive) on-state current for period of 8.3 ms for fusing IDRM -- Peak off-state current, gate open; VDRM = max rated value IGT -- DC gate trigger current in specific operating quadrants; VD = 12 V dc; RL = 60 IGTM -- Peak gate trigger current IH -- Holding current gate open; initial on-state current = 100 mA dc IT(RMS) -- RMS on-state current conduction angle of 360 ITSM -- Peak one-cycle surge PG(AV) -- Average gate power dissipation PGM -- Peak gate power dissipation; IGT IGTM tgt -- Gate controlled turn-on time; IGT = 50 mA with 0.1 s rise time VDRM -- Repetitive peak off-state/blocking voltage VGT -- DC gate trigger voltage; VD = 12 V dc; RL = 60 VTM -- Peak on-state voltage at max rated RMS current
General Notes
* * * All measurements are made with 60 Hz resistive load and at an ambient temperature of +25 C unless otherwise specified. Operating temperature range (TJ) is -65 C to +110 C for TO-92 devices and -40 C to 110 C for all other devices. Storage temperature range (TS) is -65 C to +150 C for TO-92 devices, -40 C to +150 C for TO-202 devices, and -40 C to +125 C for TO-220 devices. Lead solder temperature is a maximum of 230 C for 10 seconds maximum at a minimum of 1/16" (1.59 mm) from case. The case or lead temperature (TC or TL) is measured as shown on dimensional outline drawings. See "Package Dimensions" section of this catalog.
* *
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(c)2002 Teccor Electronics Thyristor Product Catalog
Data Sheets
Sensitive Triacs
VTM
(1) (4)
VGT
(2) (5) (15)
IH
(1) (7)
IGTM
(13)
PGM
(13)
PG(AV)
ITSM
(8) (10)
dv/dt(c)
(1) (10)
dv/dt
(1)
tgt
(9)
I2t
di/dt
Volts TC = 25 C MAX 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6
Volts TC = 25 C MAX 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
mAmps MAX 10 10 10 10 10 10 20 20 20 10 10 10 20 20 20
Amps 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6
Watts 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18
Watts 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4
Amps 60/50 Hz 60/50 60/50 60/50 60/50 60/50 60/50 60/50 60/50 60/50 80/65 80/65 80/65 80/65 80/65 80/65
Volts/Sec TYP 1 1 1 2 2 2 2 2 2 2 2 2 2 2 2
Volts/Sec TC = 100 C TYP 40 30 20 40 30 20 45 40 30 40 30 20 45 40 30
Sec TYP 3 3 3 3 3 3 3.2 3.2 3.2 3 3 3 3.2 3.2 3.2
Amps2Sec 15 15 15 15 15 15 15 15 15 26.5 26.5 26.5 26.5 26.5 26.5
Amps/Sec 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70
Electrical Specification Notes
(1) (2) (3) (4) (5) (6) (7) (8) (9) For either polarity of MT2 with reference to MT1 terminal For either polarity of gate voltage VGT with reference to MT1 terminal See Gate Characteristics and Definition of Quadrants. See Figure E1.4 for iT versus vT. See Figure E1.6 for VGT versus TC. See Figure E1.7 for IGT versus TC. See Figure E1.5 for IH versus TC. See Figure E1.9 for surge rating and specific duration. See Figure E1.8 for tgt versus IGT.
Gate Characteristics
Teccor triacs may be turned on between gate and MT1 terminals in the following ways: * * In-phase signals (with standard AC line) using Quadrants I and III Application of unipolar pulses (gate always positive or negative), using Quadrants II and III with negative gate pulses and Quadrants I and IV with positive gate pulses
When maximum surge capability is required, pulses should be a minimum of one magnitude above IGT rating with a steep rising waveform (1 s rise time).
ALL POLARITIES ARE REFERENCED TO MT1 MT2 POSITIVE (Positive Half Cycle)
(10) See Figure E1.2 and Figure E1.3 for maximum allowable case temperature at maximum rated current. (11) See Figure E1.1, Figure E1.2, and Figure E1.3 for TA or TC versus IT(RMS). (12) See package outlines for lead form configurations. When ordering special lead forming, add type number as suffix to part number. (13) Pulse width 10 s (14) TC or TL = TJ for test conditions in off state (15) Minimum non-trigger VGT at 110 C is 0.2 V.
IGT
(-)
MT2 IGT GATE
+
MT2
(+)
IGT GATE MT1
MT1
(-)
REF MT2 IGT GATE MT1 REF
QII QI QIII QIV
(+)
REF
+
MT2 IGT GATE MT1 REF
IGT
MT2 NEGATIVE (Negative Half Cycle)
-
Definition of Quadrants
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Sensitive Triacs
Data Sheets
Electrical Isolation
Teccor's isolated triac packages withstand a minimum high potential test of 2500 V ac rms from leads to mounting tab over the device's operating temperature range. The following isolation table shows standard isolation ratings.
Electrical Isolation from Leads to Mounting Tab
V AC RMS 2500 *UL Recognized File #E71639 TO-220 * Standard
Thermal Resistance (Steady State) Junction to Mounting Tab and Junction to Ambient RJC [RJA] C/W (TYP)
Package Code E C F L F2 D V
Type
TO-92 Plastic 0.8 A 1A 4A 6A 8A 60 [135] 50 [95]
Compak 60 * 40 *
TO-202 Type 1
TO-220 Isolated
TO-202 Type 2
TO-252 D-Pak
TO-251 V-Pak
3.5 [45]
3.6 [50] 3.3 2.8
6.0 [70]
3.5 3.2 2.7
6.0 [70] 3.2 2.7
* Mounted on 1
cm2
copper foil surface; two-ounce copper foil
Maximum Allowable Ambient Temperature (TA) - C
120
Maximum Allowable Case Temperature (TC) - C
100
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 FREE AIR RATING - NO HEATSINK TO-220 and TYPE 1 and 3 TO-202
110 100 90 80 70
0.8 A
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawings
80
TYPE 2 and 4 TO-202 and TO-251
1A
60
1 A TO-92
40
0.8 A TO-92
60 50 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6
25 20 0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
RMS On-State Current [IT(RMS)] - Amps
RMS On-State Current [IT(RMS)] - Amps
Figure E1.1 Maximum Allowable Ambient Temperature versus On-state Current
Figure E1.2 Maximum Allowable Case Temperature versus On-state Current (0.8 A and 1 A)
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(c)2002 Teccor Electronics Thyristor Product Catalog
Data Sheets
Sensitive Triacs
Maximum Allowable Case Temperature (TC) - C
110 105 100 95 90 85 80 75 70 65 60 0 1 2 3 4 5 6 7 8
4 A TYPE 2 and 4 TO-202 4 A TO-251 4 A TYPE 1 and 3 TO-202 4 A TO-220 (Isolated) 4 A TO-252
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawings
2.0
6A
TO TO -25 8A 1a -22 nd TO 0( TO -22 Iso -25 0( 2 lat Iso ed late ) d)
8A
VGT (TC = 25 C)
1.5
VGT
1.0
6 A TO-251 6 A TO-252
Ratio of
.5
0 -65 -40 -15 +25 +65 +110 +125
RMS On-State Current [IT(RMS)] - Amps
Case Temperature (TC) - C
Figure E1.3 Maximum Allowable Case Temperature versus On-state Current (4 A, 6 A, and 8 A)
Figure E1.6 Normalized DC Gate Trigger Voltage for All Quadrants versus Case Temperature
20 18 TC = 25 C
4.0
Positive or Negative Instantaneous On-state Current (iT) - Amps
16 14 12 10 8 6 4 2 0 0 0.5 0.8 1.0 1.2 1.4 1.6 1.8 0.8 A 4A 1A 6 A and 8 A
IGT (T = 25 C) C
3.0
IGT
2.0
Ratio of
1.0
0 -65 -40 -15 +25 +65 +110 +125
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Case Temperature (TC) - C
Figure E1.4 On-state Current versus On-state Voltage (Typical)
Figure E1.7 Normalized DC Gate Trigger Current for All Quadrants versus Case Temperature
7.0
4.0
TC = 25 C
6.0
IH (TC = 25 C)
3.0
Turn-On Time (tgt) - Sec
INITIAL ON-STATE CURRENT = 100 mA (DC) 0.8 - 4 A Devices = 200 mA (DC) 6 - 8 A Devices
IGT = 5 mA MAX
5.0 IGT = 10 mA MAX
IH
4.0
2.0
IGT = 20 mA MAX
Ratio of
3.0
IGT = 3 mA MAX
1.0
2.0
1.0
0 -65 -40 -15 +25 +65 +110 +125
0 1 2 3 4 56 8 10 20 30 40 60 80 100
Case Temperature (TC) - C
DC Gate Trigger Current (IGT) - mA
Figure E1.5 Normalized DC Holding Current versus Case Temperature
Figure E1.8 Turn-on Time versus Gate Trigger Current (Typical)
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Sensitive Triacs
Data Sheets
200 150 100 80 60 40 30 20 10 8 6 4 3 2 1 1 2 34 6 8 10 20 30 40 60 100 200 400 600 1000
8A 6A
4A
SUPPLY FREQUENCY: 60 Hz Sinusoidal LOAD: Resistive RMS On-state Current: [IT(RMS)]: Maximum Rated Value at Specified Case Temperature
Peak Surge (Non-Repetitive) On-State Current (ITSM) - Amps
NOTES: 1) Gate control may be lost during and immediately following surge current interval. 2) Overload may not be repeated until junction temperature has returned to steady-state rated value.
1A
0.8 A
Surge Current Duration - Full Cycles
Figure E1.9 Peak Surge Current versus Surge Current Duration
9.0 8.0 7.0 6.0
6 A and 8 A
Average On-state Power Dissipation [PD(AV)] - Watts
1.5
1.0
Average On-state Power Dissipation [PD(AV)] - Watts
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360
5.0 4.0 3.0 2.0 1.0
4A
0.8 A 0.5 1A
0 0 0.25 0.50 0.75 1.0 1.25 1.5
0 0 .5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0 7.5 8.0
RMS On-state Current [IT(RMS)] - Amps
RMS On-state Current [IT(RMS)] - Amps
Figure E1.10 Power Dissipation (Typical) versus RMS On-state Current (0.8 A and 1 A)
Figure E1.11 Power Dissipation (Typical) versus RMS On-state Current (4 A, 6 A, and 8 A)
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(c)2002 Teccor Electronics Thyristor Product Catalog
l Se
ec
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U.
L.
G O 1639 EC #E7 R
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Fi le
Pa
a ck
s* ge
Z NI
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E2
TO-92 TO-202 *TO-220
3-lead Compak
TO-263 D2Pak
TO-252 D-Pak TO-251 V-Pak
*TO-3 Fastpak
MT2
MT1
G
Triacs
(0.8 A to 35 A)
E2
General Description
These gated triacs from Teccor Electronics are part of a broad line of bidirectional semiconductors. The devices range in current ratings from 0.8 A to 35 A and in voltages from 200 V to 1000 V. The triac may be gate triggered from a blocking to conduction state for either polarity of applied voltage and is designed for AC switching and phase control applications such as speed and temperature modulation controls, lighting controls, and static switching relays. The triggering signal is normally applied between the gate and MT1. Isolated packages are offered with internal construction, having the case or mounting tab electrically isolated from the semiconductor chip. This feature facilitates the use of low-cost assembly and convenient packaging techniques. Tape-and-reel capability is available. See "Packing Options" section of this catalog. All Teccor triacs have glass-passivated junctions to ensure longterm device reliability and parameter stability. Teccor's glass-passivated junctions offer a rugged, reliable barrier against junction contamination. Variations of devices covered in this data sheet are available for custom design applications. Consult factory for more information.
Features
* * * * Electrically-isolated packages Glass-passivated junctions Voltage capability -- up to 1000 V Surge capability -- up to 200 A
Compak Package
* * * * Surface mount package -- 0.8 A and 1 A series New small profile three-leaded Compak package Packaged in embossed carrier tape with 2,500 devices per reel Can replace SOT-223
(c)2002 Teccor Electronics Thyristor Product Catalog
E2 - 1
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Triacs
Data Sheets
Part Number IT(RMS)
(4)
MT2
Isolated
MT2
Non-isolated
MT2
VDRM
(1)
IGT
(3) (7) (15)
G
MT2 G MT2 MT1
MT1 MT2 G MT2
MT1
MT1 G
MT2
MT1 MT2 G
MT2
MT1 G MT2
MT1
G MT2
MT1
G MT2
Volts TO-263 D2Pak MIN 200 400 600 200 400 600 200 400 600 200 400 600 10 10 10 25 25 25 10 10 10 25 25 25 10 10 10 25 25 25 25 25 25 25 50 50 50 25 25 50 50 50 QI
mAmps QII QIII QIV MAX 10 10 10 25 25 25 10 10 10 25 25 25 10 10 10 25 25 25 25 25 25 25 50 50 50 25 25 50 50 50 10 10 10 25 25 25 10 10 10 25 25 25 10 10 10 25 25 25 25 25 25 25 50 50 50 25 25 50 50 50 QIV TYP 25 25 25 50 50 50 25 25 25 50 50 50 25 25 25 50 50 50 50 50 50 50 75 75 75 50 50 75 75 75
TO-92 MAX
TO-220
Compak Q2X3 Q4X3 Q6X3 Q2X4 Q4X4 Q6X4 Q2N3 Q4N3 Q6N3 Q2N4 Q4N4 Q6N4
TO-202
TO-220
TO-252 D-Pak
TO-251 V-Pak
See "Package Dimensions" section for variations. (11) Q2X8E3 Q4X8E3 Q6X8E3 Q2X8E4 Q4X8E4
0.8 A
1A
Q6X8E4 Q201E3 Q401E3 Q601E3 Q201E4 Q401E4 Q601E4
4A
Q2004L3 Q4004L3 Q6004L3 Q2004L4 Q4004L4 Q6004L4 Q8004L4
Q2004F31 Q4004F31 Q6004F31 Q2004F41 Q4004F41 Q6004F41
Q2004D3 Q4004D3 Q6004D3 Q2004D4 Q4004D4 Q6004D4 Q8004D4 QK004D4 Q2006R4 Q4006R4 Q6006R5 Q8006R5 QK006R5
Q2004V3 Q4004V3 Q6004V3 Q2004V4 Q4004V4 Q6004V4 Q8004V4 QK004V4 Q2006N4 Q4006N4 Q6006N5 Q8006N5 QK006N5 Q2008N4 Q4008N4 Q6008N5 Q8008N5 QK008N5
200 400 600 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000
6A
QK004L4 Q2006L4 Q4006L4 Q6006L5 Q8006L5 QK006L5
Q2006F41 Q4006F41 Q6006F51
8A
Q2008L4 Q4008L4 Q6008L5 Q8008L5 QK008L5
Q2008F41 Q4008F41 Q6008F51
Q2008R4 Q4008R4 Q6008R5 Q8008R5 QK008R5
See "General Notes" on page E2 - 4 and "Electrical Specification Notes" on page E2 - 5.
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Data Sheets
Triacs
IDRM
(1) (16)
VTM
(1) (5)
VGT
(2) (6) (15) (18) (19)
IH
(1) (8) (12)
IGTM
(14)
PGM
(14)
PG(AV)
ITSM
(9) (13)
dv/dt(c)
(1) (4) (13)
dv/dt
(1)
tgt
(10)
I2t
di/dt
mAmps TC = TC = TC = 25 C 100 C 125 C MAX 0.02 0.02 0.02 0.02 0.02 0.02 0.02 0.02 0.02 0.02 0.02 0.02 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 3 0.5 0.5 0.5 0.5 3 0.5 0.5 0.5 0.5 3 1 1 1 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
Volts TC = 25 C MAX 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6
Volts TC = 25 C MAX 2 2 2 2.5 2.5 2.5 2 2 2 2.5 2.5 2.5 2 2 2 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 mAmps MAX 15 15 15 25 25 25 15 15 15 25 25 25 20 20 20 30 30 30 30 30 50 50 50 50 50 50 50 50 50 50 1 1 1 1 1 1 1 1 1 1 1 1 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.6 1.6 1.6 1.6 1.6 1.8 1.8 1.8 1.8 1.8 10 10 10 10 10 10 10 10 10 10 10 10 15 15 15 15 15 15 15 15 18 18 18 18 18 20 20 20 20 20 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 Amps Watts Watts
Amps 60/50 Hz 10/8.3 10/8.3 10/8.3 10/8.3 10/8.3 10/8.3 20/16.7 20/16.7 20/16.7 20/16.7 20/16.7 20/16.7 55/46 55/46 55/46 55/46 55/46 55/46 55/46 55/46 80/65 80/65 80/65 80/65 80/65 100/83 100/83 100/83 100/83 100/83 Volts/Sec TYP 1 1 1 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 4 4 4 4 4 4 4 4 4 4
Volts/Sec TC= TC= 100 C 125 C MIN 40 35 25 50 45 35 40 40 30 50 50 40 50 50 40 100 100 75 60 50 200 200 150 125 100 250 250 220 150 100 30 25 15 40 35 25 30 30 20 40 40 30 40 40 30 75 75 50 40 120 120 100 85 150 150 125 100 Sec TYP 2.5 2.5 2.5 3 3 3 2.5 2.5 2.5 3 3 3 2.5 2.5 2.5 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 0.41 0.41 0.41 0.41 0.41 0.41 1.6 1.6 1.6 1.6 1.6 1.6 12.5 12.5 12.5 12.5 12.5 12.5 12.5 12.5 26.5 26.5 26.5 26.5 26.5 41 41 41 41 41 20 20 20 20 20 20 30 30 30 30 30 30 50 50 50 50 50 50 50 50 70 70 70 70 70 70 70 70 70 70 Amp2Sec Amps/Sec
See "General Notes" on page E2 - 4 and "Electrical Specification Notes" on page E2 - 5.
(c)2002 Teccor Electronics Thyristor Product Catalog
E2 - 3
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Triacs
Data Sheets
Part Number IT(RMS)
(4) (16)
MT2
MT1 MT2
Isolated
Non-isolated
MT2
MT2
VDRM
(1)
IGT
(3) (7) (15)
IDRM
(1) (16)
G MT2 MT1
Gate
MT1
T MT2
MT1 G MT2
MT1
G MT2
mAmps TO-263 D2Pak Q2010N4 Q4010N4 Q6010N4 Q8010N4 QK010N4 Q2010N5 Q4010N5 Q6010N5 Q8010N5 QK010N5 Q2015N5 Q4015N5 Q6015N5 Q8015N5 QK015N5 Q2025N5 Q4025N5 Q6025N5 Q8025N5 QK025N5 Volts MIN 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 600 800 600 800 25 25 25 25 25 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 QI QII 25 25 25 25 25 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 QIII 25 25 25 25 25 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 120 120 120 120 QIV 50 50 50 50 50 75 75 75 75 75 QIV TYP 0.05 0.05 0.05 0.1 0.1 0.05 0.05 0.05 0.1 0.1 0.05 0.05 0.05 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 TC = 25 C
mAmps TC = TC = 100 C 125 C MAX 1 1 1 1 3 0.5 0.5 0.5 0.5 3 0.5 0.5 0.5 1 3 1 1 1 1 3 3 3 3 3 5 5 5 5 2 2 2 2 2 2 2 3
TO-3 Fastpak MAX
TO-220 Q2010L4 Q4010L4 Q6010L4 Q8010L4
TO-202
TO-220 Q2010R4 Q4010R4 Q6010R4 Q8010R4 QK010R4
See "Package Dimensions" section for variations. (11)
MAX
10 A
QK010L4 Q2010L5 Q4010L5 Q6010L5 Q8010L5 QK010L5 Q2015L5 Q4015L5 Q6015L5 Q8015L5 QK015L5 Q2010F51 Q4010F51 Q6010F51
Q2010R5 Q4010R5 Q6010R5 Q8010R5 QK010R5 Q2015R5 Q4015R5 Q6015R5 Q8015R5 QK015R5 Q2025R5 Q4025R5 Q6025R5
15 A
25 A
Q6025P5 Q8025P5
Q8025R5 QK025R5
35 A
Q6035P5 Q8035P5
Specific Test Conditions
di/dt -- Maximum rate-of-change of on-state current; IGT = 200 mA with 0.1 s rise time dv/dt -- Critical rate-of-rise of off-state voltage at rated VDRM gate open dv/dt(c) -- Critical rate-of-rise of commutation voltage at rated VDRM and IT(RMS) commutating di/dt = 0.54 rated IT(RMS)/ms; gate unenergized I2t -- RMS surge (non-repetitive) on-state current for period of 8.3 ms for fusing IDRM -- Peak off-state current, gate open; VDRM = maximum rated value IGT -- DC gate trigger current in specific operating quadrants; VD = 12 V dc IGTM -- Peak gate trigger current IH -- Holding current (DC); gate open IT(RMS) -- RMS on-state current conduction angle of 360 ITSM -- Peak one-cycle surge PG(AV) -- Average gate power dissipation PGM -- Peak gate power dissipation; IGT IGTM tgt -- Gate controlled turn-on time; IGT = 200 mA with 0.1 s rise time
VDRM -- Repetitive peak blocking voltage VGT -- DC gate trigger voltage; VD = 12 V dc; RL = 60 VTM -- Peak on-state voltage at maximum rated RMS current
General Notes
* * All measurements are made at 60 Hz with a resistive load at an ambient temperature of +25 C unless specified otherwise. Operating temperature range (TJ) is -65 C to +125 C for TO-92, -25 C to +125 C for Fastpak, and -40 C to +125 C for all other devices. Storage temperature range (TS) is -65 C to +150 C for TO-92, -40 C to +150 C for TO-202, and -40 C to +125 C for all other devices. Lead solder temperature is a maximum of 230 C for 10 seconds, maximum; 1/16" (1.59 mm) from case. The case temperature (TC) is measured as shown on the dimensional outline drawings. See "Package Dimensions" section of this catalog.
*
* *
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(c)2002 Teccor Electronics Thyristor Product Catalog
Data Sheets
Triacs
VTM
(1) (5)
VGT
(2) (6) (15) (18) (19)
IH
(1) (8) (12)
IGTM
(14)
PGM
(14)
PG(AV)
ITSM
(9) (13)
dv/dt(c)
(1) (4) (13)
dv/dt
(1)
tgt
(10) (17)
I2t
di/dt
Volts TC = 25 C MAX 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.8 1.8 1.8 1.8 1.8 1.4 1.4 1.5 1.5
Volts TC = 25 C MAX 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.75 2.75 2.75 2.75 mAmps MAX 35 35 35 35 35 50 50 50 50 50 70 70 70 70 70 100 100 100 100 100 50 50 50 50 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 2 2 2 2 2 2 2 2 2 2 2 2 2 2 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 Amps Watts Watts
Amps 60/50 Hz 120/100 120/100 120/100 120/100 120/100 120/100 120/100 120/100 120/100 120/100 200/167 200/167 200/167 200/167 200/167 200/167 200/167 200/167 200/167 200/167 250/220 250/220 350/300 350/300 Volts/Sec TYP 2 2 2 2 2 4 4 4 4 4 4 4 4 4 4 5 5 5 5 5 5 5 5 5
Volts/Sec TC = 100 C 150 150 100 75 50 350 350 300 250 150 400 400 350 300 200 400 400 350 300 200 550 450 550 450 475 400 475 400 275 275 225 200 225 225 200 175 275 275 225 200 TC = 125 C Sec TYP 3 3 3 3 3 3 3 3 3 3 4 4 4 4 4 4 4 4 4 4 3 3 3 3 60 60 60 60 60 60 60 60 60 60 166 166 166 166 166 166 166 166 166 166 260 260 508 508 70 70 70 70 70 70 70 70 70 70 100 100 100 100 100 100 100 100 100 100 100 100 100 100 Amps2Sec Amps/Sec
MIN
Electrical Specification Notes
(1) (2) (3) (4) (5) (6) (7) (8) (9) For either polarity of MT2 with reference to MT1 terminal For either polarity of gate voltage (VGT) with reference to MT1 terminal See Gate Characteristics and Definition of Quadrants. See Figure E2.1 through Figure E2.7 for current rating at specific operating temperature. See Figure E2.8 through Figure E2.10 for iT versus vT. See Figure E2.12 for VGT versus TC. See Figure E2.11 for IGT versus TC. See Figure E2.14 for IH versus TC. See Figure E2.13 for surge rating with specific durations.
(15) RL = 60 for 0.8 A to10 A triacs; RL = 30 for 15 A to 35 A triacs (16) TC = TJ for test conditions in off state (17) IGT = 300 mA for 25 A and 35 A devices (18) Quadrants I, II, III only (19) Minimum non-trigger VGT at 125 C is 0.2 V for all except 50 mA MAX QIV devices which are 0.2 V at 110 C.
Gate Characteristics
Teccor triacs may be turned on between gate and MT1 terminals in the following ways: * * In-phase signals (with standard AC line) using Quadrants I and III Application of unipolar pulses (gate always positive or negative), using Quadrants II and III with negative gate pulses and Quadrants I and IV with positive gate pulses However, due to higher gate requirements for Quadrant IV, it is recommended that only negative pulses be applied. If positive pulses are required, see "Sensitive Triacs" section of this catalog or contact the factory. Also, see Figure AN1002.8, "Amplified Gate" Thyristor Circuit.
(10) See Figure E2.15 for tgt versus IGT. (11) See package outlines for lead form configurations. When ordering special lead forming, add type number as suffix to part number. (12) Initial on-state current = 200 mA dc for 0.8 A to10 A devices, 400 mA dc for 15 A to 35 A devices (13) See Figure E2.1 through Figure E2.6 for maximum allowable case temperature at maximum rated current. (14) Pulse width 10 s; IGT IGTM (c)2002 Teccor Electronics Thyristor Product Catalog E2 - 5
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Triacs
Data Sheets
In all cases, if maximum surge capability is required, pulses should be a minimum of one magnitude above IGT rating with a steep rising waveform (1 s rise time).
ALL POLARITIES ARE REFERENCED TO MT1 MT2 POSITIVE (Positive Half Cycle)
Electrical Isolation
Teccor's isolated triac packages will withstand a minimum high potential test of 2500 V ac rms from leads to mounting tab or base, over the operating temperature range of the device. The following isolation table shows standard and optional isolation ratings.
Electrical Isolation from Leads to Mounting Tab *
MT2
(-)
+
MT2
IGT GATE MT1
(+)
IGT GATE MT1
IGT
(-)
REF MT2 IGT GATE MT1 REF
QII QI QIII QIV
(+)
REF
V AC RMS 2500
TO-220 Isolated Standard Optional **
Fastpak Isolated Standard N/A
+
MT2 IGT GATE MT1 REF
IGT
4000
* UL Recognized File E71639 ** For 4000 V isolation, use V suffix in part number.
MT2 NEGATIVE (Negative Half Cycle)
-
Definition of Quadrants
Thermal Resistance (Steady State) R JC [R JA] (TYP.) C/W
Package Code P E C F F2 L R D V N
Type
TO-3 Fastpak 0.8 A 1A 4A 6A 8A 10 A 15 A 25 A 35 A 1.6 1.5
TO-92 60 [135] 50 [95]
Compak 60 * 40 *
TO-202 Type 1
TO-202 Type 2
TO-220 Isolated
TO-220 Non-isolated
TO-252 D-Pak
TO-251 V-Pak
TO-263 D2Pak
3.5 [45] 3.8 3.3 3.5
6 [70]
3.6 [50] 3.3 2.8 2.6 2.1 1.8 [45] 1.5 1.3 1.1 0.89
3.5
6.0 [70] 1.8 1.5 1.3 1.1 0.89
* Mounted on 1
cm2
copper foil surface; two-ounce copper foil
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Data Sheets
Triacs
Maximum Allowable Case Temperature (TC) - C
130 120 110 100 90 80 70 60 0 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4
Maximum Allowable Case Temperature (TC) - C
130 120 110 100 90 80 70 60 0 0 2 4 6 8 10 12 14 CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing 10 A TO-202 10 A TO-220 (Non-isolated) 10 A D2Pak
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing
1A 0.8 A
RMS On-state Current [lT(RMS)] - AMPS
RMS On-state Current [lT(RMS)] - Amps
Figure E2.1 Maximum Allowable Case Temperature versus On-state Current (0.8 A and 1 A)
Figure E2.4 Maximum Allowable Case Temperature versus On-state Current (10 A)
Maximum Allowable Case Temperature (TC) - C
Maximum Allowable Case Temperature (TC) - C
130 120 110 100 90 80 70 60 0 0 1 2 3 4 A TO-202 (TYPE 2 and 4) 4 A TO-251 4 A TO-220 (Isolated) 4 A TO-202 (Type 1 and 3) 4 A TO-252 6 A TO-220 (Non-isolated) 6 A D2Pak 6 A TO-220 (Isolated) 6 A TO-202
130 120 110 100
15 A TO-220 (Non-isolated) 15 A D2Pak
15 A TO-220 (Isolated)
90 80 70 60 0 0 5 10 15 CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing
4
5
6
7
RMS On-state Current [lT(RMS)] - Amps
RMS On-state Current [lT(RMS)] - AMPS
Figure E2.2 Maximum Allowable Case Temperature versus On-state Current (4 A and 6 A)
Figure E2.5 Maximum Allowable Case Temperature versus On-state Current (15 A)
130
Maximum Allowable Case Temperature (TC) - C
130 10 A TO-220 (Isolated) 120 110 100 90 80 70 60 0 0 2 4 6 8 10 12 14 CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing 8 A TO-202 8 A TO-220 (Isolated) 8 A TO-220 (Non-isolated) 8 A D2Pak
Maximum Allowable Case Temperature (TC) - C
120
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing
110 25 A TO-220 (Non-isolated) 25 A D2Pak
100
90 25 A TO-3 Fastpak 35 A TO-3 Fastpak
80
70
60
50 0 10 20 30 40 50
RMS On-state Current [lT(RMS)] - AMPS
RMS On-state Current [lT(RMS)] - Amps
Figure E2.3 Maximum Allowable Case Temperature versus On-state Current (8 A and 10 A)
Figure E2.6 Maximum Allowable Case Temperature versus On-state Current (25 A and 35 A)
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Triacs
Data Sheets
Maximum Allowable Ambient Temperature (TA) -- C
90
120
Positive or Negative Instantaneous On-state Current (iT) - Amps
100
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 FREE AIR RATING - NO HEATSINK
80 70 60 50 40 30 20 15 A and 25 A 10 0
TC = 25 C
80
TO-202 (TYPE 2 and 4) TO-251 TO-220 Devices and TO-202 (Type 1 and 3)
15 A and 25 A Fastpak
60
1 A TO-92 40 0.8 A TO-92 25 20 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
0
0.6
0.8
1.0
1.2
1.4
1.6
1.8
RMS On-state Current [IT (RMS)] -- Amps
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Figure E2.7 Maximum Allowable Ambient Temperature versus On-state Current
10
Figure E2.10 On-state Current versus On-state Voltage (Typical) (15 A and 25 A)
4.0
Positive or Negative Instantaneous On-state Current (iT) - Amps
9
TC = 25 C
8 7 6 5 4 3 2
0.8 A
IGT(TC = 25 C)
3.0
IGT
2.0
Ratio of
1.0
1A
1 0 0 0.6 0.8 1.0 1.2 1.4 1.6 1.8
-65
-40
-15
+25
+65
+125
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Case Temperature (TC) - C
Figure E2.8 On-state Current versus On-state Voltage (Typical) (0.8 A and 1 A)
20 18 16
Figure E2.11 Normalized DC Gate Trigger Current for All Quadrants versus Case Temperature
2.0
TC = 25 C
Positive or Negative Instantaneous On-state Current (iT) - Amps
14 12 10 8 6 4 2 0 0 0.6 0.8
6-10 A
4A
VGT(TC = 25 C)
1.5
VGT
1.0
Ratio of
.5
0
1.0 1.2 1.4 1.6 1.8
-65
-40
-15
+25
+65
+125
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Case Temperature (TC) - C
Figure E2.9 On-state Current versus On-state Voltage (Typical) (4 A, 6 A, 8 A, and 10 A)
Figure E2.12 Normalized DC Gate Trigger Voltage for All Quadrants versus Case Temperature
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Data Sheets
Triacs
1000
SUPPLY FREQUENCY: 60 Hz Sinusoidal LOAD: Resistive RMS ON-STATE CURRENT [lT(RMS)]: Maximum Rated Value at Specified Case Temperature
) - Amps
400 300 200 120 100 80 60 50 40 30 20 10
NOTES:
Peak Surge (Non-repetitive) On-state Current (l
TSM
1) Gate control may be lost during and immediately following surge current interval. 2) Overload may not be repeated until junction temperature has returned to steady-state rated value.
35 A Fast pak 25 A Fast pak 25 A T 15 A 10 A
O-22 0
8A 6A
4A
1A 0.8 A
1 1 10 100 1000
Surge Current Duration - Full Cycles
Figure E2.13 Peak Surge Current versus Surge Current Duration
4.0
8
INITIAL ON-STATE CURRENT = 200 mA DC 0.8 A - 10 A Devices = 400 mA DC 15 A - 25 A Devices
Devices with lGT = 10 mA
Typical Turn-on Time (tgt) - Sec
7 6 5 4 3 2 1 0
Devices with lGT = 25 mA
3.0
TC = 25 C
Devices with lGT = 50 mA
IH(TC = 25 C)
IH
2.0
Ratio of
1.0
-65
-40
-15
+25
+65
+125
0
25
50
75
100 125 150 175 200 225 250 275 300
Case Temperature (TC) - C
DC Gate Trigger Current (lGT) - mA
Figure E2.14 Normalized DC Holding Current versus Case Temperature
Figure E2.15 Turn-on Time versus Gate Trigger Current (Typical)
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Triacs
Data Sheets
4.0
Average On-state Power Dissipation [PD(AV)] - Watts
Average On-state Power Dissipation [PD(AV)] - Watts
1.5
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360
3.0
1.0
0.8 A 1A
0.5
2.0
4A 1.0
0 0 0.25 0.50 0.75 1.0 1.25
0 0 1.0 2.0 3.0 4.0
RMS On-state Current [IT(RMS)] - Amps
RMS On-state Current [IT(RMS)] - Amps
Figure E2.16 Power Dissipation (Typical) versus On-state Current (0.8 A and 1 A)
Average On-state Power Dissipation [PD(AV)] - Watts
Figure E2.19 Power Dissipation (Typical) versus RMS On-state Current (4 A)
18 16 14 12
6-10 A 15 A
10 8 6 4 2 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360
RMS On-state Current [lT(RMS)] - Amps
Figure E2.17 Power Dissipation (Typical) versus On-state Current (6 A to 10 A and 15 A)
Average On-state Power Dissipation [PD(AV)] - Watts
45 40 35 30
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360
25 A
25 20
25 A - 35 A Fastpaks
15 10 5 0 0 8 16 24 32 40
RMS On-state Current [lT(RMS)] - Amps
Figure E2.18 Power Dissipation (Typical) versus On-state Current (25 A to 35 A)
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U.
R L.
EC
Fi
O
IZ GN
71 63
ED
9
le
#E
E3
TO-220 Isolated
MT2
MT1
T
Quadrac
Internally Triggered Triacs (4 A to 15 A)
E3
General Description
Teccor's Quadrac devices are triacs that include a diac trigger mounted inside the same package. This device, developed by Teccor, saves the user the expense and assembly time of buying a discrete diac and assembling in conjunction with a gated triac. Also, the alternistor Quadrac device (QxxxxLTH) eliminates the need for a snubber network. The Quadrac device is a bidirectional AC switch and is gate controlled for either polarity of main terminal voltage. Its primary purpose is for AC switching and phase control applications such as speed controls, temperature modulation controls, and lighting controls where noise immunity is required. Triac current capacities range from 4 A to 15 A with voltage ranges from 200 V to 600 V. Quadrac devices are available in the TO-220 package. The TO-220 package is electrically isolated to 2500 V rms from the leads to mounting surface. 4000 V rms is available on special order. This means that no external isolation is required, thus eliminating the need for separate insulators and insulator-mounting steps and saving dollars over "hot tab" devices. All Teccor triac and diac chips have glass-passivated junctions to ensure long-term device reliability and parameter stability. Variations of devices in this data sheet are available for custom design applications. Consult the factory for more information.
Features
* * * * * Glass-passivated junctions Electrically-isolated package Internal trigger diac High surge capability -- up to 200 A High voltage capability -- 200 V to 600 V
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Quadrac
Data Sheets
Part No. IT(RMS)
(5) Isolated
Trigger Diac Specifications (T-MT1) VDRM
(1)
IDRM
(1) (10)
VTM
(1) (3)
VBO (7)
VBO (6)
[V ] (6)
IBO
CT (11)
MT1
T MT2
TO-220 See "Package Dimensions" section for variations. (12) Q2004LT
Volts MIN 200 400 600 200 400 600 400 600 200 400 600 400 600 200 400 600 400 600 200 400 600 400 600
TC = 25 C
mAmps TC = 100 C MAX
Volts TC = 125 C TC = 25 C MAX 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 Volts MAX 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 Volts MIN 33 33 33 33 33 33 33 33 33 33 33 33 33 33 33 33 33 33 33 33 33 33 33 MAX 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 Volts MIN 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 Amps MAX 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 Farads MAX 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1
0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05 0.05
0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5
4A
Q4004LT Q6004LT Q2006LT Q4006LT
6A
Q6006LT Q4006LTH Q6006LTH Q2008LT Q4008LT Q6008LT Q4008LTH Q6008LTH Q2010LT Q4010LT
8A
10 A
Q6010LT Q4010LTH Q6010LTH Q2015LT Q4015LT Q6015LT Q4015LTH Q6015LTH
15 A
Specific Test Conditions
[V] -- Dynamic breakback voltage (forward and reverse) VBO -- Breakover voltage symmetry CT -- Trigger firing capacitance di/dt -- Maximum rate-of-change of on-state current dv/dt -- Critical rate-of-rise of off-state voltage at rated VDRM gate open dv/dt(c) -- Critical rate-of-rise of commutation voltage at rated VDRM and IT(RMS) commutating di/dt = 0.54 rated IT(RMS)/ms; gate unenergized I2t -- RMS surge (non-repetitive) on-state current for period of 8.3 ms for fusing IBO -- Peak breakover current IDRM -- Peak off-state current gate open; VDRM = maximum rated value IGTM -- Peak gate trigger current (10 s Max) IH -- Holding current; gate open IT(RMS) -- RMS on-state current, conduction angle of 360 ITSM -- Peak one-cycle surge tgt -- Gate controlled turn-on time VBO -- Breakover voltage (forward and reverse)
VDRM -- Repetitive peak blocking voltage VTM -- Peak on-state voltage at maximum rated RMS current
General Notes
* * * * * All measurements are made at 60 Hz with resistive load at an ambient temperature of +25 C unless otherwise specified. Operating temperature range (TJ) is -40 C to +125 C. Storage temperature range (TS) is -40 C to +125 C. Lead solder temperature is a maximum of +230 C for 10 seconds maximum; 1/16" (1.59 mm) from case. The case temperature (TC) is measured as shown on dimensional outline drawings. See "Package Dimensions" section of this catalog.
Electrical Specification Notes
(1) (2) (3) (4) For either polarity of MT2 with reference to MT1 See Figure E3.1 for IH versus TC. See Figure E3.4 and Figure E3.5 for iT versus vT. See Figure E3.9 for surge ratings with specific durations.
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Data Sheets
Quadrac
IH
(1) (2)
ITSM
(4) (8)
dv/dt(c)
(1) (5) (8)
dv/dt
(1)
tgt
(6) (9)
I2t
IGTM
di/dt
(9)
Volts/Sec mAmps MAX 40 40 40 50 50 50 50 50 60 60 60 60 60 60 60 60 60 60 70 70 70 70 70 Amps 60/50Hz 55/46 55/46 55/46 80/65 80/65 80/65 80/65 80/65 100/83 100/83 100/83 100/83 100/83 120/100 120/100 120/100 120/100 120/100 200/167 200/167 200/167 200/167 200/167 Volts/Sec MIN 3 3 3 4 4 4 25 25 4 4 4 25 25 4 4 4 30 30 4 4 4 30 30 75 75 50 150 150 125 575 425 175 175 150 575 425 200 200 175 925 775 300 300 200 925 775 TC = TC = 100 C 125 C MIN 50 50 50 100 100 85 450 350 120 120 100 450 350 150 150 120 700 600 200 200 150 700 600 Sec TYP 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 12.5 12.5 12.5 26.5 26.5 26.5 26.5 26.5 41 41 41 41 41 60 60 60 60 60 166 166 166 166 166 1.2 1.2 1.2 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 50 50 50 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 100 100 100 100 100 Amps2Sec Amps Amps/Sec
See Figure E3.6, Figure E3.7, and Figure E3.8 for current rating at specific operating temperature. (6) See Figure E3.2 and Figure E3.3 for test circuit. (7) VBO = [+ VBO] - [- VBO] (8) See Figure E3.7 and Figure E3.8 for maximum allowable case temperature at maximum rated current. (9) Trigger firing capacitance = 0.1 F with 0.1 s rise time (10) TC = TJ for test conditions in off state (11) Maximum required value to ensure sufficient gate current (12) See package outlines for lead form configurations. When ordering special lead forming, add type number as suffix to part number.
(5)
Electrical Isolation
All Teccor isolated Quadrac packages withstand a minimum high potential test of 2500 V ac rms from leads to mounting tab over the operating temperature range of the device. The following isolation table shows standard and optional isolation ratings.
Electrical Isolation from Leads to Mounting Tab *
V AC RMS 2500 4000 TYPE Standard Optional **
* UL Recognized File #E71639 **For 4000 V isolation, use "V" suffix in part number.
Thermal Resistance (Steady State) RJC [RJA] C/W (TYP)
TYPE 4A 6A 8A 10 A 15 A Isolated TO-220 3.6 [50] 3.3 2.8 2.6 2.1
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Quadrac
Data Sheets
20
Positive or Negative Instantaneous On-state Current (iT) - Amps
18
2.0 INITIAL ON-STATE CURRENT = 200 mA DC 4 A to 10 A = 400 mA DC 15 A
TC = 25 C
16 14
IH(TC = 25 C)
1.5
6 A, 8 A, and 10 A
12 10 8 6 4
IH
1.0
Ratio of
.5
4A
2 0
0 -40 -15 +25 +65 +105 +125
Case Temperature (TC) - C
0
0.6
0.8
1.0
1.2
1.4
1.6
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Figure E3.1 Normalized DC Holding Current versus Case Temperature
Figure E3.4 On-state Current versus On-state Voltage (Typical) (4 A to 10 A)
Positive or Negative Instantaneous On-state Current (iT) - Amps
90 80
RL
TC = 25C
70 60 50
D.U.T.
MT2
15 A
40 30 20 10 0 0 0.6 0.8 1.0 1.2 1.4 1.6 1.8
120 V 60 Hz T
VC CT = 0.1 F
MT1
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Figure E3.2 Test Circuit
Figure E3.5 On-state Current versus On-state Voltage (Typical) (15 A)
120
VC +VBO V+
Maximum Allowable Ambient Temperature (TA) - C
100
4A
80
60
40
V-VBO
25 20 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
RMS On-state Current [IT(RMS)] - Amps
Figure E3.3 Test Circuit Waveforms
Figure E3.6 Maximum Allowable Ambient Temperature versus On-state Current
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Data Sheets
Quadrac
120
110
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawings
Average On-state Power Dissipation [PD(AV)] - Watts
130
4.0
Maximum Allowable Case Temperature (TC) - C
3.0 4A
100
4A
90
2.0
80
70
1.0
60 0
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360
0 0 1.0 2.0 3.0 4.0 5.0
0
.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
RMS On-state Current [IT(RMS)] - Amps
RMS On-state Current [IT(RMS)] - Amps
Figure E3.7 Maximum Allowable Case Temperature versus On-state Current (4 A)
Figure E3.10 Power Dissipation (Typical) versus On-state Current (4 A)
18
120
110
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawings
Average On-state Power Dissipation [PD(AV)] - Watts
130
Maximum Allowable Case Temperature (TC) - C
16
14
12
100 6A
15 A
10
15 A 6 A to 10 A
90
8
80
8A
10 A
6
70
4
60
2
0 0 2.0 4.0 6.0 8.0 10.0 12.0 14.0 16.0 18.0 20.0
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360
0 2 4 6 8 10 12 14 16
0
RMS On-state Current [IT(RMS)] - Amps
RMS On-state Current [IT(RMS)] - Amps
Figure E3.8 Maximum Allowable Case Temperature versus On-state Current (6 A to 15 A)
Figure E3.11 Power Dissipation (Typical) versus On-state Current (6 A to 10 A and 15 A)
200 120 100 80 60 50 40 30 20
Percentage of VBO Change - %
Peak Surge (Non-repetitive) On-state Current (ITSM) - Amps
NOTES: 1) Gates control may be lost during and immediately following surge current interval. 2) Overload may not be repeated until junction temperature has returned to steady state rated value.
+4 +2 0 -2 -4 -6 -8 -40 -20 0 +20 +40 +60 +80 +100 +120 +140
15 A 10 A
10 8 6 5 4 3 2
SUPPLY FREQUENCY: 60 Hz Sinusoidal LOAD: Resistive RMS ON-STATE CURRENT [IT(RMS)]: Maximum Rated Value at Specified Case Temperature
8A 6A
4A
1 1 2 3 4 5 6 8 10 20 3040 60 80 100 200 300 600 1000
Surge Current Duration - Full Cycles
Junction Temperature (TJ) - C
Figure E3.12 Normalized diac VBO versus Junction Temperature
Figure E3.9 Peak Surge Current versus Surge Current Duration
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Notes
l Se
ec
te
U.
L.
G O 1639 EC #E7 R
d P
Fi le
k ac
ag
* es
Z NI
ED
E4
*TO-220 *TO-218X
*TO-218
TO-252 D-Pak TO-263 D 2 Pak TO-251 V-Pak
MT2 MT1
G
Alternistor Triacs
(6 A to 40 A)
E4
General Description
Teccor offers bidirectional alternistors with current ratings from 6 A to 40 A and voltages from 200 V to 1000 V as part of Teccor's broad line of thyristors. Teccor's alternistor is specifically designed for applications that switch highly inductive loads. A special chip offers the same performance as two thyristors (SCRs) wired inverse parallel (back-to-back), providing better turn-off behavior than a standard triac. An alternistor may be triggered from a blocking to conduction state for either polarity of applied AC voltage with operating modes in Quadrants I, II, and III. This new chip construction provides two electrically separate SCR structures, providing enhanced dv/dt characteristics while retaining the advantages of a single-chip device. All alternistors have glass-passivated junctions to ensure longterm reliability and parameter stability. Teccor's glass-passivated junctions offer a reliable barrier against junction contamination. Teccor's TO-218X package is designed for heavy, steady powerhandling capability. It features large eyelet terminals for ease of soldering heavy gauge hook-up wire. All the isolated packages have a standard isolation voltage rating of 2500 V rms. Variations of devices covered in this data sheet are available for custom design applications. Consult the factory for further information.
Features
* * * * * High surge current capability Glass-passivated junctions 2500 V ac isolation for L, J, and K Packages High commutating dv/dt High static dv/dt
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Alternistor Triacs
Data Sheets
Part Number IT(RMS)
(4)(16)
MT2
Isolated
MT2
Non-isolated
VDRM
(1)
IGT
(3) (7) (15) (17)
IDRM
(1) (18)
MT2
G MT2
MT2
G MT2 MT1
MT1 MT2
G
MT1 G MT2
MT1
G MT2
MT1
mAmps TO-252 D-Pak TO-263 D2Pak Volts MIN 200 400 600 800 1000 200 400 600 800 1000 Q2006NH4 Q4006NH4 Q6006NH4 Q8006NH4 QK006NH4 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 Q2008NH4 Q4008NH4 Q6008NH4 Q8008NH4 QK008NH4 Q2010NH5 Q4010NH5 Q6010NH5 Q8010NH5 QK010NH5 Q2012NH5 Q4012NH5 Q6012NH5 Q8012NH5 QK012NH5 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 QI 10 10 10 10 10 35 35 35 35 35 35 35 35 35 35 10 10 10 10 10 35 35 35 35 35 35 35 35 35 35 50 50 50 50 50 50 50 50 50 50 QII MAX 10 10 10 10 10 35 35 35 35 35 35 35 35 35 35 10 10 10 10 10 35 35 35 35 35 35 35 35 35 35 50 50 50 50 50 50 50 50 50 50 QIII 10 10 10 10 10 35 35 35 35 35 35 35 35 35 35 10 10 10 10 10 35 35 35 35 35 35 35 35 35 35 50 50 50 50 50 50 50 50 50 50 TC = 25 C 0.01 0.01 0.01 0.01 0.02 0.01 0.01 0.01 0.01 0.02 0.01 0.01 0.01 0.01 0.02 0.01 0.01 0.01 0.01 0.02 0.01 0.01 0.01 0.01 0.02 0.01 0.01 0.01 0.01 0.02 0.01 0.01 0.01 0.01 0.02 0.01 0.01 0.01 0.01 0.02
mAmps TC = 100 C MAX 0.5 0.5 0.5 0.5 2 0.5 0.5 0.5 0.5 2 0.5 0.5 0.5 0.5 3 0.5 0.5 0.5 0.5 2 0.5 0.5 0.5 0.5 2 0.5 0.5 0.5 0.5 3 0.5 0.5 0.5 0.5 3 0.5 0.5 0.5 0.5 3 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 TC = 125 C 2 2 2 2 2 2 2 2
T0-220 MAX
TO-220
TO-251 V-Pak
See "Package Dimensions" section for variations. (11) Q2006VH3 Q2006DH3 Q4006VH3 Q6006VH3 Q8006VH3 QK006VH3 Q4006DH3 Q6006DH3 Q8006DH3 QK006DH3 Q2006DH4 Q4006DH4 Q6006DH4 Q8006DH4 QK006DH4
6A
Q2006VH4 Q4006VH4 Q6006VH4 Q8006VH4 QK006VH4 Q2006LH4 Q4006LH4 Q6006LH4 Q8006LH4 QK006LH4 Q2006RH4 Q4006RH4 Q6006RH4 Q8006RH4 QK006RH4 Q2008VH3 Q4008VH3 Q6008VH3 Q8008VH3 QK008VH3 Q2008VH4
Q2008DH3 Q4008DH3 Q6008DH3 Q8008DH3 QK008DH3 Q2008DH4 Q4008DH4 Q6008DH4 Q8008DH4 QK008DH4
8A
Q4008VH4 Q6008VH4 Q8008VH4 QK008VH4 Q2008LH4 Q4008LH4 Q6008LH4 Q8008LH4 QK008LH4 Q2010LH5 Q4010LH5 Q6010LH5 Q8010LH5 QK010LH5 Q2012LH5 Q4012LH5 Q6012LH5 Q8012LH5 QK012LH5 Q2008RH4 Q4008RH4 Q6008RH4 Q8008RH4 QK008RH4 Q2010RH5 Q4010RH5 Q6010RH5 Q8010RH5 QK010RH5 Q2012RH5 Q4012RH5 Q6012RH5 Q8012RH5 QK012RH5
10 A
12 A
See "General Notes" and "Electrical Specification Notes" on page E4 - 5.
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Data Sheets
Alternistor Triacs
VGT
(2) (6) (15) (17) (20)
VTM
(1) (5)
IH
(1) (8) (12)
IGTM
(14)
PGM
(14)
PG(AV)
ITSM
(9) (13)
dv/dt(c)
(1) (4) (13)
dv/dt
(1)
tgt
(10)
I2t
di/dt
(19)
Volts TC = 25 C MAX 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 Volts MAX 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 mAmps MAX 15 15 15 15 15 35 35 35 35 35 35 35 35 35 35 15 15 15 15 15 35 35 35 35 35 35 35 35 35 35 50 50 50 50 50 50 50 50 50 50 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 0.4 0.4 0.4 0.4 0.4 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.4 0.4 0.4 0.4 0.4 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 Amps Watts Watts
Amps 60/50 Hz 65/55 65/55 65/55 65/55 65/55 65/55 65/55 65/55 65/55 65/55 85/80 85/80 85/80 85/80 85/80 85/80 85/80 85/80 85/80 85/80 85/80 85/80 85/80 85/80 85/80 100/83 100/83 100/83 100/83 100/83 120/110 120/110 120/110 120/110 120/110 120/110 120/110 120/110 120/110 120/110 Volts/Sec MIN 20 20 20 20 20 25 25 25 25 25 25 25 25 25 25 20 20 20 20 20 25 25 25 25 25 25 25 25 25 25 30 30 30 30 30 30 30 30 30 30
Volts/Sec TC = 100 C 100 100 75 50 40 500 500 400 300 150 750 575 425 300 150 100 100 75 50 40 750 575 425 300 150 500 500 400 300 150 1150 1000 850 650 300 1150 1000 850 650 300 1000 750 650 500 1000 750 650 500 75 75 50 40 400 450 350 250 400 400 300 200 600 450 350 250 TC = 125 C 75 75 50 40 400 400 300 200 Sec TYP 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 17.5 17.5 17.5 17.5 17.5 17.5 17.5 17.5 17.5 17.5 30 30 30 30 30 30 30 30 30 30 30 30 30 30 30 41 41 41 41 41 60 60 60 60 60 60 60 60 60 60 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70 Amps2Sec Amps/Sec
MIN
See "General Notes" and "Electrical Specification Notes" on page E4 - 5.
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Alternistor Triacs
Data Sheets
Part Number IT(RMS)
(4)(16)
A
Isolated
MT2
Non-isolated
VDRM
(1)
IGT
(3) (7) (15) (17)
A
MT2 G MT2 MT1
MT1 MT2
G
KAG
K A
G
MT1 G MT2
mAmps TO-263 D2Pak Q2016NH3 Q4016NH3 Q6016NH3 Q8016NH3 QK016NH3 Q2016NH4 Q4016NH4 Q6016NH4 Q8016NH4 QK016NH4 Q2016NH6 Q4016NH6 Q6016NH6 Q8016NH6 QK016NH6 Q2025NH6 Q4025NH6 Q6025NH6 Q8025NH6 QK025NH6 Volts 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 200 400 600 QI 20 20 20 20 20 35 35 35 35 35 80 80 80 80 80 80 80 80 80 80 50 50 50 50 50 50 100 100 100 100 100 QII MAX 20 20 20 20 20 35 35 35 35 35 80 80 80 80 80 80 80 80 80 80 50 50 50 50 50 50 100 100 100 100 100 20 20 20 20 20 35 35 35 35 35 80 80 80 80 80 80 80 80 80 80 50 50 50 50 50 50 100 100 100 100 100 QIII
T0-220 MAX Q2016LH3 Q4016LH3 Q6016LH3 Q8016LH3 QK016LH3 Q2016LH4 Q4016LH4
TO-218 (16)
TO-218X
TO-220 Q2016RH3 Q4016RH3 Q6016RH3 Q8016RH3 QK016RH3 Q2016RH4 Q4016RH4 Q6016RH4 Q8016RH4 QK016RH4 Q2016RH6 Q4016RH6 Q6016RH6 Q8016RH6 QK016RH6
See "Package Dimensions" section for variations. (11)
16 A
Q6016LH4 Q8016LH4 QK016LH4 Q2016LH6 Q4016LH6 Q6016LH6 Q8016LH6 QK016LH6 Q2025L6 Q4025L6 Q6025L6 Q8025L6 QK025L6 Q2030LH5 Q2025K6 Q4025K6 Q6025K6 Q8025K6 QK025K6 Q2025J6 Q4025J6 Q6025J6 Q8025J6
25 A
Q2025R6 Q4025R6 Q6025R6 Q8025R6 QK025R6
30 A
Q4030LH5 Q6030LH5 Q2035RH5 Q4035RH5 Q6035RH5 Q2040K7 Q2040J7 Q4040J7 Q6040J7 Q8040J7 Q4040K7 Q6040K7 Q8040K7 QK040K7 Q2035NH5 Q4035NH5 Q6035NH5
35 A
200 400 600 200 400 600 800 1000
40 A
See "General Notes" and "Electrical Specification Notes" on page E4 - 5.
Test Conditions
di/dt -- Maximum rate-of-change of on-state current dv/dt -- Critical rate-of-rise of off-state voltage at rated VDRM gate open dv/dt(c) -- Critical rate-of-rise of commutation voltage at rated VDRM and IT(RMS) commutating di/dt = 0.54 rated IT(RMS)/ms; gate unenergized I2t -- RMS surge (non-repetitive) on-state current for period of 8.3 ms for fusing IDRM -- Peak off-state current gate open; VDRM = maximum rated value IGT -- DC gate trigger current in specific operating quadrants; VD = 12 V dc IGTM -- Peak gate trigger current
IH -- Holding current (DC); gate open IT(RMS) -- RMS on-state current conduction angle of 360 ITSM -- Peak one-cycle surge PG(AV) -- Average gate power dissipation PGM -- Peak gate power dissipation; IGT IGTM tgt -- Gate controlled turn-on time; IGT = 300 mA with 0.1 s rise time VDRM -- Repetitive peak blocking voltage VGT -- DC gate trigger voltage; VD = 12 V dc VTM -- Peak on-state voltage at maximum rated RMS current
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Data Sheets
Alternistor Triacs
IDRM
(1) (18)
VGT
VTM
IH
(1) (8) (12)
IGTM
(14)
PGM
(14)
PG(AV)
ITSM
(9) (13)
dv/dt(c)
(1) (4) (13)
dv/dt
(1)
tgt
(10)
I2t
di/dt
(19)
(2) (6) (1) (5) (15) (17) (20)
mAmps TC = 25 C 0.05 0.05 0.05 0.1 0.1 0.05 0.05 0.05 0.1 0.1 0.05 0.05 0.05 0.1 0.1 0.05 0.05 0.05 0.1 0.1 0.05 0.05 0.05 0.05 0.05 0.05 0.2 0.2 0.2 0.2 0.2 TC = TC = 100 C 125 C MAX 0.5 0.5 0.5 1 3 0.5 0.5 0.5 1 3 0.5 0.5 0.5 1 3 0.5 0.5 0.5 1 3 0.5 0.5 0.5 0.5 0.5 0.5 2 2 2 2 5 2 2 2 2 2 2 5 5 5 5 2 2 2 3 2 2 2 3 2 27 2 3 2 2 2 3
Volts TC = 25 C MAX 1.5 1.5 1.5 1.5 1.5 2 2 2 2 2 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2 2 2 2 2 2 2.5 2.5 2.5 2.5 2.5
Volts TC = 25 C mAmps MAX 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.8 1.8 1.8 1.8 1.8 1.4 1.4 1.4 1.5 1.5 1.5 1.8 1.8 1.8 1.8 1.8 MAX 35 35 35 35 35 50 50 50 50 50 70 70 70 70 70 100 100 100 100 100 75 75 75 75 75 75 120 120 120 120 120 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 4 4 4 4 4 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 40 40 40 40 40 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.8 0.8 0.8 0.8 0.8 Amps Watts Watts
Amps 60/50 Hz 200/167 200/167 200/167 200/167 200/167 200/167 200/167 200/167 200/167 200/167 200/167 200/167 200/167 200/167 200/167 250/208 250/208 250/208 250/208 250/208 350/290 350/290 350/290 350/290 350/290 350/290 400/335 400/335 400/335 400/335 400/335 Volts/Sec MIN 20 20 20 20 20 25 25 25 25 25 30 30 30 30 30 30 30 30 30 30 20 20 20 20 20 20 50 50 50 50 50
Volts/Sec TC = TC = 100 C 125 C MIN 500 400 300 275 200 650 600 500 425 300 875 875 800 700 350 875 875 800 700 400 650 600 500 650 600 500 1100 1100 1000 900 500 500 475 400 500 475 400 700 700 625 575 600 600 520 475 600 600 520 475 400 350 250 200 500 475 400 350 Sec TYP 3 3 3 3 3 3 3 3 3 3 5 5 5 5 5 5 5 5 5 5 3 3 3 3 3 3 5 5 5 5 5 166 166 166 166 166 166 166 166 166 166 166 166 166 166 166 259 259 259 259 259 508 508 508 508 508 508 664 664 664 664 664 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 150 150 150 150 150 Amps2Sec Amps/Sec
General Notes
* * * * * All measurements are made at 60 Hz with a resistive load at an ambient temperature of +25 C unless specified otherwise. Operating temperature range (TJ) is -40 C to +125 C. Storage temperature range (TS) is -40 C to +125 C. Lead solder temperature is a maximum of 230 C for 10 seconds maximum 1/16" (1.59 mm) from case. The case temperature (TC) is measured as shown in the dimensional outline drawings. See "Package Dimensions" section.
Electrical Specification Notes
(1) (2) (3) (4) For either polarity of MT2 with reference to MT1 terminal For either polarity of gate voltage (VGT) with reference to MT1 terminal See Gate Characteristics and Definition of Quadrants. See Figure E4.1 through Figure E4.4 for current rating at specific operating temperature and Figure 4.16 for free air rating (no heat sink). See Figure E4.5 and Figure E4.6 for iT and vT. See Figure E4.7 for VGT versus TC. See Figure E4.8 for IGT versus TC. See Figure E4.9 for IH versus TC. See Figure E4.10 and Figure E4.11 for surge rating with specific durations.
(5) (6) (7) (8) (9)
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Alternistor Triacs
Data Sheets
(10) See Figure E4.12 for tgt versus IGT. (11) See package outlines for lead form configurations. When ordering special lead forming, add type number as suffix to part number. (12) Initial on-state current = 400 mA dc for 16 A to 40 A devices and 100 mA for 6 A to 12 A devices. (13) See Figure E4.1 through Figure E4.4 for maximum allowable case temperature at maximum rated current. (14) Pulse width 10 s; IGT IGTM (15) For 6 A to 12 A devices, RL = 60 ; 16 A and above, RL = 30 (16) 40 A pin terminal leads on K package can run 100 C to 125 C. (17) Alternistor does not turn on in Quadrant IV. (18) TC = TJ for test conditions in off state (19) IGT = 200 mA for 6 A to 12 A devices and 500 mA for 16 A to 40 A devices with gate pulse having rise time of 0.1 s. (20) Minimum non-trigger VGT at 125 C is 0.2 V.
(-) (-)
ALL POLARITIES ARE REFERENCED TO MT1 MT2 POSITIVE (Positive Half Cycle)
MT2 IGT GATE
+
MT2
(+)
IGT GATE MT1
MT1
IGT
IGT GATE
REF MT2
QII QI QIII QIV
(+)
REF
+
MT2 IGT GATE MT1
IGT
MT1 REF
Gate Characteristics
Teccor triacs may be turned on in the following ways: * * In-phase signals (with standard AC line) using Quadrants I and III Application of unipolar pulses (gate always negative), using Quadrants II and III with negative gate pulses
REF MT2 NEGATIVE (Negative Half Cycle) NOTE: Alternistors will not operate in QIV
-
Definition of Quadrants
Electrical Isolation
Teccor's isolated alternistor packages withstand a minimum high potential test of 2500 V ac rms from leads to mounting tab, over the operating temperature range of the device. The following isolation table shows standard and optional isolation ratings.
Electrical Isolation
In all cases, if maximum surge capability is required, gate pulses should be a minimum of one magnitude above minimum IGT rating with a steep rising waveform (1 s rise time). If QIV and QI operation is required (gate always positive), see Figure AN1002.8, "Amplified Gate" Thyristor Circuit.
from Leads to Mounting Tab *
V AC RMS 2500 4000
TO-218 Isolated
Standard N/A
TO-220 Isolated
Standard Optional **
TO-218X Isolated
Standard N/A
* UL Recognized File E71639 ** For 4000 V isolation, use V suffix in part number.
Thermal Resistance (Steady State) R JC [R JA] (TYP.) C/W
Package Code K J L R D V N
Type
TO-218 Isolated * 6A 8A 10 A 12 A 16 A 25 A 30 A 35 A 40 A
TO-218X Isolated *
1.35
1.32
TO-220 Isolated ** 3.3 [50] 2.8 2.6 2.3 2.1 2.0 2.3
TO-220 Non-Isolated 1.80 [45] 1.50 1.30 1.20 1.10 0.87 0.85
TO-252 D-Pak 2.1 1.8
TO-251 V-Pak 2.3 [64] 2.1
TO-263 D2Pak 1.80 1.50 1.30 1.20 1.10 0.87
0.97
0.95
* UL Recognized Product per UL File E71639 ** For 4000 V isolation, use V suffix in part number.
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Data Sheets
Alternistor Triacs
Maximum Allowable Case Temperature (TC) - C
130 120 110 100 90 80 70 60 0 0 2 4 6 8 10 12 14 CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing 6A TO-220 (NON-ISOLATED) AND D2 PAK 6A TO-220 (ISOLATED)
130
Maximum Allowable Case Temperature (TC) - C
10A TO-220 (NON-ISOLATED) AND D2 PAK 12A TO-220 (ISOLATED)
120
110
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing 35 A TO-220 (Non-isolated) and TO-263 25 A and 30 A TO-220 (Isolated)
100
90
40 A TO-218 (Isolated)
80 25 A TO-220 (Non-isolated) TO-218 (Isolated) TO-263
70
60
50 0 10 20 25 30 40 50
RMS On-State Current [lT(RMS)] - AMPS
RMS On-state Current [lT(RMS)] - Amps
Figure E4.1 Maximum Allowable Case Temperature versus On-state Current (6 A to 12 A)
Figure E4.4 Maximum Allowable Case Temperature versus On-state Current (25 A to 40 A)
20
130 120 12 A TO-220 (Non-isolated) and TO-263 10 A TO-220 (Isolated)
18
Positive or Negative Instantaneous On-state Current (iT) - Amps
Maximum Allowable Case Temperature (TC) - C
16 14 12 10 8 6 4 2 0 0
TC = 25 C
110 100 90 80 70 60 0 0 2 4 6 8 8 A TO-220 (Isolated) 8 A TO-220 (Non-isolated), TO-263, TO-251, and TO-252
6 A to 12 A Devices
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing 10 12 14
0.6
0.8
1.0
1.2
1.4
1.6
RMS On-state Current [lT(RMS)] - Amps
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Figure E4.2 Maximum Allowable Case Temperature versus On-state Current (8 A to 12 A)
Figure E4.5 On-state Current versus On-state Voltage (Typical) (6 A to 12 A)
130
90 80
Maximum Allowable Case Temperature (T C ) - C
120 110
TO
16 A
-22
Positive or Negative Instantaneous On-state Current (i ) - Amps
16A
TC = 25C
70 60
0( No
-22
n-is
100 90 80 70 60 0 0 5
0( Iso
lat
ed
63
T
TO
ola
ted
)a nd TO -2
40 A Devices
50 40
)
25 A to 35 A Devices
30 20
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing
10 15
16 A Devices
10 0 0 0.6 0.8 1.0 1.2 1.4
T
1.6
1.8
RMS On-state Current [I T(RMS) ] - Amps
Figure E4.3 Maximum Allowable Case Temperature versus On-state Current (16 A)
Positive or Negative Instantaneous On-state Voltage (v ) - Volts
Figure E4.6 On-state Current versus On-state Voltage (Typical) (16 A to 40 A)
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Alternistor Triacs
Data Sheets
200
2.0
Peak Surge (Non-Repetitive) On-state Current (ITSM) - Amps
V GT (T C = 25 C)
120 100 80 60 50 40 30 20
10 A to 12 A Devices 8 A Devices
Notes: 1) Gate control may be lost during and immediately following surge current interval 2) Overload may not be repeated until junction temperature has returned to steady state rated value.
1.5
V GT
8 A TO-251 and TO-252 6 A Devices 6 A TO-251 and TO-252
1.0
Ratio of
.5
10 8 6 5 4 3 2
0 -65
-40
-15
+25
+65
+125
SUPPLY FREQUENCY: 60 Hz Sinusoidal LOAD: Resistive RMS ON-STATE CURRENT [IT(RMS)]: Maximum Rated Value at Specified Case Temperature
1 1 2 3456 8 10 20 30 40 60 80 100 200 300 600 1000
Case Temperature (T C ) - C
Surge Current Duration - Full Cycles
Figure E4.7 Normalized DC Gate Trigger Voltage for all Quadrants versus Case Temperature
Figure E4.10 Peak Surge Current versus Surge Current Duration (6 A to 12 A)
1000
Peak Surge (Non-repetitive) On-state Current (I TSM ) - Amps
4.0
I GT (T C = 25 C)
400 300 250 200
SUPPLY FREQUENCY: 60Hz Sinusoidal LOAD: Resistive RMS ON-STATE CURRENT [I T(RMS) ]: Maximum Rated Value at Specified Case Temperature
3.0
I GT
40 A Devices 35 A Devices
2.0
100 80 60 50 40 30 20
30 A Devices
Notes: 1) Gate control may be lost during and immediately following surge current interval. 2) Overload may not be repeated until junction temperature has returned to steady-state rated value.
Ratio of
1.0
25 A Devices 16 A Devices
0 -65
-40
-15
+25
+65
+125
10 1
Case Temperature (T C ) - C
10
100
1000
Surge Current Duration - Full Cycles
Figure E4.8 Normalized DC Gate Trigger Current for all Quadrants versus Case Temperature
Figure E4.11 Peak Surge Current versus Surge Current Duration (16 A to 40 A)
4.0
INITIAL ON-STATE CURRENT = 400 mA dc 16 A to 40 A Devices = 100 mA dc 6 to 12A Devices
10
I H (T C = 25 C)
Typical Turn-on Time (t gt ) - s
3.0
8 I GT = 80 to 100 mA 6
IH
2.0
4 I GT = 50 mA 2 I GT = 10 mA to 35 mA
Ratio of
1.0
0 -65
0
0
100
200
300
400
500
-40
-15
+25
+65
+125
Case Temperature (T C ) - C
Figure E4.9 Normalized DC Holding Current versus Case Temperature
DC Gate Trigger Current (I GT ) - mA
Figure E4.12 Turn-on Time versus Gate Trigger Current (Typical)
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Data Sheets
Alternistor Triacs
18
120
16
Maximum Allowable Ambient Temperature (TA) - C
Average On-state Power Dissipation [PD(AV)] - Watts
14 12 10 8
100
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 FREE AIR RATING - NO HEATSINK
80
6A to 12A Devices
6 4 2 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
TO-220 Devices
60
TO-251 Devices
40
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360
25 20 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
RMS On-state Current [lT(RMS)] - AmpsS
RMS On-state Current [IT (RMS)] - Amps
Figure E4.13 Power Dissipation (Typical) versus On-state Current (6 A to 12 A)
Figure E4.16 Maximum Allowable Ambient Temperature versus On-state Current
18
CURRENT WAVEFORM: Sinusoidal
Average On-state Power Dissipation [P D (AV) ] - Watts
16 LOAD: Resistive or inductive
CONDUCTION ANGLE: 360
14 12 10 8 6 4 2 0 0 2 4 6 8 10 12 14 16 RMS On-state Current [I T(RMS) ] - Amps 16A Devices
Figure E4.14 Power Dissipation (Typical) versus On-state Current (16 A)
45
Current Waveform: Sinusoidal
Average On-State Power Dissipation [P D(AV) ]--Watts
40 Load: Resistive or Inductive 35 30
25 A
Conduction Angle: 360
25 20 15 10 5 0 0 4 8
30 A and 35 A Devices 40 A
12 16 20 24 28 32 36 40
RMS On-State Current [I T(RMS) ]--Amps
Figure E4.15 Power Dissipation (Typical) versus On-state Current (25 A to 40 A)
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Notes
l Se
ec
te
U.
L.
G O 1639 EC #E7 R
d P
Fi le
k ac
ag
* es
Z NI
ED
E5
TO-92 *TO-220 Isolated
3-lead Compak TO-202
TO-252 D-Pak
TO-251 V-Pak
A
K
G
Sensitive SCRs
(0.8 A to 10 A)
E5
General Description
The Teccor line of sensitive SCR semiconductors are half-wave unidirectional, gate-controlled rectifiers (SCR-thyristor) which complement Teccor's line of power SCRs. This group of packages offers ratings of 0.8 A to 10 A, and 200 V to 600 V with gate sensitivities of 12 A to 500 A. For gate currents in the 10 mA to 50 mA ranges, see "SCRs" section of this catalog. The TO-220 and TO-92 are electrically isolated where the case or tab is internally isolated to allow the use of low-cost assembly and convenient packaging techniques. Teccor's line of SCRs features glass-passivated junctions to ensure long-term device reliability and parameter stability. Teccor's glass offers a rugged, reliable barrier against junction contamination. Tape-and-reel packaging is available for the TO-92 package. Consult the factory for more information. Variations of devices covered in this data sheet are available for custom design applications. Consult the factory for more information.
Features
* * * * Electrically-isolated TO-220 package High voltage capability -- up to 600 V High surge capability -- up to 100 A Glass-passivated chip
Compak Features
* * * * * Surface mount package -- 0.8 A series New small-profile three-leaded Compak package Four gate sensitivities available Packaged in embossed carrier tape with 2,500 devices per reel Can replace SOT-223
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Sensitive SCRs
Data Sheets
Part Number
Non-isolated
A
IT
(1)
VDRM & VRRM
IGT
(2) (12) (14) (18)
IDRM & IRRM
(20) (21)
VTM
(3) (10)
A
G
A A
A
G
TYPE
K G A
K A G
K
K
K
A
G
TO-92
TO-202
TO-251 V-Pak
Compak
TO-252 D-Pak
Amps IT(RMS) IT(AV) MAX 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 0.8 0.51 1.5 0.95 1.5 0.95 1.5 0.95 4 2.5 4 2.5 4 2.5 4 2.5 4 2.5 4 2.5 4 2.5 4 2.5 4 2.5 4 2.5 4 2.5 4 2.5 Volts MIN 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 Amps MAX 12 12 12 50 50 50 200 200 200 500 500 500 200 200 200 12 12 12 50 50 50 500 500 500 200 200 200 200 200 200 200 200 500 500 500 50 50 50 200 200 200
See "Package Dimensions" section for variations. (11) S2S1 S4S1 S6S1 S2S2 S4S2 S6S2 S2S S4S S6S S2S3 S4S3 S6S3 EC103B EC103D EC103M EC103B1 EC103D1 EC103M1 EC103B2 EC103D2 EC103M2 EC103B3 EC103D3 EC103M3 2N5064 2N6565 TCR22-4 TCR22-6 TCR22-8 T106B1 T106D1 T106M1 T107B1 T107D1 T107M1 S2004VS1 S4004VS1 S6004VS1 S2004VS2 S4004VS2 S6004VS2 S2004DS1 S4004DS1 S6004DS1 S2004DS2 S4004DS2 S6004DS2
0.8 A
1.5 A
4A
Amps TC or TL = TC or TL = TC or TL = 25 C 100 C 110 C MAX 2 100 2 100 2 100 2 100 2 100 2 100 2 100 2 100 2 100 2 100 2 100 2 100 1 50 1 50 2 100 1 50 1 50 2 100 1 50 1 50 2 100 1 50 1 50 2 100 1 50 1 100 1 100 1 100 2 100 2 100 2 100 2 100 2 100 2 100 2 100 2 100 2 100 2 100 2 100 2 100 2 100
Volts MAX 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.5 1.5 1.5 2.2 2.2 2.2 2.5 2.5 2.5 1.6 1.6 1.6 1.6 1.6 1.6
See "General Notes" on page E5 - 4 and "Electrical Specifications Notes" on page E5 - 5
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Data Sheets
Sensitive SCRs
.
VGT
(4) (12) (22)
IH
(5) (15) (16) (19)
IGM
(17)
VGRM
PGM
(17)
PG(AV)
ITSM
(6) (7) (13)
dv/dt
di/dt
tgt
(8)
tq
(9)
l2t
Volts TC or TL = TC or TL = TC or TL = mAmps -40 C 25 C 110 C MAX MAX 1.2 0.8 0.2 5 1.2 0.8 0.2 5 1.2 0.8 0.2 5 1.2 0.8 0.25 5 1.2 0.8 0.25 5 1.2 0.8 0.25 5 1.2 0.8 0.25 5 1.2 0.8 0.25 5 1.2 0.8 0.25 5 1.2 0.8 0.25 8 1.2 0.8 0.25 8 1.2 0.8 0.25 8 1.2 0.8 0.25 5 1.2 0.8 0.25 5 1.2 0.8 0.25 5 1.2 0.8 0.2 5 1.2 0.8 0.2 5 1.2 0.8 0.2 5 1.2 0.8 0.25 5 1.2 0.8 0.25 5 1.2 0.8 0.25 5 1.2 0.8 0.25 8 1.2 0.8 0.25 8 1.2 0.8 0.25 8 1.2 0.8 0.25 5 1.2 0.8 0.25 5 1 0.8 0.25 5 1 0.8 0.25 5 1 0.8 0.25 5 1 0.8 0.2 5 1 0.8 0.2 5 1 0.8 0.2 5 1 0.8 0.2 6 1 0.8 0.2 6 1 0.8 0.2 6 1 0.8 0.2 4 1 0.8 0.2 4 1 0.8 0.2 4 1 0.8 0.2 6 1 0.8 0.2 6 1 0.8 0.2 6
Amps Amps 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Volts MIN 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6 Watts 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Watts 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 60/50 Hz 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 20/16 30/25 30/25 30/25 30/25 30/25 30/25 Volts/Sec MIN 20 20 10 25 25 10 30 30 15 40 40 20 30 30 15 20 20 10 25 25 10 40 40 20 25 25 60 40 30 TYP (23) 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 Amps/Sec Sec TYP 2 2 2 3 3 3 4 4 4 5 5 5 3.5 3.5 3.5 2 2 2 3 3 3 5 5 5 2.2 2.2 3.5 3.5 3.5 4 4 4 5 5 5 3 3 3 4 4 4 Sec MAX 60 60 60 60 60 60 50 50 50 45 45 45 50 50 50 60 60 60 60 60 60 45 45 45 60 60 50 50 50 50 50 50 45 45 45 50 50 50 50 50 50 Amps2/Sec 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 3.7 3.7 3.7 3.7 3.7 3.7
8 8 8 8 8 8 8 8 8 8 8 8
See "General Notes" on page E5 - 4 and "Electrical Specifications Notes" on page E5 - 5
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Sensitive SCRs
Data Sheets
Part Number
Isolated
A
Non-isolated
A
A G A K
IT
(1)
VDRM & VRRM
IGT
(2) (12)
IDRM & IRRM
(20) (21)
VTM
(3) (10)
TYPE
K A
G
K A
G
K
A
G
TO-220
TO-202
TO-251 V-Pak
TO-252 D-Pak
Amps IT(RMS) MAX 6 6 6 6 6 6 8 8 8 8 8 8 10 10 10 10 10 10 IT(AV) MAX 3.8 3.8 3.8 3.8 3.8 3.8 5.1 5.1 5.1 5.1 5.1 5.1 6.4 6.4 6.4 6.4 6.4 6.4 Volts MIN 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 Amps MAX 200 200 200 500 500 500 200 200 200 500 500 500 200 200 200 500 500 500
Amps TC = 25 C MAX 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 TC = 110 C MAX 250 250 250 250 250 250 250 250 250 250 250 250 250 250 250 250 250 250 Volts MAX 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6
See "Package Dimensions" section for variations. (11) S2006LS2 S4006LS2 S6006LS2 S2006LS3 S4006LS3 S6006LS3 S2008LS2 S4008LS2 S6008LS2 S2008LS3 S4008LS3 S6008LS3 S2010LS2 S4010LS2 S6010LS2 S2010LS3 S4010LS3 S6010LS3 S2006FS21 S4006FS21 S6006FS21 S2006FS31 S4006FS31 S6006FS31 S2008FS21 S4008FS21 S6008FS21 S2008FS31 S4008FS31 S6008FS31 S2010FS21 S4010FS21 S6010FS21 S2010FS31 S4010FS31 S6010FS31 S2006VS2 S4006VS2 S6006VS2 S2006VS3 S4006VS3 S6006VS3 S2008VS2 S4008VS2 S6008VS2 S2008VS3 S4008VS3 S6008VS3 S2010VS2 S4010VS2 S6010VS2 S2010VS3 S4010VS3 S6010VS3 S2006DS2 S4006DS2 S6006DS2 S2006DS3 S4006DS3 S6006DS3 S2008DS2 S4008DS2 S6008DS2 S2008DS3 S4008DS3 S6008DS3 S2010DS2 S4010DS2 S6010DS2 S2010DS3 S4010DS3 S6010DS3
6A
8A
10 A
Specific Test Conditions
di/dt -- Maximum rate-of-change of on-state current; IGT = 50 mA pulse width 15 sec with 0.1 s rise time dv/dt -- Critical rate-of-rise of forward off-state voltage I2t -- RMS surge (non-repetitive) on-state current for period of 8.3 ms for fusing IDRM and IRRM -- Peak off-state current at VDRM and VRRM IGT -- DC gate trigger current VD = 6 V dc; RL = 100 IGM -- Peak gate current IH -- DC holding current; initial on-state current = 20 mA IT -- Maximum on-state current ITSM -- Peak one-cycle forward surge current PG(AV) -- Average gate power dissipation PGM -- Peak gate power dissipation tgt -- Gate controlled turn-on time gate pulse = 10 mA; minimum width = 15 S with rise time 0.1 s tq -- Circuit commutated turn-off time VDRM and VRRM -- Repetitive peak off-state forward and reverse voltage VGRM -- Peak reverse gate voltage VGT -- DC gate trigger voltage; VD = 6 V dc; RL = 100 VTM -- Peak on-state voltage
General Notes
* Teccor 2N5064 and 2N6565 Series devices conform to all JEDEC registered data. See specifications table on pages E5 - 2 and E5 - 3. The case lead temperature (TC or TL) is measured as shown on dimensional outline drawings in the "Package Dimensions" section of this catalog. All measurements (except IGT) are made with an external resistor RGK = 1 k unless otherwise noted. All measurements are made at 60 Hz with a resistive load at an ambient temperature of +25 C unless otherwise specified. Operating temperature (TJ) is -65 C to +110 C for EC Series devices, -65 C to +125 C for 2N Series devices, -40 C to +125 C for "TCR" Series, and -40 C to +110 C for all others. Storage temperature range (TS) is -65 C to +150 C for TO-92 devices, -40 C to +150 C for TO-202 and Compak devices, and -40 C to +125 C for all others. Lead solder temperature is a maximum of +230 C for 10 seconds maximum 1/16" (1.59 mm) from case.
*
* * *
*
*
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Data Sheets
Sensitive SCRs
VGT
(4) (12) (22)
IH
(5) (19)
IGM
(17)
VGRM
PGM
(17)
PG(AV)
ITSM
(6) (13)
dv/dt
di/dt
tgt
(8)
tq
(9)
l2t
TC = -40 C 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
Volts TC = 25 C MAX 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8
Volts/Sec TC = 110 C 0.25 0.25 0.25 0.25 0.25 0.25 0.25 0.25 0.25 0.25 0.25 0.25 0.25 0.25 0.25 0.25 0.25 0.25 mAmps MAX 6 6 6 8 8 8 6 6 6 8 8 8 6 6 6 8 8 8 Amps 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Volts MIN 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6 Watts 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Watts 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 Amps 60/50 Hz 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 TC = 110 C TYP 10 8 8 10 8 8 10 8 8 10 8 8 10 8 8 10 8 8 Amps/Sec 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 Sec TYP 4 4 4 5 5 5 4 4 4 5 5 5 4 4 4 5 5 5 Sec MAX 50 50 50 45 45 45 50 50 50 45 45 45 50 50 50 45 45 45 Amps2Sec 41 41 41 41 41 41 41 41 41 41 41 41 41 41 41 41 41 41
Electrical Specifications Notes
(1) (2) (3) (4) (5) (6) (7) See Figure E5.1 through Figure E5.9 for current ratings at specified operating temperatures. See Figure E5.10 for IGT versus TC or TL. See Figure E5.11 for instantaneous on-state current (iT) versus onstate voltage (vT) TYP. See Figure E5.12 for VGT versus TC or TL. See Figure E5.13 for IH versus TC or TL. For more than one full cycle, see Figure E5.14. 0.8 A to 4 A devices also have a pulse peak forward current onstate rating (repetitive) of 75 A. This rating applies for operation at 60 Hz, 75 C maximum tab (or anode) lead temperature, switching from 80 V peak, sinusoidal current pulse width of 10 s minimum, 15 s maximum. See Figure E5.20 and Figure E5.21. See Figure E5.15 for tgt versus IGT. Test conditions as follows: - TC or TL 80 C, rectangular current waveform - Rate-of-rise of current 10 A/s - Rate-of-reversal of current 5 A/s - ITM = 1 A (50 s pulse), Repetition Rate = 60 pps - VRRM = Rated - VR = 15 V minimum, VDRM = Rated - Rate-of-rise reapplied forward blocking voltage = 5 V/s - Gate Bias = 0 V, 100 (during turn-off time interval)
(10) Test condition is maximum rated RMS current except TO-92 devices are 1.2 APK; T106/T107 devices are 4 APK. (11) See package outlines for lead form configurations. When ordering special lead forming, add type number as suffix to part number. (12) VD = 6 V dc, RL = 100 (See Figure E5.19 for simple test circuit for measuring gate trigger voltage and gate trigger current.) (13) See Figure E5.1 through Figure E5.9 for maximum allowable case temperature at maximum rated current. (14) IGT = 500 A maximum at TC = -40 C for T106 devices (15) IH = 10 mA maximum at TC = -65 C for 2N5064 Series and 2N6565 Series devices (16) IH = 6 mA maximum at TC = -40 C for T106 devices (17) Pulse Width 10 s (18) IGT = 350 A maximum at TC = -65 C for 2N5064 Series and 2N6565 Series devices (19) Latching current can be higher than 20 mA for higher IGT types. Also, latching current can be much higher at -40 C. See Figure E5.18. (20) TC or TL = TJ for test conditions in off state (21) IDRM and IRRM = 50 A for 2N5064 and 100 A for 2N6565 at 125 C (22) TO-92 devices specified at -65 C instead of -40 C (23) TC = 110 C
(8) (9)
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E5 - 5
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Sensitive SCRs
Data Sheets
Thermal Resistance (Steady State) RJC [R JA] C/W (TYPICAL)
Package Code
E L F2 F C D V
Type
TO-92 0.8 A 1.5 A 4.0 A 6.0 A 8.0 A 10.0 A 75 [160] 50 [160]
TO-220
TO-202 Type 2, 4, & 41
TO-202 Type 1 & 3
Compak 60*
TO-252 D-Pak
TO-251 V-Pak
10 [100] 4.0 [65] 3.4 3.0
6.2 [80] 4.3 3.9 3.4
3.0 1.8 1.5 1.45
3.8 [85] 2.4 2.1 1.72
*Mounted on 1
cm 2 copper
foil surface; two-ounce copper foil
Electrical Isolation
Maximum Allowable Case Temperature (TC) - C
Teccor's isolated sensitive SCRs will withstand a minimum high potential test of 2500 V ac rms from leads to mounting tab over the device's operating temperature range. The following table shows other standard and optional isolation ratings.
Electrical Isolation * from Leads to Mounting Tab V AC RMS TO-220 Standard 2500 Optional ** 4000
*UL Recognized File #E71639 **For 4000 V isolation, use "V" suffix in part number.
130 120 110 100 90 80 70 60 TCR22 Devices 50 40 0 0.5 1.0 1.5 2.0 2.6 2.5 3.0 3.5 4.0 T106 and T107 Type 2 and 4 4 A TO-251 and TO-252 CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measured as Shown on Dimensional Drawing
T106 and T107 Type 1 and 3
RMS On-state Current [IT(RMS)] - Amps
130 120
Maximum Allowable Case Temperature (TC) - C
110 100
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measured as Shown on Dimensional Drawing JEDEC 2N Series
Figure E5.2 Maximum Allowable Case Temperature versus RMS On-state Current
130
Maximum Allowable Case Temperature (TC) - C
90 80
120 110 100
EC Series
70
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measured as Shown on Dimensional Drawing
Compak
60 50 0.1
JEDEC 2N Series 90 80 70 60 50
0.51
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
RMS On-State Current [IT(RMS)] - Amps
EC Series Compak
Figure E5.1 Maximum Allowable Case Temperature versus RMS On-state Current
0
0.1
0.2
0.3
0.4
0.5
0.6
Average On-state Current [IT(AV)] - Amps
Figure E5.3 Maximum Allowable Case Temperature versus Average On-state Current
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Data Sheets
Sensitive SCRs
140
130 CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measured as Shown on Dimensional Drawing
Maximum Allowable Ambient Temperature (TA) - C
120
120
Maximum Allowable Case Temperature (TC) - C
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 FREE AIR RATING
110 100 90 80 70 60 50 40 0 0.5 TCR22 Devices
100 T106/T107 TO-202 Type 1 and 3
80
T106 and T107 T106 and T107 Type 2 and 4 Type 1 and 3
60 TO-220 40 T106/T107 TO-202 Type 2 and 4 and TO-251 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4
0.95
1.65
1.9
2.54
1.0
1.5
2.0
2.5
3.0
20
Average On-state Current [IT(AV)] - Amps
Average On-state Current [IT(AV)] - Amps
Figure E5.4 Maximum Allowable Case Temperature versus Average On-state Current
Figure E5.7 Maximum Allowable Ambient Temperature versus Average On-state Current
Maximum Allowable Ambient Temperature (TA) - C
140
120
Maximum Allowable Case Temperature (TC) - C
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 FREE AIR RATING
115 110 105 100 95 90 85 80 0 2 4 6 8 10 6 A TO-220 and TO-202 8 A TO-220 and TO-202 10 A TO-220 and TO-202 6 A TO-251 and TO-252
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 TEMPERATURE: Measured as Shown on Dimensional Drawings
100
EC Series IT(RMS)
8 A TO-251 and TO-252 10 A TO-251 and TO-252
80
1.5 A Devices and JEDEC 2N Series IT(RMS) 1.5 A and JEDEC 2N Series IT(AV) and EC Series IT(AV)
60
40
20 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
RMS On-state Current [IT(RMS)] - Amps
On-state Current - Amps
Figure E5.5 Maximum Allowable Ambient Temperature versus On-state Current
Figure E5.8 Maximum Allowable Case Temperature versus RMS On-state Current
140
Maximum Allowable Ambient Temperature (TA) - C
120
100
Maximum Allowable Case Temperature (TC) - C
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 FREE AIR RATING
110 6 A TO-251 and TO-252
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measured as Shown on Dimensional Drawings
105
100 6 A TO-220 and TO-202 8 A TO-220 and TO-202 10 A TO-220 and TO-202 8 A TO-251 and TO-252 10 A TO-251 and TO-252
80
T106/T107 TO-202 Type 1 and 3
95
60
T106/T107 TO-202 Type 2 and 4 and TO-251 TO-220
90
40
85
20 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
80 0 1 2 3 4 5 6 7
RMS On-state Current [IT(RMS)] - Amps
Average On-state Current [IT(AV)] - Amps
Figure E5.6 Maximum Allowable Ambient Temperature versus RMS On-state Current
Figure E5.9 Maximum Allowable Case Temperature versus Average On-state Current
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Sensitive SCRs
Data Sheets
9.0 8.0 See General Notes for specific device operating temperature range.
4.0 See General Notes for specific operating temperature range.
= 25 C)
IH(TC
IGT (TC = 25 C)
7.0 6.0 5.0 4.0 3.0 2.0 1.0
3.0
IGT
IH
2.0
Ratio of
Ratio of
1.0
0
0 -65 -40 -15 +25 +65 +110 +125
-65
-40
-15
+25
+65
+110 +125
Case Temperature (TC) - C
Case Temperature (TC) - C
Figure E5.10 Normalized DC Gate-Trigger Current versus Case Temperature
Figure E5.13 Normalized DC Holding Current versus Case Temperature
Instantaneous On-state Current (iT) - Amps
32 28 24 20 16 12 8 4 0 0 .6 .8 1.0 1.2 1.4 1.6
0.8 A to 1.5 A TO-92, T106/T107, and Compak 6 A to 10 A Devices
TC = 25C
4 A TO-251 and TO-252
Instantaneous On-state Voltage (vT) - Volts
Figure E5.11 Instantaneous On-state Current versus On-state Voltage (Typical)
2.0 See General Notes for specific operating temperature range
VGT (TC = 25 C)
1.5
VGT
1.0
Ratio of
0.5
0 -65 -40 -15 +25 +65 +110 +125
Case Temperature (TC) - C
Figure E5.12 Normalized DC Gate-Trigger Voltage versus Case Temperature
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Data Sheets
Sensitive SCRs
200
100 80 60 50 40 30
10 A Devices
SUPPLY FREQUENCY: 60 Hz Sinusoidal LOAD: Resistive RMS ON-STATE CURRENT: [IT(RMS)]: Max Rated Value at Specified Case Temperature 8 A Devices 6 A Devices
Peak Surge (Non-repetitive) On-state Current (ITSM) - Amps
4 A TO-251 and TO-252
20
10 8 6 5 4 3 2 Notes: 1) Gate control may be lost during and immediately following surge current interval. 2) Overload may not be repeated until junction temperature has returned to steady-state rated value.
TO-106 and TO-107 1.5 A Devices
0.8 A TO-92 and Compak
1 1 2 3 4 56 8 10 20 30 40 50 60 80 100 200 300 400 600 1000
Surge Current Duration - Full Cycles
Figure E5.14 Peak Surge On-state Current versus Surge Current Duration
100
IGT = 50 A MAX IGT = 200 A MAX
Average On-state Power Dissipation [PD(AV)] - Watts
5.0
CURRENT WAVEFORM: Half Sine Wave LOAD: Resistive or Inductive CONDUCTION ANGLE: 180
4.0
IGT = 500 A MAX
3.0
T106 and T107
10
Turn-on Time (tgt) - s
2.0 4 A TO-251 and TO-252 1.0 0.8 A TO-92 and Compak 1.5 A Devices
IGT = 12 A MAX
1.0
0
1
2
3
4
RMS On-state Current [IT(RMS)] - Amps
TC = 25 C
Figure E5.16 Power Dissipation (Typical) versus RMS On-state Current
0.1 0.01
0.1
1
10
100
DC Gate Trigger Current (IGT) - mA
Figure E5.15 Typical Turn-on Time versus Gate Trigger Current
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Sensitive SCRs
Data Sheets
12
Average On-state Power Dissipation [PD(AV)] - Watts
10
CURRENT WAVEFORM: Half Sine Wave LOAD: Resistive or Inductive CONDUCTION ANGLE: 180
Reset Normally-closed Pushbutton
8
6
100 + 6 VDC - V1
4
D.U.T.
IGT IG 1k (1%)
IN4001 100 VGT R1
2
6 A to 10 A TO-220, TO-202, TO-251, and TO-252
0 0 2 4 6 8 10
RMS On-state Current [IT(RMS)] - Amps
Figure E5.17 Power Dissipation (Typical) versus RMS On-state Current
Figure E5.19 Simple Test Circuit for Gate Trigger Voltage and Current Measurement
9.0 8.0 See General Notes for specific device operating temperature range.
Note: V1 -- 0 V to 10 V dc meter VGT -- 0 V to 1 V dc meter IG -- 0 mA to 1 mA dc milliammeter R1 -- 1 k potentiometer To measure gate trigger voltage and current, raise gate voltage (VGT) until meter reading V1 drops from 6 V to 1 V. Gate trigger voltage is the reading on VGT just prior to V1 dropping. Gate trigger current IGT can be computed from the relationship V GT I GT = I G - ------------ Amps 1000 where IG is reading (in amperes) on meter just prior to V1 dropping.
IL IL (TC = 25 C) Ratio of
7.0 6.0 5.0 4.0 3.0 2.0 1.0 0 -65 -40
-15
+25
+65
+110 +125
Note: IGT may turn out to be a negative quantity (trigger current flows out from gate lead).
Case Temperature (TC) - C
Figure E5.18 Normalized DC Latching Current versus Case Temperature
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Data Sheets
Sensitive SCRs
180 160
Peak Discharge Current (ITM) - Amps
140 120
1 Hz 12 Hz
100 80 60 ITM 40 20 0 1.0 3.0 5.0 7.0 10 30 50 70 100 tW
tW = 5 TIME CONSTANTS
60 Hz
0.8 A to 4 A
Peak Current Duration (tW) - s
Figure E5.20 Peak Repetitive Capacitor Discharge Current
180 160
Peak Discharge Current (ITM) - Amps
140 120 100 80 60 40 20 0 1.0 3.0 5.0 7.0 10 30 50 70 100
1 Hz
12 Hz
ITM tW 0.8 A to 4 A
60 Hz
Peak Current Duration (tW) - s
Figure E5.21 Peak Repetitive Sinusoidal Curve
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Notes
l Se
ec
te
U.
L.
G O 1639 EC #E7 R
d P
Fi le
k ac
ag
* es
Z NI
ED
TO-263 D 2 Pak
E6
TO-92 *TO-218
TO-252 D-Pak TO-202
*TO-218X
3-lead Compak
*TO-220
TO-251 V-Pak
A
K
G
SCRs
(1 A to 70 A)
E6
General Description
The Teccor line of thyristor SCR semi-conductors are half-wave, unidirectional, gate-controlled rectifiers which complement Teccor's line of sensitive SCRs. Teccor offers devices with ratings of 1 A to 70 A and 200 V to 1000 V, with gate sensitivities from 10 mA to 50 mA. If gate currents in the 12 A to 500 A ranges are required, see "Sensitive SCRs" section of this catalog. Three packages are offered in electrically isolated construction where the case or tab is internally isolated to allow the use of low-cost assembly and convenient packaging techniques. The Teccor line of SCRs features glass-passivated junctions to ensure long-term reliability and parameter stability. Teccor's glass offers a rugged, reliable barrier against junction contamination. Variations of devices covered in this data sheet are available for custom design applications. Consult the factory for more information.
Features
* * * * Electrically-isolated package High voltage capability -- 200 V to 1000 V High surge capability -- up to 950 A Glass-passivated chip
Compak SCR
* * * * Surface mount package -- 1 A series New small profile three-leaded Compak package Packaged in embossed carrier tape with 2,500 devices per reel Can replace SOT-223
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SCRs
Data Sheets
Part Number
Isolated
A
Non-isolated
A
IT
(1) (2) (15)
VDRM & VRRM
IGT
(4)
A
G
TYPE
A A
A
G
K
K
K G
A
K A
G
K
K A G
G A
K
A
G
TO-92
TO-220
TO-202
TO-220
TO-251 V-Pak
Compak
TO-252 D-Pak
Amps IT(RMS) IT(AV) MAX 0.64 0.64 0.64 3.8 3.8 3.8 3.8 3.8 5.1 5.1 5.1 5.1 5.1 6.4 6.4 6.4 6.4 6.4 7.6 7.6 7.6 7.6 7.6 Volts MIN 200 400 600 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 mAmps MIN 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 MAX 10 10 10 15 15 15 15 15 15 15 15 15 15 15 15 15 15 15 20 20 20 20 20 MAX 1 1 1
S201E
See "Package Dimensions" section for variations. (11) S2N1 S4N1 S6N1 S2006L S2006F1 S4006F1 S6006F1 S2006V S4006V S6006V S8006V SK006V S2008F1 S4008F1 S6008F1 S2008R S4008R S6008R S8008R SK008R S2010F1 S4010F1 S6010F1 S2010R S4010R S6010R S8010R SK010R S2012R S4012R S6012R S8012R SK012R S2008V S4008V S6008V S8008V SK008V S2010V S4010V S6010V S8010V SK010V S2012V S4012V S6012V S8012V SK012V S2006D S4006D S6006D S8006D SK006D S2008D S4008D S6008D S8008D SK008D S2010D S4010D S6010D S8010D SK010D S2012D S4012D S6012D S8012D SK012D S4006L S6006L S8006L SK006L S2008L S4008L S6008L S8008L SK008L
1A
S401E S601E
6 6 6 6 6 8 8 8 8 8 10 10 10 10 10 12 12 12 12 12
6A
8A
10 A
S2010L S4010L S6010L S8010L SK010L
12 A
Specific Test Conditions
di/dt -- Maximum rate-of-rise of on-state current; IGT = 150 mA with 0.1 s rise time dv/dt -- Critical rate of applied forward voltage I2t -- RMS surge (non-repetitive) on-state current for period of 8.3 ms for fusing IDRM and IRRM -- Peak off-state forward and reverse current at VDRM and VRRM Igt -- dc gate trigger current; VD = 12 V dc; RL = 60 for 1 to 16 A devices and 30 for 20 to 70 A devices IGM -- Peak gate current IH -- dc holding current; gate open IT -- Maximum on-state current ITSM -- Peak one-cycle forward surge current PG(AV) -- Average gate power dissipation PGM -- Peak gate power dissipation tgt -- Gate controlled turn-on time; gate pulse = 100 mA; minimum width = 15 s with rise time 0.1 s tq -- Circuit commutated turn-off time
VDRM and VRRM -- Repetitive peak off-state forward and reverse voltage Vgt -- DC gate trigger voltage; VD = 12 V dc; RL = 60 for 1 to 16 A devices and 30 for 20 to 70 A devices VTM -- Peak on-state voltage at maximum rated RMS current
General Notes
* * * All measurements are made at 60 Hz with a resistive load at an ambient temperature of +25 C unless otherwise specified. Operating temperature range (TJ) is -65 C to +125 C for TO-92 devices and -40 C to +125 C for all other packages. Storage temperature range (TS) is -65 C to +150 C for TO-92 devices, -40 C to +150 C for TO-202 and TO-220 devices, and -40 C to +125 C for all others. Lead solder temperature is a maximum of 230 C for 10 seconds maximum; 1/16" (1.59 mm) from case. The case temperature (TC) is measured as shown on dimensional outline drawings in the "Package Dimensions" sectionof this catalog.
* *
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Data Sheets
SCRs
IDRM & IRRM
(14)
VTM
(3)
VGT
(8) (17)
IH
(5) (13)
IGM
(12)
PGM
(12)
PG(AV)
ITSM
(6) (10)
dv/dt
I2t
di/dt
tgt
(7)
tq
(9) (10)
mAmps TC = 25 C 0.01 0.01 0.01 0.01 0.01 0.01 0.01 0.02 0.01 0.01 0.01 0.01 0.02 0.01 0.01 0.01 0.02 0.02 0.01 0.01 0.01 0.02 0.02 TC = TC = 100 C 125 C MAX 0.2 0.2 0.2 0.2 0.2 0.2 0.2 3 0.2 0.2 0.2 0.2 3 0.2 0.2 0.2 0.5 3 0.5 0.5 0.5 0.5 3 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 1 1 1 1 1
Volts TC = 25 C MAX 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6
Volts TC = 25 C MAX 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 mAmps MAX 30 30 30 30 30 30 30 30 30 30 30 30 30 30 30 30 30 30 40 40 40 40 40 1.5 1.5 1.5 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 15 15 15 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 0.3 0.3 0.3 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 Amps Watts Watts
Amps 60/50 Hz 30/25 30/25 30/25 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 100/83 120/100 120/100 120/100 120/100 120/100
Volts/Sec TC = 100 C MIN 40 40 40 350 350 300 250 100 350 350 300 250 100 350 350 300 250 100 350 350 300 250 100 TC = 125 C MIN 20 20 20 250 250 225 200 250 250 225 200 250 250 225 200 250 250 225 200 3.7 3.7 3.7 41 41 41 41 41 41 41 41 41 41 41 41 41 41 41 60 60 60 60 60 50 50 50 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 Amps2Sec Amps/Sec Sec TYP 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 Sec MAX 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35
Electrical Specification Notes
(1) (2) (3) (4) (5) (6) (7) (8) (9) See Figure E6.5 through Figure E6.16 for current rating at specified operating case temperature. See Figure E6.1 and Figure E6.2 for free air current rating. See Figure E6.19 and Figure E6.20 for instantaneous on-state current versus on-state voltage (typical). See Figure E6.18 for IGT versus TC. See Figure E6.17 for IH versus TC. For more than one full cycle rating, see Figure E6.23. See Figure E6.22 for tgt versus IGT. See Figure E6.21 for VGT versus TC. Test conditions are as follows: * IT = 1 A for 1 A devices and 2 A for all other devices * Pulse duration = 50 s, dv/dt = 20 V/s, di/dt = -10 A/s for 1 A devices, and -30 A/s for other devices * IGT = 200 mA at turn-on (10) See Figure E6.5 through Figure E6.10 for maximum allowable case temperatures at maximum rated current.
(11) See package outlines for lead form configuration. When ordering special lead forming, add type number as suffix to part number. (12) Pulse width 10 s (13) Initial on-state current = 200 mA dc for 1 A through 16 A devices; 400 mA dc for 20 A through 70 A devices. (14) TC = TJ for test conditions in off state. (15) The R, K, or M package rating is intended for high surge condition use only and not recommended for 50 A rms continuous current use since narrow pin lead temperature can exceed PCB solder melting temperature. Teccor's J package or W package is recommended for 50 A rms continuous current requirements. (16) For various durations of an exponentially decaying current waveform, see Figure E6.3 and Figure E6.4. (tW is defined as 5 time constants.) (17) Minimum non-trigger VGT at 125 C is 0.2 V.
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SCRs
Data Sheets
Part Number
Isolated
A
Non-isolated
A
A
IT
(1) (15)
A
A A K G
VDRM & VRRM
IGT
(4)
IDRM & IRRM
(14)
TYPE
K A G
A
K
A
G
KAG
K AG
K A
G
KAG
Amps TO-263 D2Pak IT(RMS) 15 15 15 15 IT(AV) MAX 9.5 9.5 9.5 9.5 9.5 10 10 10 10 10 12.8 12.8 12.8 12.8 12.8 16 16 16 16 16 22 22 22 22 22 25 25 25 25 25 35 35 35 35 35 41 41 41 41 41 45 45 45 45 Volts MIN 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 mAmps MIN 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 MAX 30 30 30 30 30 30 30 30 30 30 30 30 30 30 30 35 35 35 35 35 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 50 50 50 50 50 50 50 50 50 0.01 0.01 0.01 0.02 0.02 0.01 0.01 0.01 0.02 0.02 0.01 0.01 0.01 0.02 0.02 0.01 0.01 0.01 0.02 0.02 0.01 0.01 0.01 0.02 0.02 0.01 0.01 0.01 0.02 0.03 0.01 0.01 0.01 0.02 0.03 0.02 0.02 0.02 0.02 0.03 0.02 0.02 0.02 0.02 TC = 25 C
mAmps TC = 100 C MAX 0.5 0.5 0.5 1 3 0.5 0.5 0.5 1 3 0.5 0.5 0.5 1.0 3 1 1 1 1.5 3 1 1 1 1.5 3 1 1 1 1.5 5 1 1 1 1.5 5 1.5 1.5 1.5 2 5 1.5 1.5 1.5 2 1 1 1 2 1 1 1 2 1 1 1 2 2 2 2 3 2 2 2 3 2 2 2 3 2 2 2 3 3 3 3 5 3 3 3 5 TC = 125 C
TO-220 S2015L S4015L S6015L S8015L SK015L
TO-218X
TO-218
TO-220
TO-218X
TO-218
See "Package Dimensions" section for variations. (11)
15 A
S2016R
S2016N S4016N S6016N S8016N SK016N
15 16 16 16 16 16 20 20 20 20
16 A
S4016R S6016R S8016R SK016R S2020L S4020L S6020L S8020L SK020L S2025L S2025R S4025R S6025R S8025R SK025R S2035J S4035J S6035J S8035J S2035K S4035K S6035K S8035K SK035K S2040R
20 A
S2025N S4025N S6025N S8025N SK025N
20 25 25 25 25 25 35 35 35 35
25 A
S4025L S6025L S8025L SK025L
35 A
S2040N S4040N S6040N S8040N SK040N S2055W S4055W S6055W S8055W S2055M S4055M S6055M S8055M SK055M S2055N S4055N S6055N S8055N SK055N
35 40 40 40 40 40 55 55 55 55 55 65 65 65 65 65
40 A
S4040R S6040R S8040R SK040R S2055R S4055R S6055R S8055R SK055R S2065J S2065K S4065K S6065K S8065K SK065K S2070W S4070W S6070W S8070W S4065J S6065J S8065J
55 A
65 A
70 A
70 70 70 70
See "General Notes" on page E6 - 2 and "Electrical Specification Notes" on page E6 - 3.
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(c)2002 Teccor Electronics Thyristor Product Catalog
Data Sheets
SCRs
VTM
(3)
VGT
(8) (17)
IH
(5) (13)
IGM
(12)
PGM
(12)
PG(AV)
ITSM
(6) (10) (16)
dv/dt
I2t
di/dt
tgt
(7)
tq
(9) (10)
Volts
Volts mAmps MAX 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 50 50 50 50 50 50 50 50 50 50 60 60 60 60 60 60 60 60 60 60 80 80 80 80 80 80 80 80 80 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3.5 3.5 3.5 3.5 3.5 3.5 3.5 3.5 3.5 3.5 3.5 3.5 3.5 3.5 3.5 4 4 4 4 4 5 5 5 5 5 5 5 5 5 30 30 30 30 30 30 30 30 30 30 30 30 30 30 30 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 40 40 40 40 40 50 50 50 50 50 50 50 50 50 0.6 0.6 0.6 0.6 0.6 0.6 0.6 0.6 0.6 0.6 0.6 0.6 0.6 0.6 0.6 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 1 1 1 1 1 1 1 1 1 Amps Watts Watts
Amps 60/50 Hz 225/188 225/188 225/188 225/188 225/188 225/188 225/188 225/188 225/188 225/188 300/255 300/255 300/255 300/255 300/255 350/300 350/300 350/300 350/300 350/300 500/425 500/425 500/425 500/425 500/425 520/430 520/430 520/430 520/430 520/430 650/550 650/550 650/550 650/550 650/550 950/800 950/800 950/800 950/800 950/800 950/800 950/800 950/800 950/800
TC = 25 C TC = 25 C MAX 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 MAX 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 2 2 2 2 2 2 2 2 2
Volts/Sec TC = TC = 100 C 125 C MIN 450 450 425 400 200 450 450 425 400 200 450 450 425 400 200 450 450 425 400 200 450 450 425 400 200 650 650 600 500 250 650 650 600 500 250 650 650 600 500 250 650 650 600 500 550 550 500 475 550 550 500 475 550 550 500 475 350 350 325 300 550 550 500 475 350 350 325 300 350 350 325 300 350 350 325 300 MIN 350 350 325 300
Amps2Sec 210 210 210 210 210 210 210 210 210 210 374 374 374 374 374 510 510 510 510 510 1035 1035 1035 1035 1035 1122 1122 1122 1122 1122 1750 1750 1750 1750 1750 3745 3745 3745 3745 3745 3745 3745 3745 3745
Amps/Sec 125 125 125 125 125 125 125 125 125 125 125 125 125 125 125 150 150 150 150 150 150 150 150 150 150 175 175 175 175 175 175 175 175 175 175 200 200 200 200 200 200 200 200 200
Sec TYP 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5
Sec MAX 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35
See "General Notes" on page E6 - 2 and "Electrical Specification Notes" on page E6 - 3.
(c)2002 Teccor Electronics Thyristor Product Catalog
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SCRs
Data Sheets
Thermal Resistance (Steady State) RJC [RJA] C/W (TYP.) Pkg. Code
L F F2 R J W K M D V N
Type
TO-220 Isolated
TO-202 Type 1 Non-isolated 4.3 [45] 3.9 3.4
TO-202 Type 2 Non-isolated 9.5 [70]
TO-220 Non-isolated
TO-218X Isolated
TO-218X Non-isolated See below
TO-218 Isolated
TO-218 Non-isolated
TO-252 TO-251AA D-Pak V-Pak Surface Mount Non-isolated 1.7 2.3 [70] 2.0 1.7 1.6
TO-263 D2Pak Non-isolated
1A 6A 8A 10 A 12 A 15 A 16 A 20 A 25 A 35 A 40 A 55 A 65 A 70 A
4.0 [50] 3.4 3.0 2.5
1.8 [40] 1.6 1.5 1.3
1.5 1.45 1.4
1.3 1.0 0.70 0.70 0.6 0.53 0.86 0.60 0.86 0.53 0.5
2.4 2.35 1.0 0.6 0.5
Electrical Isolation
Thermal Resistance (Steady State) RJC [RJA] C/W (TYP.)
Package Code Type C E
Teccor's isolated SCR packages will withstand a minimum high potential test of 2500 V ac rms from leads to mounting tab over the device's operating temperature range. The following table shows standard and optional isolation ratings.
Electrical Isolation * from Leads to Mounting Tab TO-220 TO-218X Isolated Isolated
Standard Optional ** Standard N/A
1A
Compak 35 *
TO-92 50 [145]
V AC RMS 2500 4000
TO-218 Isolated
Standard N/A
* Mounted on
1cm 2
copper foil surface; two-ounce copper foil
* UL Recognized File #E71639 ** For 4000 V isolation, use "V" suffix in part number.
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(c)2002 Teccor Electronics Thyristor Product Catalog
Data Sheets
SCRs
120
Maximum Allowable Ambient Temperature (TA) - C
8 A TO-220 (Non-isolated)
80
Normalized Peak Current
100
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 FREE AIR RATING
1.0 0.8 0.6 0.4 0.2 0 25 50 75 100 125
6 A TO-220 (Isolated) and 6 A TO-202 (Types 1 and 3)
60
1 A TO-92
40
6 A TO-202 (Types 2 and 4) and 6 A TO-251
20 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2
Case Temperature (TC) - C
RMS On-state Current [IT(RMS)] - Amps
Figure E6.1 Maximum Allowable Ambient Temperature versus RMS On-state Current
Figure E6.4 Peak Capacitor Discharge Current Derating (6 A through 55 A)
120 CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 FREE AIR RATING
130 120
Maximum Allowable Ambient Temperature (TA) - C
100
Maximum Allowable Case Temperature (TC) - C
110 100 90 80 70 60 50 0 0.2 0.4 0.6 0.8 1.0 1.2 CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measure as shown on dimensional drawing
8 A TO-220 (Non-isolated)
80
1 A Devices
1 A TO-92
60
6 A TO-220 (Isolated) and 6 A TO-202 (Types 1 and 3)
40
6 A TO-202 (Types 2 and 4) and 6 A TO-251
20 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4
Average On-state Current [IT(AV)] - Amps
RMS On-state Current [IT(RMS)] - Amps
Figure E6.2 Maximum Allowable Ambient Temperature versus Average On-state Current
Figure E6.5 Maximum Allowable Case Temperature versus RMS On-state Current (1 A)
130
Peak Discharge Current (ITM) - Amps
1000
120
55 A Devices
8 A TO-220 (Non-isolated) TO-251 and TO-252 10 A TO-220 (Isolated) and 10 A TO-202
Maximum Allowable Case Temperature (TC) - C
110
6 A Devices
100 90 80 70 60 50 CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measure as shown on dimensional drawings 0 2 4 6 8
300 200
25 A Devices 15 A and 16 A Devices
8 A TO-220 (Isolated) and 8 A TO-202
100
6 A to 10 A Devices 12 A Devices
50 ITM tw tw = 5 times constants 20 0.5 1.0 2.0 5.0 10 20 50
10
12
Pulse Current Duration (tw) - ms
RMS On-state Current [IT(RMS)] - Amps
Figure E6.3 Peak Capacitor Discharge Current (6 A through 55 A)
Figure E6.6 Maximum Allowable Case Temperature versus RMS On-state Current (6 A, 8 A, and 10 A)
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E6 - 7
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SCRs
Data Sheets
130
130
Maximum Allowable Case Temperature (TC) - C
120 110 100 90 80 70 60 50 0 55 A TO-220 (Non-isolated) and TO-263 *
Maximum Allowable Case Temperature (TC) - C
120 110 100 90 80 70 60 50 0 4
10 A TO-220 (Non-isolated)
16 A TO-220 (Non-isolated) and TO-263 20 A TO-220 (Isolated)
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measure as shown on dimensional drawings
55 A TO-218AC (Non-isolated) *
10 A TO-251 and 10 A TO-252 12 A TO-220 (Non-isolated) TO-251 and TO-252
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measure as shown on dimensional drawing
65 A TO-218AC (Isolated) *
* The R, K or M package rating is intended only for high surge condition use and is not recommended for >50 A rms continuous current use, since narrow pin lead temperature can exceed PCB solder melting temperature. J or W packages are recommended for >50 A rms continuous current requirements. 10 20 30 40 50 60 70 75
15 A TO-220 (Isolated)
8
12
16
20
RMS On-state Current [IT(RMS)] - Amps
RMS On-state Current [IT(RMS)] - Amps
Figure E6.7 Maximum Allowable Case Temperature versus RMS On-state Current (10 A, 12 A, 16 A, and 20 A)
Figure E6.10 Maximum Allowable Case Temperature versus RMS On-state Current (55 A and 65 A)
Maximum Allowable Case Temperature (TC) - C
130 120
130 120 110 100
Maximum Allowable Case Temperature (TC) - C
110 100 90 80 70 60 50 0
25 A TO-220 (Isolated)
35 A TO-218 (Isolated)
25 A TO-220 (Non-isolated) and TO-263
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measure as shown on dimensional drawings 4 8 12 16 20 24 28 32 36
1 A Devices
90 80 70 60
50 0
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measure as shown on dimensional drawings
0.2 0.4 0.6 0.8
RMS On-state Current [IT(RMS)] - Amps
Average On-state Current [IT(AV)] - Amps
Figure E6.8 Maximum Allowable Case Temperature versus RMS On-state Current (25 A and 35 A)
130 120
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measure as shown on dimensional drawings
Figure E6.11 Maximum Allowable Case Temperature versus Average On-state Current (1 A)
Maximum Allowable Case Temperature (TC) - C
130
12 A TO-220 (Non-isolated) and TO-251 and TO-252
Maximum Allowable Case Temperature (TC) - C
120
10 A TO-251 10 A TO-252
110 100 90 80 70 60 50 0 10 20 30 40 50 60 70
40 A TO-220 (Non-isolated) and TO-263 65 A TO-218X (Isolated)
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measure as shown on dimensional drawings
70 A TO-218X (Non-isolated)
110
6 A TO-220 6 A TO-202
10 A TO-220 (Non-isolated)
10 A TO-220 (Isolated) and 10 A TO-202
100
6 A TO-251 6 A TO-252
8 A TO-220 (Isolated) 8 A TO-202
55 A TO-218X (Non-isolated)
90
8 A TO-220 (Non-isolated)
80 0 1 2 3 4 5 6 7 8
RMS On-state Current [IT(RMS)] - Amps
Average On-state Current [IT(AV)] - Amps
Figure E6.9 Maximum Allowable Case Temperature versus RMS On-state Current (40 A through 70 A)
Figure E6.12 Maximum Allowable Case Temperature versus Average On-state Current (8 A, 10 A, and 12 A)
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Data Sheets
SCRs
130
130
16 AT O-2 20
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measured as shown on dimensional drawings
120 Case Temperature (TC) - C 110 100 90 80 70 60 50 0
120 Case Temperature (TC) - C 110 100 90 80 70 60 50 0
55 A TO-220 (Non-isolated) and TO-263 *
(No
n-is
olat
Maximum Allowable
ed)
-26 3
20 A TO-220 (Isolated)
Maximum Allowable
and
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measure as shown on dimensional drawings 55 A TO-218AC (Non-isolated) *
TO
65 A TO-218AC (Isolated) *
10 A TO-220 (Non-isolated)
* The R, K, or M package
rating is intended only for high surge condition use and is not recommended for >32 A (AV) continuous current use since narrow pin lead temperature can exceed PCB solder melting temperature. J or W packages are recommended for >32 A (AV) continuous current requirements.
15 A TO-220 (Isolated) 2 4 6 8 10 12 14
10
20
30
40
50
Average On-state Current [IT(AV)] - Amps
Average On-state Current [IT(AV)] - Amps
Figure E6.13 Maximum Allowable Case Temperature versus Average On-state Current (10 A through 20 A)
Figure E6.16 Maximum Allowable Case Temperature versus Average On-state Current (55 A and 65 A)
130
Maximum Allowable Case Temperature (TC) - C
120
110
IH (TC = 25 C)
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measure as shown on dimensional drawings
2.0
INITIAL ON-STATE CURRENT = 200 mA dc for 1 A to 20 A Devices and 400 mA dc for 25 A to 70 A Devices
1.5
35 A TO-218 (Non-isolated)
100
IH
35 A TO-218 (Isolated)
90
1.0
80
Ratio of
25A TO-220 (Isolated)
.5
70
60
25A TO-220 (Non-isolated) and TO-263
0
50 0 .4 8 12 16 20 24
-40
-15
+25
+65
+105 +125
Case Temperature (TC) - C
Average On-state Current [IT(AV)] - Amps
Figure E6.14 Maximum Allowable Case Temperature versus Average On-state Current (25 A and 35 A)
130 120
Maximum Allowable Case Temperature (TC) - C
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 180 CASE TEMPERATURE: Measure as shown on dimensional drawings
Figure E6.17 Normalized dc Holding Current versus Case Temperature
2.0
110 100 90 80 40 A TO-220 (Non-isolated) and TO-263 55 A TO-218X (Non-isolated) 65 A TO-218X (Isolated)
IGT (TC = 25 C)
1.5
70 A TO-218X (Non-isolated)
IGT Ratio of
1.0
70 60 50 0
0.5
0
10
20
30
40
50
-40
-15
+25
+65
+105 +125
Average On-state Current [IT(AV)] - Amps
Case Temperature (TC) - C
Figure E6.15 Maximum Allowable Case Temperature versus Average On-state Current (40 A through 70 A)
Figure E6.18 Normalized DC Gate-Trigger Current versus Case Temperature
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SCRs
Data Sheets
90
Instantaneous On-state Current (iT) - Amps
1.5
80 70 60 50
VGT (TC = 25 C)
TC = 25C
25 A Devices
15 A to 20 A Devices
40
12 A Devices
30
VGT
6 A to 10 A Devices
1.0
20 10
Ratio of
1 A Devices
0.5
0
0 0 0.6 0.8 1.0 1.2 1.4 1.6
-40
-15
+25
+65
+105 +125
Case Temperature (TC) - C
Instantaneous On-state Voltage (vT) - Volts
Figure E6.19 Instantaneous On-state Current versus On-state Voltage (Typical) (6 A through 25 A)
Figure E6.21 Normalized DC Gate-trigger Voltage versus Case Temperature
200 180
7 6 A to 12 A Devices
TC = 25C
15 A to 35 A Devices
Turn-on Time (tgt) - s
160 Instantaneous On-state Current (iT) - Amps 140 120 100 80 60 40 20 0 0
TC = 25C
6
5
65 A and 70 A Devices
4 40 A to 70 A Devices 3 1 A Devices
55 A Devices
2 1
35 A to 40 A Devices .6 .8 1.0 1.2 1.4 1.6
0 10 20 30 40 50 60 80 100 200
Instantaneous On-state Voltage (vT) - Volts
DC Gate Trigger Current (IGT) - mA
Figure E6.20 Instantaneous On-state Current versus On-state Voltage (Typical) (35 A through 70 A)
Figure E6.22 Typical Turn-on Time versus Gate-trigger Current
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Data Sheets
SCRs
Peak Surge (Non-repetitive) On-state Current (ITSM) - Amps
1000 800 600 500 400 300 200
65 A
SUPPLY FREQUENCY: 60 Hz Sinusoidal LOAD: Resistive RMS ON-STATE CURRENT: [IT(RMS)]: MaxRated Value at Specified Case Temperature
TO-2 18
70 A Devic Devic
es
35 A 25 A 16 A
10 A Devic es
Devic
55 A
Devic es
es
es 40 A Devic es
es
100 80 60 50 40 30 20
Devic
20 A 15 A Devic es
Devic
es
12 A
Devic es 8AD evice s 6A Dev ices
10 8 6 5 4 3 2
1A Dev
Notes: 1) Gate control may be lost during and immediately following surge current interval. 2) Overload may not be repeated until junction temperature has returned to steady-state rated value.
ices
1 1 2 3 4 5 6 7 8 10 20 30 40 60 80100 200 300400 600 1000
Surge Current Duration - Full Cycles
Figure E6.23 Peak Surge Current versus Surge Current Duration
Average On-state Power Dissipation [PD(AV)] - Watts
Average On-state Power Dissipation [PD(AV)] - Watts
CURRENT WAVEFORM: Half Sine Wave LOAD: Resistive or Inductive CONDUCTION ANGLE: 180
18 16 14 12 10 8 6 4 2 0 15 A to 20 A Devices 12 A Devices 6 A to 10 A Devices
CURRENT WAVEFORM: Half Sine Wave LOAD: Resistive or Inductive CONDUCTION ANGLE: 180
1.0 0.8
1.0 A Devices
0.6 0.4 0.2 0 0 0.2 0.4 0.6 0.8 1.0
0
2
4
6
8
10
12
14
16
18
20
RMS On-state Current [IT(RMS)] - Amps
Figure E6.24 Power Dissipation (Typical) versus RMS On-state Current (1 A)
RMS On-state Current [IT(RMS)] - Amps
Figure E6.25 Power Dissipation (Typical) versus RMS On-state Current (6 A through 20 A)
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SCRs
Data Sheets
32
60
Average On-state Power Dissipation [PD(AV)] x- Watts
28 24 20 16 12 8
Power Dissipation [PD(AV)] - Watts
es
CURRENT WAVEFORM: Half Sine Wave LOAD: Resistive or Inductive CONDUCTION ANGLE: 180
De
Average On-state
25
4 0 0 4 8
A
TO
22
0
D
ic ev
es
20
10
0
12
16
20
24
28
32
36
0 10 20 30 40 50 60 70
RMS On-state Current [IT(RMS)] - Amps
Figure E6.26 Power Dissipation (Typical) versus RMS On-state Current (25 A and 35 A)
RMS On-state Current [IT(RMS)] - Amps
Figure E6.27 Power Dissipation (Typical) versus RMS On-state Current (40 A through 70 A)
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E6 - 12
40
30
A
an
d
55
35
A
A
De
vic
v
s ice
50
CURRENT WAVEFORM: Half Sine Wave LOAD: Resistive or Inductive CONDUCTION ANGLE: 180
d 70 A
De
vic
es
40
65
A
an
(c)2002 Teccor Electronics Thyristor Product Catalog
L U.
.
O 1639 EC #E7 R
Fi le
IZ GN
ED
E7
TO-220 Isolated
A C
Rectifiers
(15 A to 25 A)
E7
General Description
Teccor manufactures 15 A rms to 25 A rms rectifiers with voltages rated from 200 V to 1000 V. Due to the electrically-isolated TO-220 package, these rectifiers may be used in common anode or common cathode circuits using only one part type, thereby simplifying stock requirements. Teccor's silicon rectifiers feature glass-passivated junctions to ensure long term reliability and stability. In addition, glass offers a rugged, reliable barrier against junction contamination.
Features
* * * * Electrically-isolated packages High voltage capabilities -- 200 V to 1000 V High surge capabilities -- up to 350 A Glass-passivated junctions
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Rectifiers
Data Sheets
Part Number
Isolated
VRRM
VR
IF(AV)
(1)
IF(RMS)
IFSM
(2)
IRM
(3)
VFM
I 2t
RJC
Type
C A
Not Used
Amps Volts MIN 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 Volts MIN 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 Amps MAX 9.5 9.5 9.5 9.5 9.5 12.7 12.7 12.7 12.7 12.7 15.9 15.9 15.9 15.9 15.9 Amps MAX 15 15 15 15 15 20 20 20 20 20 25 25 25 25 25 225/188 225/188 225/188 225/188 225/188 300/255 300/255 300/255 300/255 300/255 350/300 350/300 350/300 350/300 350/300 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 60/50 Hz TC = 25 C
TO-220 See "Package Dimensions" section for variations. (4) D2015L D4015L D6015L D8015L DK015L D2020L D4020L D6020L D8020L DK020L D2025L D4025L D6025L D8025L DK025L
mA TC = 100 C MAX 0.5 0.5 0.5 0.5 3 0.5 0.5 0.5 0.5 3 0.5 0.5 0.5 0.5 3
Volts TC = 125 C TC=25 C MAX 1 1 1 1 1 1 1 1 1 1 1 1 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 210 210 210 210 210 374 374 374 374 374 508 508 508 508 508 Amps2Sec C/W TYP 2.85 2.85 2.58 2.85 2.85 2.5 2.5 2.5 2.5 2.5 2.7 2.7 2.7 2.7 2.7
15 A
20 A
25 A
Test Conditions
I2t -- RMS surge (non-repetitive) forward current for 8.3 ms for fusing IF(AV) -- Average forward current IF(RMS) -- RMS forward current IFSM -- Peak one-cycle surge current IRM -- Peak reverse current RJC -- Thermal resistance (steady state) junction to case VFM -- Peak forward voltage at rated average forward current VR -- DC blocking voltage VRRM -- Peak repetitive reverse voltage
Electrical Specification Notes
(1) (2) (3) (4) See Figure E7.3 for current rating at specified case temperature. For more than one full cycle rating, see Figure E7.4. TC = TJ for test conditions See package outlines for lead form configurations. When ordering special lead forming, add type number as suffix to part number.
Electrical Isolation
Electrical Isolation from Leads to Mounting Tab * V AC RMS 2500 4000
TO-220 Isolated Standard Optional **
General Notes
* * * * Operating temperature range (TJ) is -40 C to +125 C. Storage temperature range (TS) is -40 C to +125 C. Lead solder temperature is a maximum of 230 C for 10 seconds maximum at a minimum of 1/16" (1.59 mm) from case. The case temperature (TC) is measured as shown on dimensional outline drawings in the "Package Dimensions" section of this catalog. Teccor's electrically-isolated TO-220 devices withstand a high potential test of 2500 V ac rms from leads to mounting tab over the operating temperature range. Typical Reverse Recovery Time (trr) is 4 s. (Test conditions = 0.9 A forward current and 1.5 A reverse current)
* UL Recognized File #E71639 ** For 4000 V isolation, use "V" suffix in the part number.
*
*
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Data Sheets
Rectifiers
140
Instantaneous Forward Current (iF) - Amps
120
TC = 25C
Peak Surge (Non-repetitive) Forward Current (IFSM) - Amps
1000 800 600 400 300 200 15 A Devices 20 A Devices 25 A Devices
100
25 A Devices
80
20 A Devices
60
100 80 60 40 30 20 10 1 2 4 6 10 20 40 60 100 200 400 600 1000 SUPPLY FREQUENCY: 60 Hz Sinewave LOAD: Resistive or Inductive RMS ON-STATE CURRENT: [IF(RMS)] Maximium Rated Value at Specified Case Temperature
40
15 A Devices
20 0 0 0.6 0.8 1.0 1.2 1.4 1.6 1.8
Surge Current Duration - Cycles
Instantaneous Forward Voltage (vF) - Volts
Figure E7.1 Instantaneous Forward Current versus Forward Voltage (Typical)
Figure E7.4 Peak Surge Forward Current versus Surge Current Duration
20
Average Forward Power Dissipation [PF(AV)] - Watts
SINGLE PULSE RECTIFICATION 60 Hz SINE WAVE 16
12
20 A Devices
8 15 A Devices 4 25 A Devices
0 0 2 4 6 8 10 12 14 16
Average Forward Current [IF(AV)] - Amps
Figure E7.2 Forward Power Dissipation (Typical)
125
Maximum Allowable Case Temperature (TC) - C
120 115 110 105 100
SUPPLY FREQUENCY: 60 Hz Sine Wave LOAD: Resistive or Inductive CASE TEMPERATURE: Measured As Shown on Dimensional Drawing
20 A Devices
25 A Devices
95
15 A Devices
90 85 80 75 70 0 0 2 4 6 8 10 12 14 16
Average Forward Current [IF (AV)] - Amps
Figure E7.3 Maximum Allowable Case Temperature versus Average Forward Current
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Notes
E8
DO-35
DO-214
Diac
HT and ST Series
E8
General Description
Teccor's HT and ST Series of bilateral trigger diacs offer a range of voltage characteristics from 27 V to 45 V. A diac semiconductor is a full-wave or bidirectional thyristor. It is triggered from a blocking- to conduction-state for either polarity of applied voltage whenever the amplitude of applied voltage exceeds the breakover voltage rating of the diac. The Teccor line of diacs features glass-passivated junctions to ensure long-term reliability and parameter stability. Teccor's glass offers a rugged, reliable barrier against junction contamination. The diac specifications listed in this data sheet are for standard products. Special parameter selections such as close tolerance voltage symmetry are available. Consult the factory for more information about custom design applications.
Features
* * * Bilateral triggering device Glass-passivated junctions Wide voltage range selections
ST Series
* * Epoxy SMT package High-temperature, solder-bonded die attachment
HT Series
* * DO-35 trigger package Pre-tinned leads
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Diac
Data Sheets
Electrical Characteristics TC = 25C Part No.
VBO Breakover Voltage (Forward and Reverse) VBO Breakover Voltage Symmetry VBO = [ | +VBO | - | - VBO | ] DO-35 HT-32 HT-32A / HT-5761 HT-32B / HT-5761A HT-34B HT-35 HT-36A / HT-5762 HT-36B HT-40 DO-214 ST-32 ST-32B ST-34B ST-35 ST-36A ST-36B ST-40 Volts MIN 27 28 30 32 30 32 34 35 MAX 37 36 34 36 40 40 38 45 Volts MAX 3 (1) 2 (1) 2 (1) 2 (1) 3 (1) 2 (1) 2 (1) 3 (1) VBB Dynamic Breakback Voltage (3) | V | Volts MIN 10 (2) 7 at 10 mA (4) 7 at 10 mA (4) 10 (2) 10 (2) 7 at 10 mA (4) 10 (2) 10 (2) IBO Peak Breakover Current at Breakover Voltage Amps MAX 25 25 25 25 25 25 25 25 ITRM Peak Pulse Current for 10 s 120 PPS TA 40 C Amps MAX 2 2 2 2 2 2 2 2
General Notes
* * Lead solder temperature is +230 C for 10-second maximum; 1/16" (1.59 mm) from case. See "Package Dimensions" section of this catalog.
Current 10 mA
V
Electrical Specification Notes
(1) (2) (3) Breakover voltage symmetry as close as 1 V is available from the factory on these products. See Figure E8.4 and Figure E8.5 for test circuit and waveforms. Typical switching time is 900 nano-seconds measured at IPK (Figure E8.4) across a 20 resistor (Figure E8.5). Switching time is defined as rise time of IPK between the 10% to 90% points. See V-I Characteristics.
-VBO
Breakover Current IBO
Voltage +VBO
(4)
Breakover Voltage VBO
Bilateral Trigger DIAC Specifications
* Maximum Ratings, Absolute-Maximum Values - Maximum Trigger Firing Capacitance: 0.1 F - Device dissipation (at TA = -40 C to +40 C): 250 mW for DO-35 and 300 mW for DO-214 - Derate above +40 C: 3.6 mW/C for DO-35 and 3 mW/C for DO-214 * Temperature Ranges Storage: -40 C to +125 C Operating (Junction): -40 C to +125 C
V-I Characteristics
HT and ST Series Thermal Resistance Junction to Lead - RJL: C/W Junction to Ambient [RJA]: C/W (based on maximum lead temperature of 90 C for DO-214 and 85 C for DO-35 devices)
Y Package S Package
DO-35 100 [278] C/W
DO-214 65 C/W *
* Mounted on 1 cm2 copper foil surface; two-ounce copper foil
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Thyristor Product Catalog
Data Sheets
Diac
LOAD -- Up to 1500 W
3.3 k
Triac Q2015L5 200 k 120 V ac 60 Hz G
MT2
MT1
0.1 F 100 V
HT-35 Bilateral Trigger Diac
Figure E8.1 Typical Diac/Triac Full-wave Phase Control Circuit Using Lower Voltage Diacs.
10 5.0
Repetitive Peak On-state Current (ITRM) - Amps
3.0 2.0 1.0 0.5 0.3 0.2 0.1 0.05 0.03 0.02 .01 .005 .003 .002 .001
Safe Operating Area
PULSE REPETITION RATE = 120 pps TA = 40 C
1 2 4 6 10 20 40 60 100 200 400 6001000 2000 4000 10000
Base Pulse Duration - s
Figure E8.2 Repetitive Peak On-state Current versus Pulse Duration
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Diac
Data Sheets
+8
Percentage of VBO Change - %
+6 +4 +2 HT Series 0 -2 -4 -6 -8 -40 -20 0 +20 +40 +60 +80 +100 +120 +140 ST Series
47 k
*
100 k D.U.T. RL VC CT O.1 F IL 20 1%
120 V rms 60 Hz
Junction Temperature (TJ) - C
* Adjust for one firing in each half cycle. D.U.T. = Diac
Figure E8.3 Normalized VBO Change versus Junction Temperature
Figure E8.5 Circuit Used to Measure Diac Characteristics (Refer to Figure E8.4.)
V +V
BO
C
300
Peak Output Current (IPK) - mA
V+
250
0
t
200
e vic )
V-V
BO
150
Ty pic a
5V l (3
De
I +I
PK
L
100
50
0
t
0
-I
.01 .02 .03 .04 .05 .06 .07 .08 .09 .10
PK
Triggering Capacitance (CT) - F
Typical pulse base width is 10 s
Figure E8.4 Test Circuit Waveforms (Refer to Figure E8.5.)
Figure E8.6 Peak Output Current versus Triggering Capacitance (Per Figure E8.5 with RL of 20 )
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E9
DO-15X
DO-214 Surface Mount TO-92 Type 70 TO-202
Sidac
(79 V to 330 V)
E9
General Description
The sidac is a silicon bilateral voltage triggered switch with greater power-handling capabilities than standard diacs. Upon application of a voltage exceeding the sidac breakover voltage point, the sidac switches on through a negative resistance region to a low on-state voltage. Conduction continues until the current is interrupted or drops below the minimum holding current of the device. Teccor's sidacs feature glass-passivated junctions to ensure a rugged and dependable device capable of withstanding harsh environments. Variations of devices covered in this data sheet are available for custom design applications. Consult the factory for more information.
Applications
* * * * * * * * * High-voltage lamp ignitors Natural gas ignitors Gas oil ignitors High-voltage power supplies Xenon ignitors Overvoltage protector Pulse generators Fluorescent lighting ignitors HID lighting ignitors
Features
* * * AC circuit oriented Glass-passivated junctions High surge current capability
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Sidac
Data Sheets
Part No.
(10)
IT(RMS)
(7) (8)
VDRM
VBO
(1)
IDRM
IBO
(2)
IH
(3) (4)
Type
TO-92
DO-15X
TO-202
DO-214 Amps MAX 1 1 1 1 1 1 1 1 1 1 1 1 Volts MIN 70 90 90 90 90 90 90 180 180 190 200 200 MIN 79 95 104 110 120 130 140 190 205 220 240 270 Volts MAX 97 113 118 125 138 146 170 215 230 250 280 330 Amps MAX 5 5 5 5 5 5 5 5 5 5 5 5 Amps MAX 10 10 10 10 10 10 10 10 10 10 10 10 mAmps TYP 60 60 60 60 60 60 60 60 60 60 60 60 MAX 150 150 150 150 150 150 150 150 150 150 150 150
See "Package Dimensions" section for variations. (9) K0900E70 K0900G K0900S K1050E70 K1100E70 K1200E70 K1300E70 K1400E70 K1500E70 K2000E70 K2200E70 K2400E70 K2500E70 K1050G K1100G K1200G K1300G K1400G K1500G K2000G K2200G K2400G K2500G K2000F1 K2200F1 K2400F1 K2500F1 K3000F1 K1050S K1100S K1200S K1300S K1400S K1500S K2000S K2200S K2400S K2500S
Specific Test Conditions
di/dt -- Critical rate-of-rise of on-state current dv/dt -- Critical rate-of-rise of off-state voltage at rated VDRM; TJ 100 C IBO -- Breakover current 50/60 Hz sine wave IDRM -- Repetitive peak off-state current 50/60 Hz sine wave; V = VDRM IH -- Dynamic holding current 50/60 Hz sine wave; R = 100 IT(RMS) -- On-state RMS current TJ 125 C 50/60 Hz sine wave ITSM -- Peak one-cycle surge current 50/60 Hz sine wave (nonrepetitive) RS -- Switching resistance R
Electrical Specification Notes
(1) (2) (3) (4) (5) (6) See Figure E9.5 for VBO change versus junction temperature. See Figure E9.6 for IBO versus junction temperature. See Figure E9.2 for IH versus case temperature. See Figure E9.13 for test circuit. See Figure E9.1 for more than one full cycle rating. TC 90 C for TO-92 Sidac TC 105 C for TO-202 Sidacs TL 100 C for DO-15X TL 90 C for DO-214 See Figure E9.14 for clarification of sidac operation. For best sidac operation, the load impedance should be near or less than switching resistance. See package outlines for lead form configurations. When ordering special lead forming, add type number as suffix to part number.
S
( V BO - V S ) = ------------------------------- 50/60 Hz sine wave ( I - I BO ) S
(7) (8) (9)
VBO -- Breakover voltage 50/60 Hz sine wave VDRM -- Repetitive peak off-state voltage VTM -- Peak on-state voltage; IT = 1 A
(10) Do not use electrically connected mounting tab or center lead.
+I IT IH IS IDRM IBO +V VBO VS VDRM RS
General Notes
* * * All measurements are made at 60 Hz with a resistive load at an ambient temperature of +25 C unless otherwise specified. Storage temperature range (TS) is -65 C to +150 C. The case (TC) or lead (TL) temperature is measured as shown on the dimensional outline drawings in the "Package Dimensions" section of this catalog. Junction temperature range (TJ) is -40 C to +125 C. Lead solder temperature is a maximum of +230 C for 10-second maximum; 1/16" (1.59 mm) from case.
RS = (VBO - VS) (IS - IBO)
-V
* *
VT
-I
V-I Characteristics
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(c)2002 Teccor Electronics Thyristor Product Catalog
Data Sheets
Sidac
VTM
ITSM
(5)
RS
(8)
dv/dt
di/dt
Volts MAX Package E 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 G 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 3 3 3 3 3 F S 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 20 20 20 20 20 20 20 20 20 20 20 20 60 Hz
Amps 50 Hz 16.7 16.7 16.7 16.7 16.7 16.7 16.7 16.7 16.7 16.7 16.7 16.7 k MIN 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 Volts/Sec MIN 1500 1500 1500 1500 1500 1500 1500 1500 1500 1500 1500 1500 Amps/Sec TYP 150 150 150 150 150 150 150 150 150 150 150 150
Thermal Resistance (Steady State) RJC [RJA] C/W (TYPICAL)
E Package G Package F Package S Package
IH IH(TC = 25 C) Ratio of
2.0
1.5
1.0 .5 0
35 [95]
18 [75]
7 [45] **
30 * [85]
* Mounted on 1 cm2 copper foil surface; two-ounce copper foil ** RJA for TO-202 Type 23 and Type 41 is 70 C/Watt.
-40
-15
+25
+65
+105
+125
Case Temperature (TC) - C 100
Peak Surge (Non-repetitive) On-state Current [ITSM] - Amps
40
SUPPLY FREQUENCY: 60 Hz Sinusoidal LOAD: Resistive RMS ON-STATE CURRENT: IT RMS Maximum Rated Value at Specified Junction Temperature
Figure E9.2 Normalized DC Holding Current versus Case/Lead Temperature
20 10 8.0 6.0 4.0
Notes: 1) Blocking capability may be lost during and immediately following surge current interval. 2) Overload may not be repeated until junction temperature has returned to steady-state rated value.
2.0 1.0
1.0
10
100
1000
Surge Current Duration - Full Cycles
Figure E9.1 Peak Surge Current versus Surge Current Duration
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Sidac
Data Sheets
600 400
di/dt Limit Line
No n -Re
ITRM VBO Firing Current Waveform
Repetitive Peak On-state Current (ITRM) - Amps
200 100 80 60 40 20 10 8 6 4 2 1 0.8 0.6 4
2 x 10-3
f=
pe
ate
d
pe titi
on
l/f
Fr eq ue nc
f=
10
f=
10
Hz
0H
yf
=5
Repetitive Peak Breakover Current (IBO) Multiplier
Re
to
9 8 7 6 5 4 3 2
z
Hz
V = VBO
1k Hz
TJ = 125 C Max
f=
f=
f=2
5k Hz 10 kH z
z
1 20 30 40 50 60 70 80 90 100 110 120 130
0 kH
Junction Temperature (TJ) - C
68
1 x 10-2
2
4
68
1 x 10-1
2
4 6 81
Pulse base width (to) - ms
Figure E9.3 Repetitive Peak On-state Current (I TRM) versus Pulse Width at Various Frequencies Figure E9.6 Normalized Repetitive Peak Breakover Current versus Junction Temperature
9
CURRENT WAVEFORM: Sinusoidal - 60 Hz LOAD: Resistive or Inductive FREE AIR RATING
140
Maximum Allowable Ambient Temperature (TA) - C
TL = 25 C 8
Positive or Negative Instantaneous On-state Current (iT) - Amps
120
7 6 5 4 3 2 1 0
TO-202 "F" Package TO-92, DO-214 and DO-15X "E", "S" and "G" Packages
100
TO -20 2
80
DO
-1
Ty pe 1
60
5X
TO -9 2
an
dT
O-
40
an d
20
DO -2 14
2T yp
e2
3a
nd
41
25 20 0 0.2 0.4 0.6 0.8 1.0
0
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2 2.4
2.6
2.8
3.0
3.2
3.4
3.6
RMS On-state Current [IT(RMS)] - Amps
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Figure E9.4 Maximum Allowable Ambient Temperature versus On-state Current
Figure E9.7 On-state Current versus On-state Voltage (Typical)
+4
K2xxxF1
2.2 2.0 Average On-state Power Dissipation [PD(AV)] - Watts 1.8 1.6 1.4 1.2 1.0 0.8 0.6 0.4 0.2
+2
Percentage of VBO Change - %
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: See Basic Sidac Cirucit
0 -2 -4 -6 -8 -10 -12 -40 -20 0
K2xxxE K2xxxG K2xxxS K1xxxE K1xxxG K1xxxS
TO-202 "F" Package
"E", "S" and "G" Packages TO-92, DO-214 and DO-15X
+25
+20
+40
+60
+80
+100
+120 +140
0
0.2
0.4
0.6
0.8
1.0
Junction Temperature (TJ) - C
RMS On-state Current [IT(RMS)] - Amps
Figure E9.5 Normalized VBO Change versus Junction Temperature
Figure E9.8 Power Dissipation (Typical) versus On-state Current [Refer to Figure E9.14 for Basic Sidac Circuit]
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Data Sheets
Sidac
SCR
Sidac
100 2W
-
10 F
+
Xenon Lamp
250 V K2200G
20 M
100-250 V ac 60 Hz
100-250 V ac 60 Hz
+ 10 F - 450 V
120 V ac 60 Hz
4 kV Sidac 200400 V Trigger Transformer 20:1 0.01 F 400 V
Figure E9.9 Comparison of Sidac versus SCR for Gas Ignitor Circuit
Figure E9.12 Xenon Lamp Flashing Circuit
Push to test
4.7 F 10 F 100 V
S1
4.7 k
Switch to test in each direction
-
+
-
50 V
+
1/2W
100-250 V ac 60 Hz
K1200E Sidac 200 V
100 1%
Device Under Test
+ 24 V ac 60 Hz
4.7 F 100 V
1.2 F
S1
Scope
IPK
Trace Stops
H.V. Ignitor
IH
Scope Indication
Figure E9.10 Circuit (Low Voltage Input) for Gas Ignition
Figure E9.13 Dynamic Holding Current Test Circuit for Sidacs
Ballast
Ballast
Sidac 3.3 k
0.47 F 400 V Lamp
Sidac 7.5 k
0.22 F Lamp
100-250 V ac 60 Hz
VBO
VBO VBO
IH
Load IH
120 V ac 60 Hz 16 mH
220 V ac 60 Hz
120-145 Conduction Angle
IH
Load Current
120 V ac
220 V ac
Figure E9.11 Typical High Pressure Sodium Lamp Firing Circuit
Figure E9.14 Basic Sidac Circuit
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Sidac
Data Sheets
(a) Circuit V R SIDAC V DC(IN) V B0 V C t L R L I V C (b) Waveforms BO
C
I
L
Rmax R min
V
-V IN BO IBO
t
V
-V IN TM IH (MIN)
Figure E9.15 Relaxation Oscillator Using a Sidac
VCE Monitor (See Note B) RBB1 = 150 TIP-47 100 mH
Input Voltage 0V 5V Collector Current 0.63 A 0
tw 3 ms (See Note A) tw 100 ms
Input 50
2N6127 (or equivalent)
50
RBB2 = 100 + VBB2 =0
+ VCC = 20 V RS = 0.1 IC Monitor
Sidac VBO Collector Voltage 10 V VCE(sat)
VBB1 =10 V
-
Test Circuit
Voltage and Current Waveforms
Note A: Input pulse width is increased until ICM = 0.63 A. Note B: Sidac (or Diac or series of Diacs) chosen so that VBO is just below VCEO rating of transistor to be protected. The Sidac (or Diac) eliminates a reverse breakdown of the transistor in inductive switching circuits where otherwise the transistor could be destroyed.
Figure E9.16 Sidac Added to Protect Transistor for Typical Transistor Inductive Load Switching Requirements
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M1
Package Dimensions
M1
This section contains the dimensions for the following packages: * * * * * * * * * * * * * * * * F Package -- TO-202AB, Type 1 (Non-isolated) Y Package -- DO-35 or DO-204AH R Package -- TO-220AB (Non-isolated) L Package -- TO-220AB (Isolated) P Package -- TO-3 Fastpak (Isolated) E Package -- TO-92 (Isolated) S Package -- DO-214AA M Package -- TO-218AC (Non-isolated) K Package -- TO-218AC (Isolated) W Package -- TO-218X (Non-isolated) J Package -- TO-218X (Isolated) G Package -- DO-15X Axial Lead C Package -- Compak N Package -- TO-263 D Package -- TO-252 V Package -- TO-251
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Package Dimensions
Data Sheets
F Package -- TO-202AB, Type 1
Non-isolated Mounting Tab Common with MT2 / Anode / PIN 2
A Tab Common to MT2 / Anode / PIN 2 R DIA. D Case Temperature Measurement Point E B C G
Inches Dimension A B C D E F G H J K L M N P Q R S MIN 0.365 0.243 0.110 0.780 0.290 0.400 0.052 0.055 0.023 0.095 0.195 0.049 0.017 0.055 0.175 0.124 0.390 MAX 0.385 0.253 0.120 0.810 0.310 0.430 0.062 0.065 0.029 0.105 0.205 0.059 0.023 0.065 0.185 0.130 0.405
MT1 / Cathode / PIN 1 MT2 / Anode / PIN 2 M K L
H
F
J Q Gate / Trigger / PIN 3
N P
0.070 x 45Chamfer Common to All Types S Notes: (1) Maximum torque to be applied to mounting tab is 8 in-lbs. (0.904 Nm) (2) Pin 2 and mounting tab are electrically connected. Do not use either for Sidac operation.
Millimeters MIN MAX 9.27 9.78 6.17 6.43 2.79 3.05 19.81 20.57 7.37 7.87 10.16 10.92 1.32 1.58 1.40 1.65 0.58 0.74 2.41 2.67 4.95 5.21 1.24 1.50 0.43 0.58 1.40 1.65 4.45 4.70 3.15 3.30 9.91 10.29
Y Package -- DO-35 or DO-204AH
1 A DIA.
Inches Dimension A B C D E
C
MIN 0.060 0.135 0.018 1.000
B
MAX 0.090 0.015 0.165 0.022
Millimeters MIN MAX 1.530 2.280 0.381 3.430 4.190 0.458 0.558 25.400
1
(1)
Package contour optional within dimensions A and C. Slugs, if any, shall be included within this cylinder but shall not be subject to the minimum limit of Dimension A. Lead diameter is not controlled in this zone to allow for flash, lead finish build-up, and minor irregularities other than slugs.
(2)
B E TYP D DIA. TYP 2
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Data Sheets
Package Dimensions
R Package -- TO-220AB
Non-isolated Mounting Tab Common with Center Lead
R Package MT2 / Anode
A
O P
Inches Dimension A B C D E F G H J K L M N O P R MIN 0.380 0.105 0.230 0.590 0.142 0.110 0.540 0.025 0.195 0.095 0.060 0.070 0.018 0.178 0.045 0.038 MAX 0.420 0.115 0.250 0.620 0.147 0.130 0.575 0.035 0.205 0.105 0.075 0.085 0.024 0.188 0.060 0.048
C D
B
E DIA. F
Case Temperature Measurement Point Notch in gate lead identifies non-isolated tab Gate/Trigger * MT2 / Anode MT1 / Cathode
G
R
H
N M
L K J
* The gate pin is not used
on diode rectifiers. Note: Maximum torque to be applied to mounting tab is 8 in-lbs. (0.904 Nm).
Millimeters MIN MAX 9.65 10.67 2.66 2.92 5.85 6.35 14.98 15.75 3.61 3.73 2.80 3.30 13.71 14.60 0.63 0.89 4.95 5.21 2.41 2.67 1.52 1.91 1.78 2.16 0.45 0.61 4.52 4.78 1.14 1.53 0.97 1.22
L Package -- TO-220AB
Isolated Mounting Tab
R Package MT2 / Anode
A
O P
Inches Dimension A B C D E F G H J K L M N O P R MIN 0.380 0.105 0.230 0.590 0.142 0.110 0.540 0.025 0.195 0.095 0.060 0.070 0.018 0.178 0.045 0.038 MAX 0.420 0.115 0.250 0.620 0.147 0.130 0.575 0.035 0.205 0.105 0.075 0.085 0.024 0.188 0.060 0.048
C D
B
E DIA. F
Case Temperature Measurement Point Gate/Trigger * MT2 / Anode MT1 / Cathode
G
R
H
N M
L K J
* The gate pin is not used
on diode rectifiers. Note: Maximum torque to be applied to mounting tab is 8 in-lbs. (0.904 Nm).
Millimeters MIN MAX 9.65 10.67 2.66 2.92 5.85 6.35 14.98 15.75 3.61 3.73 2.80 3.30 13.71 14.60 0.63 0.89 4.95 5.21 2.41 2.67 1.52 1.91 1.78 2.16 0.45 0.61 4.52 4.78 1.14 1.53 0.97 1.22
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Package Dimensions
Data Sheets
P Package -- TO-3 Fastpak
Isolated Mounting Base
A B D
Inches Dimension A B C D E F G H I J K L M N O P Q R S T (MT1) T (MT2) T (Gate) U (MT1) U (MT2) U (Gate) V W MIN 1.531 1.177 0.843 0.780 0.783 0.874 0.161 0.386 0.508 0.079 0.047 0.307 0.372 0.043 0.315 0.098 0.846 0.244 0.106 0.321 0.321 0.220 0.246 0.246 0.183 0.120 0.175 MAX 1.543 1.185 0.850 0.795 0.791 0.906 0.169 0.465 0.587 0.087 0.055 0.319 0.396 0.059 0.331 0.106 0.886 0.256 0.130 0.329 0.329 0.228 0.254 0.254 0.191 0.130 0.185
MT2
F
MT1 Gate
H
G
TC Measuring Point
E C I
J (MT1, MT2)
T U R
K (Gate)
M 5-N
L
Q S O P
Millimeters MIN MAX 38.90 39.20 29.90 30.10 21.40 21.60 19.80 20.20 19.90 20.10 22.20 23.00 4.10 4.30 9.80 11.80 12.90 14.90 2.00 2.20 1.20 1.40 7.80 8.10 9.45 10.05 1.10 1.50 8.00 8.40 2.50 2.70 21.50 22.50 6.20 6.50 2.70 3.30 8.15 8.35 8.15 8.35 5.60 5.80 6.25 6.45 6.25 6.45 4.65 4.85 3.05 3.30 4.45 4.70
Note: Maximum torque to be applied to mounting tab is 8 in-lbs. (0.904 Nm).
E Package -- TO-92
TC Measuring Point
Inches Dimension A B D E F G H J K L M MIN 0.176 0.500 0.095 0.150 0.046 0.135 0.088 0.176 0.088 0.013 0.013 MAX 0.196 0.105 0.054 0.145 0.096 0.186 0.096 0.019 0.017
A
B
Cathode / MT1 / PIN 1 Gate / PIN 2
E
Millimeters MIN MAX 4.47 4.98 12.70 2.41 2.67 3.81 1.16 1.37 3.43 3.68 2.23 2.44 4.47 4.73 2.23 2.44 0.33 0.48 0.33 0.43
Anode / MT2 / PIN 3
All leads insulated from case. Case is electrically nonconductive.
M F L D K J
H
G
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Data Sheets
Package Dimensions
S Package -- DO-214AA
B D TC / TL Temperature Measurement Point
Inches Dimension A B C D E F G H J K L MIN 0.140 0.205 0.077 0.166 0.036 0.073 0.004 0.077 0.043 0.008 0.027 MAX 0.155 0.220 0.083 0.180 0.056 0.083 0.008 0.086 0.053 0.012 0.049
CA
H E 0.079 (2.0) J
F
L G
K
Millimeters MIN MAX 3.56 3.94 5.21 5.59 1.96 2.11 4.22 4.57 0.91 1.42 1.85 2.11 0.10 0.20 1.96 2.18 1.09 1.35 0.20 0.30 0.69 1.24
0.110 (2.8) 0.079 (2.0)
Dimensions are in inches (and millimeters).
Pad Outline
M Package -- TO-218AC
Non-Isolated Mounting Tab Common with Center Lead
K Package -- TO-218AC
Isolated Mounting Tab
TC Measurement Point B U DIA. M Package MT2 / Anode C D
Inches Dimension A B C D E F G H J K L M N P Q R U W MIN 0.810 0.610 0.178 0.055 0.487 0.635 0.022 0.075 0.575 0.211 0.422 0.058 0.045 0.095 0.008 0.008 0.159 0.085 MAX 0.835 0.630 0.188 0.070 0.497 0.655 0.029 0.095 0.625 0.219 0.437 0.068 0.055 0.115 0.016 0.016 0.163 0.095
A F E W
Gate / PIN 3 P MT1 / Cathode / PIN 1 MT2 / Anode / PIN 2 J
M
H G
Q
R N 3 Times
K L
Note: Maximum torque to be applied to mounting tab is 8 in-lbs. (0.904 Nm).
Millimeters MIN MAX 20.57 21.21 15.49 16.00 4.52 4.78 1.40 1.78 12.37 12.62 16.13 16.64 0.56 0.74 1.91 2.41 14.61 15.88 5.36 5.56 10.72 11.10 1.47 1.73 1.14 1.40 2.41 2.92 0.20 0.41 0.20 0.41 4.04 4.14 2.17 2.42
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Package Dimensions
Data Sheets
W Package -- TO-218X
Non-isolated Mounting Tab Common with Center Lead
J Package -- TO-218X
Isolated Mounting Tab
C B D U DIA.
W Package MT2 / Anode
INCHES DIM A B C D E F G H J K L M N P R S T U V W X Y Z MIN 0.810 0.610 0.178 0.055 0.487 0.635 0.022 0.075 0.575 0.256 0.220 0.080 0.169 0.034 0.113 0.086 0.156 0.159 0.603 0.000 0.003 0.028 0.085 MAX 0.835 0.630 0.188 0.070 0.497 0.655 0.029 0.095 0.625 0.264 0.228 0.088 0.177 0.042 0.121 0.096 0.166 0.163 0.618 0.005 0.012 0.032 0.095
Tc Measurement Point
A F EZ
MT1 / Cathode
W
X J
Gate
N T M Y K V L
R S P
MT2 / Anode
G H
Note: Maximum torque to be applied to mounting tab is 8 in-lbs. (0.904 Nm).
MILLIMETERS MIN MAX 20.57 21.21 15.49 16.00 4.52 4.78 1.40 1.78 12.37 12.62 16.13 16.64 0.56 0.74 1.91 2.41 14.61 15.88 6.50 6.71 5.58 5.79 2.03 2.24 4.29 4.49 0.86 1.07 2.87 3.07 2.18 2.44 3.96 4.22 4.04 4.14 15.31 15.70 0.00 0.13 0.07 0.30 0.71 0.81 2.17 2.42
G Package -- DO-15X
Axial Lead
L G L D
Inches Dimension B2 D G L MIN 0.027 0.104 0.230 1.000 MAX 0.035 0.150 0.300
Millimeters MIN MAX 0.686 0.889 2.640 3.810 5.840 7.620 25.400
B2
TL Measuring Point
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Data Sheets
Package Dimensions
C Package -- Compak
TC / TL Temperature Measurement Point B D M N P A C Gate
Inches Dimension A B C D E F G H J K L M N P
0.040 (1.0)
MT1 / Cathode MT2 / Anode
H
F L
E
J
MIN 0.140 0.205 0.077 0.166 0.036 0.073 0.004 0.077 0.043 0.008 0.027 0.022 0.027 0.052
MAX 0.155 0.220 0.083 0.180 0.056 0.083 0.008 0.086 0.053 0.012 0.049 0.028 0.033 0.058
K 0.079 (2.0) 0.079 (2.0)
G
0.079 (2.0)
Millimeters MIN MAX 3.56 3.94 5.21 5.59 1.96 2.11 4.22 4.57 0.91 1.42 1.85 2.11 0.10 0.20 1.96 2.18 1.09 1.35 0.20 0.30 0.69 1.24 1 0.71 0.56 0.69 0.84 1.32 1.47
0.110 (2.8)
0.030 (0.76)
Dimensions are in inches (and millimeters).
Pad Outline
N Package -- TO-263
D2Pak Surface Mount
MT2 / Anode B Case Temperature Measurement A S V C E
Inches Dimension A B C D E F G H J K S V U W MIN 0.360 0.380 0.178 0.025 0.048 0.060 0.095 0.083 0.018 0.090 0.590 0.035 0.002 0.040 MAX 0.370 0.420 0.188 0.035 0.055 0.075 0.105 0.093 0.024 0.110 0.625 0.045 0.010 0.070
U W K MT1 / Cathode G F Gate D 2PL J H
0.46 (11.684) 0.085 (2.159) 0.17 (4.318) 0.665 (16.891) 0.35 (8.89) 0.26 (6.604) 0.15 (3.81) 0.08 (2.032) 0.115 (2.921)
Dimensions are in inches (and millimeters).
Millimeters MIN MAX 9.14 9.40 9.65 10.67 4.52 4.78 0.63 0.89 1.22 1.40 1.52 1.91 2.41 2.67 2.11 2.36 0.46 0.61 2.29 2.79 14.99 15.87 0.89 1.14 0.05 0.25 1.02 1.78
Pad Outline
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Package Dimensions
Data Sheets
D Package -- TO-252AA
D-Pak Surface Mount
H G Case Temperature Measurement Point A B Gate O D MT1 / Cathode C F E P L MT2 / Anode
M K
Inches Dimension A B C D E F G H J K L M N O P MIN 0.236 0.379 0.176 0.035 0.087 0.027 0.205 0.251 0.040 0.086 0.026 0.018 0.170 0.002 0.018 MAX 0.244 0.409 0.184 0.050 0.093 0.033 0.213 0.261 0.050 0.094 0.036 0.023 0.180 0.010 0.023
Dimensions are in inches (and millimeters). 0.264 (6.7) .460
Millimeters MIN MAX 6.00 6.20 9.63 10.39 4.47 4.67 0.89 0.27 2.21 2.36 0.69 0.84 5.21 5.41 6.38 6.63 1.02 1.27 2.18 2.39 0.66 0.91 0.46 0.58 4.32 4.57 0.05 0.25 0.46 0.58
0.264 (6.7)
0.071 (1.8) 0.118 (3.0) 0.063 (1.6) 0.181 (4.6)
Pad Outline
V Package -- TO-251AA
V-Pak Through Hole
MT2 / Anode E A D Case Temperature Measurement Point B Mounting Tab Internally Connected to MT2
H J
Inches Dimension A B C D E F G H J K L MIN 0.040 0.236 0.350 0.205 0.251 0.027 0.087 0.086 0.018 0.036 0.018 MAX 0.050 0.244 0.375 0.213 0.261 0.033 0.093 0.094 0.023 0.042 0.023
K C F
Millimeters MIN MAX 1.02 1.27 6.00 6.20 8.89 9.53 5.21 5.41 6.38 6.63 0.69 0.84 2.21 2.36 2.18 2.39 0.46 0.58 0.91 1.07 0.46 0.58
Gate MT1 / Cathode MT2 / Anode G
L
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M1 - 8
2002 Teccor Electronics
Thyristor Product Catalog
M2
Lead Form Dimensions
M2
The TO-202AB, TO-220AB, and TO-92 package configurations, because of their unique design, can be mounted in a variety of methods, depending upon heat sink requirements and circuit packaging methods. Any of the derived types shown in this section are available as standard parts direct from the factory. Custom package variations are available. Consult the factory for more information. To designate lead form options, simply indicate the type number at the end of the Teccor standard part number. Example: Q2004F312 (Signifies Type 12) Note: When ordering a TO-202 F package, include a 1 for standard full tab package. When ordering anything other than full tab, remove the 1 and add the Lead Form Type. See "Description of Part Numbers" in the Product Selection Guide of this catalog for a complete description of Teccor part numbers.
Lead Bending Specifications
Leads may be bent easily and may be bent to any desired angle, provided that the bend is made at a minimum 0.063" (0.1 for TO-218) away from the package body with a minimum radius of 0.032". DO-15X device leads may be bent with a minimum radius of 0.050", and DO-35 device leads may be bent with a minimum radius of 0.028". Leads should be held firmly between the package body and the bend, so that strain on the leads is not transmitted to the package body. When bending leads in the plane of the leads (spreading), bend only the narrow part. Sharp angle bends should be done only once, as repetitive bending will fatigue and break the leads.
(c)2002 Teccor Electronics Thyristor Product Catalog
M2 - 1
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Lead Form Dimensions
Data Sheets
TO-202AB Type 11 -- F Package
Tab Common to MT2 / Anode
TO-202AB Type 2 -- F Package
A
B
A
MT1 / Cathode MT2 / Anode Gate
MT1 / Cathode MT2 / Anode Gate
MT2 / Anode
B
C
Inches Dimension A B C MIN 0.080 0.301 0.080 MAX 0.120 0.361 0.120
Millimeters MIN MAX 2.03 3.05 7.65 9.17 2.03 3.05
Inches Dimension A B MIN 0.240 0.030 MAX 0.260 0.050
Millimeters MIN MAX 6.100 6.60 0.762 1.27
TO-202AB Type 12 -- F Package
TO-202AB Type 21 -- F Package
Tab Common to MT2 / Anode
B A B C
MT1 / Cathode MT2 / Anode Gate
A
D
MT2 / Anode
MT1 / Cathode MT2 / Anode Gate
E
Inches Inches Dimension A B MIN 0.435 0.120 MAX 0.495 0.160 Millimeters MIN MAX 11.05 12.57 3.05 4.06 Dimension A B C D E MIN 0.030 0.240 0.080 0.301 0.080 MAX 0.050 0.260 0.120 0.361 0.120
Millimeters MIN MAX 0.762 1.27 6.100 6.60 2.030 3.05 7.650 9.17 2.030 3.05
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M2 - 2
(c)2002 Teccor Electronics Thyristor Product Catalog
Data Sheets
Lead Form Dimensions
TO-202AB Type 23 -- F Package
Sidac Only
TO-202AB Type 3 -- F Package
Non-isolated
MT2 / Anode
A
C
B
B
A
MT1 / Pin 1 MT2 / Pin 2 MT1 / Cathode Gate
Inches Dimension A B C MIN 0.240 0.030 0.030 MAX 0.260 0.050 0.050
Millimeters MIN MAX 6.100 6.60 0.762 1.27 0.762 1.27
Inches Dimension A B MIN 0.030 0.645 MAX 0.050 0.705
Millimeters MIN MAX 0.762 1.27 16.380 17.91
TO-202AB Type 26 -- F Package
TO-202AB Type 32 -- F Package
Non-isolated
MT2 / Anode
A
B
C
B
C
A
Gate MT2 / Anode MT1 / Cathode
D E
MT1 / Cathode Gate
Inches Dimension A B C D E MIN 0.240 0.030 0.050 0.095 0.172 MAX 0.260 0.050 0.070 0.105 0.202
Millimeters MIN MAX 6.100 6.60 0.762 1.27 0.127 1.78 2.410 2.67 4.370 5.13
Inches Dimension A B C MIN 0.030 0.435 0.120 MAX 0.050 0.495 0.160
Millimeters MIN MAX 0.762 1.27 11.050 12.57 3.050 4.06
(c)2002 Teccor Electronics Thyristor Product Catalog
M2 - 3
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Lead Form Dimensions
Data Sheets
TO-202AB Type 4 -- F Package
TO-202AB Type 43 -- F Package
Surface Mount
A
MT2 / Anode
B C G
0.150 MT2 / Anode
D
G
C D
0.450
A
Gate
B
E
E
F
0.050 Five PLCs
0.150 MT1 / Cathode
F
MT1 / Cathode
Pad Outline
Gate
Inches Dimension A B C D E F G MIN 0.240 0.114 0.023 0.030 0.297 0.030 0.297 MAX 0.260 0.134 0.029 0.050 0.327 0.050 0.327
Millimeters MIN MAX 6.100 6.600 2.900 3.400 0.584 0.737 0.762 1.270 7.540 8.310 0.765 1.270 7.540 8.310
Inches Dimension A B C D E F G MIN 0.030 0.680 0.110 0.080 0.080 0.110 0.000 MAX 0.050 0.760 0.130 0.100 0.100 0.130 0.013
Millimeters MIN MAX 0.762 1.270 17.270 19.300 2.800 3.300 2.030 2.540 2.030 2.540 2.800 3.300 0.000 0.330
TO-202AB Type 41 -- F Package
TO-220 Type 51 -- R or L Package
Replaces RCA 6249
MT2 / Anode
Mounting Tab Common to MT2 / Anode for Non-isolated R Package
A
C
B
Gate MT1 / Cathode
A B
MT2 / Anode Gate
Ref Only MT1 / Cathode
Inches Dimension A B MIN 0.380 0.180 MAX 0.420 0.220
Millimeters MIN MAX 9.65 10.67 4.57 5.59
Inches Dimension A B C MIN 0.320 0.190 0.795 MAX 0.340 0.850
Millimeters MIN MAX 8.13 8.64 4.83 20.19 21.59
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M2 - 4
(c)2002 Teccor Electronics Thyristor Product Catalog
Data Sheets
Lead Form Dimensions
TO-220 Type 52 -- R or L Package
TO-220 Type 54 -- R Package
Replaces Motorola Form 4, G.E. Type 4, RCA 6206
Mounting Tab Common to MT2 / Anode for Non-isolated R Package
MT2 / Anode
B
Gate / Trigger MT2 / Anode MT1 / Cathode
A
D
C
A
Gate MT1 / Cathode
B
Inches Dimension A B C D MIN 0.169 0.040 0.250 0.110 MAX 0.189 0.060 0.170
Millimeters MIN MAX 4.29 4.80 1.02 1.52 6.35 2.79 4.32
Inches Dimension A B MIN 0.040 0.500 MAX 0.070
Millimeters MIN MAX 1.02 1.78 12.70
TO-220 Type 55 -- R or L Package TO-220 Type 53 -- R or L Package
Replaces G.E. Type 5
Mounting Tab Common to MT2 / Anode for Non-isolated R Package
Mounting Tab Common to MT2 / Anode for Non-isolated R Package
B
A
MT1 / Cathode MT2 / Anode
A
MT2 / Anode Gate / Trigger
MT1 / Cathode MT2 / Anode Gate / Trigger
B
C
MT2 / Anode
D
C
Inches Dimension A B C D MIN 0.175 0.542 0.167 0.355 MAX 0.582 0.207 0.395
Millimeters MIN MAX 4.45 13.77 14.78 4.24 5.26 9.02 10.03
Inches Dimension A B C MIN 0.065 0.353 0.115 MAX 0.095 0.433 0.130
Millimeters MIN MAX 1.65 2.41 8.97 11.00 2.92 3.30
(c)2002 Teccor Electronics Thyristor Product Catalog
M2 - 5
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Lead Form Dimensions
Data Sheets
TO-220 Type 56 -- R or L Package
Replaces G.E. Type 6, Motorola Lead Form 3, RCA 6221
TO-220 Type 58 -- R or L Package
Mounting Tab Common to MT2 / Anode for Non-isolated R Package
Mounting Tab Common to MT2 / Anode for Non-isolated R Package
B
A
A
Gate / Trigger MT2 / Anode MT2 / Anode MT1 / Cathode
B C
MT1 / Cathode MT2 / Anode
MT2 / Anode Gate
C D
Inches Inches Dimension A B C MIN 0.570 0.120 0.172 MAX 0.590 0.130 0.202 Millimeters MIN MAX 14.48 14.99 3.05 3.30 4.37 5.13 Dimension A B C D MIN 0.175 0.542 0.167 0.355 MAX 0.582 0.207 0.395
Millimeters MIN MAX 4.45 13.77 14.78 4.24 5.26 9.02 10.03
TO-220 Type 57 -- R Package
Similar to TO-66, Gate-Cathode Reversed
TO-220 Type 59 -- R or L Package
Mounting Tab Common to MT2 / Anode for Non-isolated R Package
MT2 / Anode
B
B
A
MT2 / Anode
Gate
MT1 / Cathode
A MT1 / Cathode C
Gate
D
MT2 / Anode
C
Inches Dimension A B C MIN 0.040 0.570 0.340 MAX 0.070 0.590 0.422
Millimeters MIN MAX 1.02 1.78 14.48 14.99 8.64 10.72
Inches Dimension A B C D MIN 0.685 0.558 0.375 0.250 MAX 0.725 0.598
Millimeters MIN MAX 17.40 18.42 14.17 15.19 9.53 6.35
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M2 - 6
(c)2002 Teccor Electronics Thyristor Product Catalog
Data Sheets
Lead Form Dimensions
TO-220 Type 65 -- R or L Package
Replaces RCA 6210
TO-220 Type 68 -- R or L Package
Surface Mount
Mounting Tab Common to MT2 / Anode for Non-isolated R Package
0.460
This Footprint Optional
Mounting Tab Common to MT2 / Anode for Non-isolated R Package 0.270
D
B
0.860 0.170 0.115 0.230
A
MT1 / Cathode MT2 / Anode
A
MT2 / Anode
C
.150
B C
Gate / Trigger MT2 / Anode MT1 / Cathode
Gate / Trigger
D
0.045 0.055 TYP
0.050 TYP
Pad Outline
Inches Dimension A B C D MIN 0.550 0.820 0.530 0.080 MAX 0.580 0.260 0.570 0.120
Millimeters MIN MAX 12.70 14.27 14.73 15.75 7.62 2.03 3.05
Inches Dimension A B C D MIN 0.780 0.080 0.110 MAX 0.850 0.100 0.130 0.013
Millimeters MIN MAX 19.05 21.59 2.03 2.54 2.79 3.30 0.33
TO-220 Type 67 -- R Package
Surface Mount
TO-92 Type 70 -- E Package
Sidac Only
MT2 / Anode 0.460
D
Flat Side
This Footprint Optional
0.270
A
0.860 0.230 0.170 0.115
A
B
0.150 0.155 0.050 TYP Gate MT1 / Cathode
C
MT1 / Pin 1 MT2 / Pin 3
B
Pad Outline
Inches Dimension A B C D MIN 0.780 0.080 0.110 MAX 0.850 0.100 0.130 0.013
Millimeters MIN MAX 19.05 21.59 2.03 2.54 2.79 3.30 0.33
Inches Dimension A B MIN 0.50 MAX 0.060
Millimeters MIN MAX 1.52 12.7
(c)2002 Teccor Electronics Thyristor Product Catalog
M2 - 7
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Lead Form Dimensions
Data Sheets
TO-92 Type 73 -- E Package
Surface Mount
TO-218 Type 81 -- K, M, J, or W Packages
Mounting Tab Common to MT2 / Anode on W Package
A
B C
MT1 / Cathode / Pin 1 Gate / Pin 2 MT2 / Anode/ Pin 3
A
0.08 0.034 TYP 0.016 TYP
B
MT1 / Cathode MT2 / Anode Gate
Pad Outline
Inches Inches Dimension A B C MIN 0.000 0.052 0.295 MAX 0.010 0.067 0.315 Millimeters MIN MAX 0.000 0.254 1.320 1.700 7.490 8.000 Dimension A B MIN 0.080 0.580 MAX 0.120 0.640
Millimeters MIN MAX 2.03 3.05 14.73 16.26
TO-218 Type 82 -- M and W Packages TO-92 Type 75 -- E Package
Replaces TO-5 Pinout
Mounting Tab Common to MT2 / Anode Flat Side
D TYP A B
A
Gate / Pin 2
B
MT1 / Cathode / Pin 1 Gate / Pin 2 MT2 / Anode / Pin 3 MT1 / Cathode Gate
C
C
F E
Inches Dimension A B C MIN 0.080 0.580 MAX 0.095 0.120 0.640
Inches Dimension A B C D E F MIN 0.400 0.500 0.080 0.045 0.180 0.080 MAX
0.120 0.085 0.220 0.120
Millimeters MIN MAX 10.16 12.70 2.03 3.05 1.14 2.16 4.57 5.59 2.03 3.05
Millimeters MIN MAX 2.41 2.03 3.05 14.73 16.26
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M2 - 8
(c)2002 Teccor Electronics Thyristor Product Catalog
Data Sheets
Lead Form Dimensions
DO-35 Type 91 -- Y Package
DO-35 Type 93 -- Y Package
Surface Mount
B
A D B C
A
Inches Dimension A B MIN 0.519 0.140 MAX 0.521 0.172
Millimeters MIN MAX 12.18 13.23 3.56 4.37
Inches Dimension A B C D MIN 0.020 0.290 0.370 0.040 MAX 0.060 0.310 0.430 0.060
DO-35 Type 92 -- Y Package
Millimeters MIN MAX 0.508 1.52 7.370 7.87 9.400 10.92 1.020 1.52
B
A
Inches Dimension A B MIN 0.610 0.140 MAX 0.630 0.172
Millimeters MIN MAX 15.49 16.00 3.56 4.37
(c)2002 Teccor Electronics Thyristor Product Catalog
M2 - 9
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Notes
M3
Packing Options
M3
Packing options include: * * * * * Bulk Pack Reel Pack (RP) Ammo Pack (AP) Tube Pack (TP) Embossed Carrier (RP)
Sample Instructions for Choosing a Packing Option
(1) If selecting an "L401E6" (sensitive gate, 400 V, 1 A triac in a TO-92 package), choose one of the options available for that device: * Bulk packed in 2,000 quantity * Tape and Reel with 2,000 parts per reel * Tape and Ammo with 2,000 parts per box (2) Add the designated code as a suffix to the device number, such as "L401E6 RP" if selecting Tape and Reel or "L401E6 AP" if selecting Tape and Ammo. (Bulk packing requires no suffix.)
See "Package Type and Packing Options" on page M3-2.
2002 Teccor Electronics
Thyristor Product Catalog
M3 - 1
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Packing Options
Data Sheets
Package Type and Packing Options
Reel Pack (RP) 2,000 Packing Options Ammo Pack Tube Pack (AP) (TP) 2,000 Contact factory for availability Embossed Carrier (RP) Only Type 73
Package Type
TO-92
Package Code E
Bulk Pack 2,000
TO-220
L, R
500
n/a
n/a
50
Only Type 67 and 68
TO-202
F
500
700 (Type 2)
n/a
50
Only Type 43
TO-218
K, J, M, W
250
n/a
n/a
Contact factory for availability
n/a
Fastpak
P
200
n/a
n/a
n/a
n/a
TO-251 V-Pak
V
1,000
Contact factory for availability
n/a
75
n/a
TO-252 D-Pak
D
n/a
n/a
n/a
75
2500
TO-263 D2Pak
N
n/a
n/a
n/a
50
500
DO-214
S
1,000
n/a
n/a
n/a
2500
Compak
C
1,000
n/a
n/a
n/a
2500
DO-35
Y
10,000 Minimum order of 5,000 available
5,000
n/a
n/a
n/a
DO-15X
G
1,000
5,000
n/a
n/a
n/a
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M3 - 2
2002 Teccor Electronics
Thyristor Product Catalog
Data Sheets
Packing Options
TO-92 (3-lead) Reel Pack (RP) Radial Leaded
Meets all EIA-468-B 1994 Standards
1.6 (41.0)
0.236 (6.0)
0.02 (0.5)
0.098 (2.5) MAX
1.26 (32.0)
0.708 (18.0)
0.354 (9.0) 0.5 (12.7) 0.1 (2.54) 14.17(360.0) MT1 / Cathode 0.2 (5.08) Gate 0.157 DIA (4.0) MT2 / Anode
Flat up
1.97 (50.0) Dimensions are in inches (and millimeters).
Direction of Feed
TO-92 (3-lead) Ammo Pack (AP) Radial Leaded
Meets all EIA-468-B 1994 Standards
0.236 (6.0) 1.62 (41.2) 0.708 (18.0)
0.02 (0.5)
0.098 (2.5) MAX
1.27 (32.2)
0.354 (9.0) 0.5 (12.7) 0.1 (2.54) MT2 / Anode 0.2 (5.08) MT1 / Cathode 0.157 (4.0) DIA
Gate
Flat down
n Directio of Feed
25 Devices per fold
1.85 (47.0)
12.2 (310.0) Dimensions are in inches (and millimeters).
1.85 (47.0)
13.3 (338.0)
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Thyristor Product Catalog
M3 - 3
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Packing Options
Data Sheets
TO-92 Type 70 Reel Pack (RP3) Optional
Meets all EIA-468-B 1994 Standards
0.236 (6.0) 1.3 (33.1) 0.708 (18.0)
0.02 (0.5) 0.95 (24.1)
0.354 (9.0) 0.5 (12.7) 0.1 (2.54)
0.157 DIA (4.0)
14.17 (360.0)
Dimensions are in inches (and millimeters).
Flat Up
1.97 (50.0)
Direction of Feed
TO-92 Type 70 Reel Pack (RP2) Standard
Meets all EIA-468-B 1994 Standards
0.50 (12.7) 0.236 (6.0) 1.62 (41.2) 0.708 (18.0) 0.354 (9.0) 0.50 (12.7) 14.17 (360.0) 0.02 (0.5)
0.25 (6.35)
0.125 (3.2) MAX 1.27 (32.2)
0.20 (5.08) 0.157 DIA (4.0)
Flat Down 1.97 (50.0) Dimensions are in inches (and millimeters).
Direction of Feed
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M3 - 4
2002 Teccor Electronics
Thyristor Product Catalog
Data Sheets
Packing Options
TO-92 Type 70 Ammo Pack (AP) Radial Leaded
Meets all EIA-468-B 1994 Standards
0.50 (12.7) 0.02 (0.5)
0.25 (6.35)
1.62 (41.2) MAX
0.236 (6.0)
0.125 (3.2) MAX
1.27 (32.2)
0.708 (18.0)
0.354 (9.0) 0.50 (12.7) 0.20 (5.08) 0.157 (4.0) DIA
Directio
d n of Fee
Flat down
25 Devices per fold
1.85 (47.0)
12.2 (310.0)
1.85 (47.0) 13.3 (338.0)
Dimensions are in inches (and millimeters).
2002 Teccor Electronics
Thyristor Product Catalog
M3 - 5
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Packing Options
Data Sheets
TO-202 Type 2 Reel Pack (RP)
Meets all EIA-468-B 1994 Standards
0.236 (6.0) 1.33 (33.8) 0.708 (18.0)
0.02 (0.5) 0.63 (16.0) 0.354 (9.0) 0.5 (12.7) 0.1 (2.54) 0.2 (5.08) MT1 / Cathode MT2 / Anode 14.17 (360.0) Dimensions are in inches (and millimeters). Gate 0.157 (4.0) DIA
1.97 (50.0)
Direction of Feed
Reel Pack (RP) for TO-252 Embossed Carrier
Meets all EIA-481-2 Standards
0.157 (4.0) Gate
0.059 DIA (1.5)
MT1 / Cathode
* Cover tape
0.315 (8.0)
MT2 / Anode
0.512 (13.0) Arbor Hole Dia.
12.99 (330.0) Dimensions are in inches (and millimeters).
0.64 (16.3)
Direction of Feed
XXXXXX
0.63 (16.0)
0.524 (13.3)
*
DC
DC
DC
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M3 - 6
2002 Teccor Electronics
Thyristor Product Catalog
Data Sheets
Packing Options
TO-263 Embossed Carrier Reel Pack (RP)
Meets all EIA-481-2 Standards
0.63 (16.0)
0.157 (4.0) Gate 0.059 DIA (1.5) MT1 / Cathode
0.945 (24.0)
0.827 (21.0)
*
* Cover tape
MT2 / Anode 12.99 (330.0) Dimensions are in inches (and millimeters).
0.512 (13.0) Arbor Hole Dia.
1.01 (25.7)
Direction of Feed
DO-214 Embossed Carrier Reel Pack (RP)
Meets all EIA-481-1 Standards
0.157 (4.0)
0.472 (12.0)
0.36 (9.2)
0.315 (8.0)
0.059 DIA (1.5) 12.99 (330.0)
Cover tape
0.512 (13.0) Arbor Hole Dia.
Dimensions are in inches (and millimeters).
0.49 (12.4)
Direction of Feed
2002 Teccor Electronics
Thyristor Product Catalog
M3 - 7
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Packing Options
Data Sheets
Compak Embossed Carrier Reel Pack (RP)
Meets all EIA-481-1 Standards
0.157 (4.0) 0.47 (12.0)
Anode / MT2
0.36 (9.2) 8.0 0.315 (8.0) Gate Cathode / MT1
0.059 DIA (1.5)
Cover tape
0.512 (13.0) Arbor Hole Dia.
12.99 (330.0) Dimensions are in inches (and millimeters).
0.49 (12.4)
Direction of Feed
DO-15X and DO-35 Reel Pack (RP)
Meets all EIA RS-296 Standards
DO-15X
DO-35
2.063 (52.4)
2.063 (52.4) 0.956 (24.3)
0.898 (22.8) 0.252 (6.4)
0.252 (6.4)
0.197 (5.0)
10.0 - 14.0 (254.0 - 356.0)
0.197 (5.0)
Dimensions are in inches (and millimeters). 3.15 (80.0) TYP
Direction of Feed
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M3 - 8
2002 Teccor Electronics
Thyristor Product Catalog
Application Notes
Fundamental Characteristics of Thyristors - - - - - - - - - - - - - - - - - - Gating, Latching, and Holding of SCRs and Triacs - - - - - - - - - - - - Phase Control Using Thyristors- - - - - - - - - - - - - - - - - - - - - - - - - - Mounting and Handling of Semiconductor Devices - - - - - - - - - - - - Surface Mount Soldering Recommendations - - - - - - - - - - - - - - - - Testing Teccor Semiconductor Devices Using Curve Tracers - - - - Thyristors Used as AC Static Switches and Relays- - - - - - - - - - - - Explanation of Maximum Ratings and Characteristics for Thyristors Miscellaneous Design Tips and Facts - - - - - - - - - - - - - - - - - - - - - Thyristors for Ignition of Fluorescent Lamps - - - - - - - - - - - - - - - - - AN1001 AN1002 AN1003 AN1004 AN1005 AN1006 AN1007 AN1008 AN1009 AN1010
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Notes
AN1001
AN1001
Fundamental Characteristics of Thyristors
The connections between the two transistors trigger the occurrence of regenerative action when a proper gate signal is applied to the base of the NPN transistor. Normal leakage current is so low that the combined hFE of the specially coupled two-transistor feedback amplifier is less than unity, thus keeping the circuit in an off-state condition. A momentary positive pulse applied to the gate biases the NPN transistor into conduction which, in turn, biases the PNP transistor into conduction. The effective hFE momentarily becomes greater than unity so that the specially coupled transistors saturate. Once saturated, current through the transistors is enough to keep the combined hFE greater than unity. The circuit remains "on" until it is "turned off" by reducing the anode-to-cathode current (IT) so that the combined hFE is less than unity and regeneration ceases. This threshold anode current is the holding current of the SCR.
Introduction
The thyristor family of semiconductors consists of several very useful devices. The most widely used of this family are silicon controlled rectifiers (SCRs), triacs, sidacs, and diacs. In many applications these devices perform key functions and are real assets in meeting environmental, speed, and reliability specifications which their electro-mechanical counterparts cannot fulfill. This application note presents the basic fundamentals of SCR, triac, sidac, and diac thyristors so the user understands how they differ in characteristics and parameters from their electromechanical counterparts. Also, thyristor terminology is defined.
SCR
Basic Operation
Figure AN1001.1 shows the simple block construction of an SCR.
Anode P N Gate P N Cathode Cathode
J1 J2 J3
Geometric Construction
Figure AN1001.3 shows cross-sectional views of an SCR chip and illustrations of current flow and junction biasing in both the blocking and triggering modes.
Anode
Gate (+) IGT
Cathode (-) N N P (+) Anode IT Forward Blocking Junction
Cathode (-)
Gate
P
Block Construction
Figure AN1001.1
Schematic Symbol
SCR Block Construction
(+) Anode
The operation of a PNPN device can best be visualized as a specially coupled pair of transistors as shown in Figure AN1001.2.
Anode P N N J2 N P Gate N Cathode Cathode Gate P J3 N P P J1 N J2 Load Anode
Forward Bias and Current Flow
Equivalent Diode Relationship
Gate
Cathode (+) N N P (-) Anode Reverse Biased Junction Reverse Biased Gate Junction
Cathode (+)
P
(-) Anode
Reverse Bias
Two-transistor Schematic
Figure AN1001.2
Two-transistor Block Construction Equivalent
Figure AN1001.3
Equivalent Diode Relationship
Coupled Pair of Transistors as a SCR
Cross-sectional View of SCR Chip
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Application Notes
Triac
Basic Operation
Figure AN1001.4 shows the simple block construction of a triac. Its primary function is to control power bilaterally in an AC circuit.
Geometric Construction
Figure AN1001.6 show simplified cross-sectional views of a triac chip in various gating quadrants and blocking modes.
GATE(+) IGT
MT1(-)
Main Terminal 2 (MT2)
N
P
N
N
P
N
Main Terminal 1 (MT1)
Gate
N
N
P N
MT1(-)
P
N
Block Construction
MT2
IT
MT2(+)
QUADRANT I
GATE(-) IGT MT1(-)
Blocking Junction
Gate
N
N
P
MT2(+)
N
MT1
P
N
Equivalent Diode Relationship
Schematic Symbol
Figure AN1001.4 Triac Block Construction
MT2(+)
QUADRANT II
Operation of a triac can be related to two SCRs connected in parallel in opposite directions as shown in Figure AN1001.5. Although the gates are shown separately for each SCR, a triac has a single gate and can be triggered by either polarity.
MT1
GATE(-) IGT
N N
MT1(+)
P N
P
N
MT1(+)
MT2(-)
IT
QUADRANT III
GATE(+) IGT
N N
MT1(+)
Blocking Junction
P
N P N
MT2(-)
MT2
MT2(-)
IT
Figure AN1001.5
SCRs Connected as a Triac
QUADRANT IV
Figure AN1001.6
Equivalent Diode Relationship
Since a triac operates in both directions, it behaves essentially the same in either direction as an SCR would behave in the forward direction (blocking or operating).
Simplified Cross-sectional of Triac Chip
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Application Notes
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Sidac
Basic Operation
The sidac is a multi-layer silicon semiconductor switch. Figure AN1001.7 illustrates its equivalent block construction using two Shockley diodes connected inverse parallel. Figure AN1001.7 also shows the schematic symbol for the sidac.
Diac
Basic Operation
The construction of a diac is similar to an open base NPN transistor. Figure AN1001.9 shows a simple block construction of a diac and its schematic symbol.
MT1
MT1 MT1
N
P
N
MT2 MT1
MT2
Block Construction
Schematic Symbol
N2 P3 N4 P5
MT2
P 1 N2 P3 N4
Figure AN1001.9
Diac Block Construction
MT2 Schematic Symbol
Equivalent Diode Relationship
Figure AN1001.7
Sidac Block Construction
The bidirectional transistor-like structure exhibits a high-impedance blocking state up to a voltage breakover point (V BO) above which the device enters a negative-resistance region. These basic diac characteristics produce a bidirectional pulsing oscillator in a resistor-capacitor AC circuit. Since the diac is a bidirectional device, it makes a good economical trigger for firing triacs in phase control circuits such as light dimmers and motor speed controls. Figure AN1001.10 shows a simplified AC circuit using a diac and a triac in a phase control application.
The sidac operates as a bidirectional switch activated by voltage. In the off state, the sidac exhibits leakage currents (IDRM) less than 5 A. As applied voltage exceeds the sidac VBO, the device begins to enter a negative resistance switching mode with characteristics similar to an avalanche diode. When supplied with enough current (IS), the sidac switches to an on state, allowing high current to flow. When it switches to on state, the voltage across the device drops to less than 5 V, depending on magnitude of the current flow. When the sidac switches on and drops into regeneration, it remains on as long as holding current is less than maximum value (150 mA, typical value of 30 mA to 65 mA). The switching current (IS) is very near the holding current (IH) value. When the sidac switches, currents of 10 A to 100 A are easily developed by discharging small capacitor into primary or small, very high-voltage transformers for 10 s to 20 s. The main application for sidacs is ignition circuits or inexpensive high voltage power supplies.
Load
Figure AN1001.10
AC Phase Control Circuit
Geometric Construction
MT1
N
MT1
Geometric Construction
P
N
MT1
MT2
MT2 Equivalent Diode Relationship
N2
P1
Cross-section of Chip
P3
P5 N4
Figure AN1001.11
Cross-sectional View of Diac Chip
MT2
Figure AN1001.8
Cross-sectional View of a Bidirectional Sidac Chip with Multi-layer Construction
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Application Notes
Electrical Characteristic Curves of Thyristors
+I
+I
Voltage Drop (VT) at Specified Current (iT)
IT IH
Latching Current (IL)
RS
IS
Reverse Leakage Current - (IRRM) at Specified VRRM Off - State Leakage Current - (IDRM) at Specified VDRM
Minimum Holding Current (IH)
-V
IDRM
IBO +V VBO VS VDRM
-V
+V
RS =
Specified Minimum Reverse Blocking Voltage (VRRM) Specified Minimum Off - State Blocking Voltage (VDRM)
(VBO - VS) (IS - IBO)
VT
-I
Reverse Breakdown Voltage Forward Breakover Voltage
-I
Figure AN1001.15
V-I Characteristics of a Sidac Chip
Figure AN1001.12
V-I Characteristics of SCR Device
Methods of Switching on Thyristors
Three general methods are available for switching thyristors to on-state condition: * Application of gate signal Static dv/dt turn-on Voltage breakover turn-on
+I
Voltage Drop (VT) at Specified Current (iT)
Latching Current (IL)
* *
Off-state Leakage Current - (IDRM) at Specified VDRM Minimum Holding Current (IH)
Application Of Gate Signal
Gate signal must exceed IGT and VGT requirements of the thyristor used. For an SCR (unilateral device), this signal must be positive with respect to the cathode polarity. A triac (bilateral device) can be turned on with gate signal of either polarity; however, different polarities have different requirements of IGT and VGT which must be satisfied. Since diacs and sidacs do not have a gate, this method of turn-on is not applicable. In fact, the single major application of diacs is to switch on triacs.
-V
+V
Specified Minimum Off-state Blocking Voltage (VDRM)
-I
Breakover Voltage
Static dv/dt Turn-on
Static dv/dt turn-on comes from a fast-rising voltage applied across the anode and cathode terminals of an SCR or the main terminals of a triac. Due to the nature of thyristor construction, a small junction capacitor is formed across each PN junction. Figure AN1001.16 shows how typical internal capacitors are linked in gated thyristors.
Figure AN1001.13
V-I Characteristics of Triac Device
+I
10 mA V
Breakover Current IBO
-V
+V
Breakover Voltage VBO
Figure AN1001.16
-I
Internal Capacitors Linked in Gated Thyristors
Figure AN1001.14
V-I Characteristics of Bilateral Trigger Diac
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Application Notes
AN1001
When voltage is impressed suddenly across a PN junction, a charging current flows, equal to: dv i = C ae ------o e dt o dv When C ae ------o becomes greater or equal to thyristor IGT, e dt o the thyristor switches on. Normally, this type of turn-on does not damage the device, providing the surge current is limited. Generally, thyristor application circuits are designed with static dv/dt snubber networks if fast-rising voltages are anticipated.
modes are Quadrants II and III where the gate has a negative polarity supply with an AC main terminal supply. Typically, Quadrant II is approximately equal in gate sensitivity to Quadrant I; however, latching current sensitivity in Quadrant II is lowest. Therefore, it is difficult for triacs to latch on in Quadrant II when the main terminal current supply is very low in value. Special consideration should be given to gating circuit design when Quadrants I and IV are used in actual application, because Quadrant IV has the lowest gate sensitivity of all four operating quadrants.
General Terminology
The following definitions of the most widely-used thyristor terms, symbols, and definitions conform to existing EIA-JEDEC standards: Breakover Point - Any point on the principal voltage-current characteristic for which the differential resistance is zero and where the principal voltage reaches a maximum value Principal Current - Generic term for the current through the collector junction (the current through main terminal 1 and main terminal 2 of a triac or anode and cathode of an SCR) Principal Voltage - Voltage between the main terminals: (1) In the case of reverse blocking thyristors, the principal voltage is called positive when the anode potential is higher than the cathode potential and negative when the anode potential is lower than the cathode potential. (2) For bidirectional thyristors, the principal voltage is called positive when the potential of main terminal 2 is higher than the potential of main terminal 1. Off State - Condition of the thyristor corresponding to the highresistance, low-current portion of the principal voltage-current characteristic between the origin and the breakover point(s) in the switching quadrant(s) On State - Condition of the thyristor corresponding to the lowresistance, low-voltage portion of the principal voltage-current characteristic in the switching quadrant(s).
Voltage Breakover Turn-on
This method is used to switch on sidacs and diacs. However, exceeding voltage breakover of SCRs and triacs is definitely not recommended as a turn-on method. In the case of SCRs and triacs, leakage current increases until it exceeds the gate current required to turn on these gated thyristors in a small localized point. When turn-on occurs by this method, localized heating in a small area may melt the silicon or damage the device if di/dt of the increasing current is not sufficiently limited. Diacs used in typical phase control circuits are basically protected against excessive current at breakover as long as the firing capacitor is not excessively large. When diacs are used in a zener function, current limiting is necessary. Sidacs are typically pulse-firing, high-voltage transformers and are current limited by the transformer primary. The sidac should be operated so peak current amplitude, current duration, and di/dt limits are not exceeded.
Triac Gating Modes Of Operation
Triacs can be gated in four basic gating modes as shown in Figure AN1001.17.
ALL POLARITIES ARE REFERENCED TO MT1 MT2 POSITIVE (Positive Half Cycle)
MT2
(-)
+
MT2
Specific Terminology
Average Gate Power Dissipation [PG(AV)] - Value of gate power which may be dissipated between the gate and main terminal 1 (or cathode) averaged over a full cycle
+
IGT
IGT GATE MT1
(+)
IGT GATE MT1
IGT
(-)
REF MT2 IGT GATE MT1 REF
QII QI QIII QIV
(+)
REF MT2 IGT GATE MT1 REF
Breakover Current (IBO) - Principal current at the breakover point Breakover Voltage (VBO) - Principal voltage at the breakover point Circuit-commutated Turn-off Time (tq) - Time interval between the instant when the principal current has decreased to zero after external switching of the principal voltage circuit and the instant when the thyristor is capable of supporting a specified principal voltage without turning on Critical Rate-of-rise of Commutation Voltage of a Triac (Commutating dv/dt) - Minimum value of the rate-of-rise of principal voltage which will cause switching from the off state to the on state immediately following on-state current conduction in the opposite quadrant
MT2 NEGATIVE (Negative Half Cycle)
-
NOTE: Alternistors will not operate in Q IV
Figure AN1001.17
Gating Modes
The most common quadrants for triac gating-on are Quadrants I and III, where the gate supply is synchronized with the main terminal supply (gate positive -- MT2 positive, gate negative -- MT2 negative). Gate sensitivity of triacs is most optimum in Quadrants I and III due to the inherent thyristor chip construction. If Quadrants I and III cannot be used, the next best operating
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Application Notes
Critical Rate-of-rise of Off-state Voltage or Static dv/dt (dv/dt) - Minimum value of the rate-of-rise of principal voltage which will cause switching from the off state to the on state Critical Rate-of-rise of On-state Current (di/dt) - Maximum value of the rate-of-rise of on-state current that a thyristor can withstand without harmful effect Gate-controlled Turn-on Time (tgt) - Time interval between a specified point at the beginning of the gate pulse and the instant when the principal voltage (current) has dropped to a specified low value (or risen to a specified high value) during switching of a thyristor from off state to the on state by a gate pulse. Gate Trigger Current (IGT) - Minimum gate current required to maintain the thyristor in the on state Gate Trigger Voltage (VGT) - Gate voltage required to produce the gate trigger current Holding Current (IH) - Minimum principal current required to maintain the thyristor in the on state Latching Current (IL) - Minimum principal current required to maintain the thyristor in the on state immediately after the switching from off state to on state has occurred and the triggering signal has been removed On-state Current (IT) - Principal current when the thyristor is in the on state On-state Voltage (VT) - Principal voltage when the thyristor is in the on state Peak Gate Power Dissipation (PGM) - Maximum power which may be dissipated between the gate and main terminal 1 (or cathode) for a specified time duration Repetitive Peak Off-state Current (IDRM) - Maximum instantaneous value of the off-state current that results from the application of repetitive peak off-state voltage Repetitive Peak Off-state Voltage (VDRM) - Maximum instantaneous value of the off-state voltage which occurs across a thyristor, including all repetitive transient voltages and excluding all non-repetitive transient voltages Repetitive Peak Reverse Current of an SCR (IRRM) - Maximum instantaneous value of the reverse current resulting from the application of repetitive peak reverse voltage Repetitive Peak Reverse Voltage of an SCR (VRRM) - Maximum instantaneous value of the reverse voltage which occurs across the thyristor, including all repetitive transient voltages and excluding all non-repetitive transient voltages Surge (Non-repetitive) On-state Current (ITSM) - On-state current of short-time duration and specified waveshape Thermal Resistance, Junction to Ambient (RJA) - Temperature difference between the thyristor junction and ambient divided by the power dissipation causing the temperature difference under conditions of thermal equilibrium Note: Ambient is the point at which temperature does not change as the result of dissipation. Thermal Resistance, Junction to Case (RJC) - Temperature difference between the thyristor junction and the thyristor case divided by the power dissipation causing the temperature difference under conditions of thermal equilibrium
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AN1002
AN1002
Gating, Latching, and Holding of SCRs and Triacs
Triacs (bilateral devices) can be gated on with a gate signal of either polarity with respect to the MT1 terminal; however, different polarities have different requirements of IGT and V GT. Figure AN1002.2 illustrates current flow through the triac chip in various gating modes.
Introduction
Gating, latching, and holding currents of thyristors are some of the most important parameters. These parameters and their interrelationship determine whether the SCRs and triacs will function properly in various circuit applications. This application note describes how the SCR and triac parameters are related. This knowledge helps users select best operating modes for various circuit applications.
Gate(+) IGT
N N
MT1(-)
Gating of SCRs and Triacs
Three general methods are available to switch thyristors to on-state condition: * * * Applying proper gate signal Exceeding thyristor static dv/dt characteristics Exceeding voltage breakover point
P N
QUADRANT I
P
IT
N
MT2(+)
This application note examines only the application of proper gate signal. Gate signal must exceed the IGT and VGT requirements of the thyristor being used. IGT (gate trigger current) is the minimum gate current required to switch a thyristor from the off state to the on state. VGT (gate trigger voltage) is the voltage required to produce the gate trigger current. SCRs (unilateral devices) require a positive gate signal with respect to the cathode polarity. Figure AN1002.1 shows the current flow in a cross-sectional view of the SCR chip.
Gate(-) IGT
N N
MT1(-)
P N
QUADRANT II
P
N
MT2(+)
Gate(-)
MT1(+)
Gate (+) I GT P N P
Cathode (-) N
IGT
N N
P N
QUADRANT III
P
N
MT2(-)
IT MT1(+)
(+) I T Anode
Figure AN1002.1 SCR Current Flow
Gate(+) IGT
N N
P
QUADRANT IV
P
N N
In order for the SCR to latch on, the anode-to-cathode current (IT) must exceed the latching current (IL) requirement. Once latched on, the SCR remains on until it is turned off when anode-to-cathode current drops below holding current (IH) requirement.
MT2(-)
IT
Figure AN1002.2
Triac Current Flow (Four Operating Modes)
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Application Notes
Triacs can be gated on in one of four basic gating modes as shown in Figure AN1002.3. The most common quadrants for gating on triacs are Quadrants I and III, where the gate supply is synchronized with the main terminal supply (gate positive -- MT2 positive, gate negative -- MT2 negative). Optimum triac gate sensitivity is achieved when operating in Quadrants I and III due to the inherent thyristor chip construction. If Quadrants I and III cannot be used, the next best operating modes are Quadrants II and III where the gate supply has a negative polarity with an AC main terminal supply. Typically, Quadrant II is approximately equal in gate sensitivity to Quadrant I; however, latching current sensitivity in Quadrant II is lowest. Therefore, it is difficult for triacs to latch on in Quadrant II when the main terminal current supply is very low in value. Special consideration should be given to gating circuit design when Quadrants I and IV are used in actual application, because Quadrant IV has the lowest gate sensitivity of all four operating quadrants.
ALL POLARITIES ARE REFERENCED TO MT1 MT2 POSITIVE (Positive Half Cycle)
2.0
IGT Ratio of I (T = 25C) GT C
1.5
1.0
.5
0 -40 -15 +25 +65 +100
Case Temperature (TC) - C
Figure AN1002.4
Typical DC Gate Trigger Current versus Case Temperature
For applications where low temperatures are expected, gate current supply should be increased to at least two to eight times the gate trigger current requirements at 25 C. The actual factor varies by thyristor type and the environmental temperature. Example of a 10 A triac: If I GT(I) = 10 mA at 25 C, then IGT(I) = 20 mA at -40 C In applications where high di/dt, high surge, and fast turn-on are expected, gate drive current should be steep rising (1 s rise time) and at least twice rated IGT or higher with minimum 3 s pulse duration. However, if gate drive current magnitude is very high, then duration may have to be limited to keep from overstressing (exceeding the power dissipation limit of) gate junction.
MT2
(-)
+
MT2
IGT GATE MT1
(+)
IGT GATE MT1
IGT
(-)
REF MT2 IGT GATE MT1 REF
QII QI QIII QIV
(+)
REF
+
MT2 IGT GATE MT1 REF
IGT
Latching Current of SCRs and Triacs
Latching current (IL) is the minimum principal current required to maintain the thyristor in the on state immediately after the switching from off state to on state has occurred and the triggering signal has been removed. Latching current can best be understood by relating to the "pick-up" or "pull-in" level of a mechanical relay. Figure AN1002.5 and Figure AN1002.6 illustrate typical thyristor latching phenomenon. In the illustrations in Figure AN1002.5, the thyristor does not stay on after gate drive is removed due to insufficient available principal current (which is lower than the latching current requirement).
Gate Pulse (Gate Drive to Thyristor)
MT2 NEGATIVE (Negative Half Cycle)
-
NOTE: Alternistors will not operate in Q IV
Figure AN1002.3
Definition of Operating Quadrants in Triacs
The following table shows the relationships between different gating modes in current required to gate on triacs.
Typical Ratio of
I GT ( In given Quadrant ) ---------------------------------------------------------------------------I GT ( Quadrant 1 )
at 25 C
Operating Mode Type 4 A Triac 10 A Triac
Quadrant I 1 1 Quadrant II 1.6 1.5 Quadrant III 2.5 1.4 Quadrant IV 2.7 3.1
Latching Current Requirement
Time
Example of 4 A triac: If IGT(I) = 10 mA, then IGT(II) = 16 mA IGT(III) = 25 mA IGT(IV) = 27 mA Gate trigger current is temperature-dependent as shown in Figure AN1002.4. Thyristors become less sensitive with decreasing temperature and more sensitive with increasing temperature.
Principal Current Through Thyristor
Zero Crossing Point Time
Figure AN1002.5
Latching Characteristic of Thyristor (Device Not Latched)
In the illustration in Figure AN1002.6 the device stays on for the remainder of the half cycle until the principal current falls below the holding current level. Figure AN1002.5 shows the characteristics of the same device if gate drive is removed or shortened before latching current requirement has been met.
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Application Notes
AN1002
Gate Drive to Thyristor
Gate Pulse
Holding current modes of the thyristor are strictly related to the voltage polarity across the main terminals. The following table illustrates how the positive and negative holding current modes of triacs relate to each other.
Time
Typical Triac Holding Current Ratio Operating Mode
Latching Current Point Principal Current Through Thyristor Holding Current Point Zero Crossing Point
Type 4 A Triac 10 A Triac
IH(+) 1 1
IH(-) 1.1 1.3
Time
Figure AN1002.6 Latching and Holding Characteristics of Thyristor
Example of a 10 A triac: If I H(+) = 10 mA, then IH(-) = 13 mA Holding current is also temperature-dependent like gating and latching shown in Figure AN1002.7. The initial on-state current is 200 mA to ensure that the thyristor is fully latched on prior to holding current measurement. Again, applications with low temperature requirements should have sufficient principal (anode) current available to maintain the thyristor in the on-state condition. Both minimum and maximum holding current specifications may be important, depending on application. Maximum holding current must be considered if the thyristor is to stay in conduction at low principal (anode) current; the minimum holding current must be considered if the device is expected to turn off at a low principal (anode) current.
2.0
Similar to gating, latching current requirements for triacs are different for each operating mode (quadrant). Definitions of latching modes (quadrants) are the same as gating modes. Therefore, definitions shown in Figure AN1002.2 and Figure AN1002.3 can be used to describe latching modes (quadrants) as well. The following table shows how different latching modes (quadrants) relate to each other. As previously stated, Quadrant II has the lowest latching current sensitivity of all four operating quadrants.
I ( In given Quadrant ) L Typical Ratio of ------------------------------------------------------------------------ at 25 C I ( Quadrant 1 )
L
Operating Mode Type 4 A Triac 10 A Triac
Quadrant I 1 1 Quadrant II 4 4 Quadrant III 1.2 1.1 Quadrant IV 1.1 1
Latching current has even somewhat greater temperature dependence compared to the DC gate trigger current. Applications with low temperature requirements should have sufficient principal current (anode current) available to ensure thyristor latch-on. Two key test conditions on latching current specifications are gate drive and available principal (anode) current durations. Shortening the gate drive duration can result in higher latching current values.
Ratio of
If IL(I) = 10 mA, then IL(II) = 40 mA IL(III) = 12 mA IL(IV) = 11 mA
IH (TC = 25 C)
Example of a 4 Amp Triac:
IH
INITIAL ON-STATE CURRENT = 200 mA dc
1.5
1.0
.5
0 -40 -15 +25 +65 +100 Case Temperature (TC) - C
Figure AN1002.7
Typical DC Holding Current vs Case Temperatures
Holding Current of SCRs and Triacs
Holding current (IH) is the minimum principal current required to maintain the thyristor in the on state. Holding current can best be understood by relating it to the "drop-out" or "must release" level of a mechanical relay. Figure AN1002.6 shows the sequences of gate, latching, and holding currents. Holding current will always be less than latching. However, the more sensitive the device, the closer the holding current value approaches its latching current value. Holding current is independent of gating and latching, but the device must be fully latched on before a holding current limit can be determined.
Example of a 10 A triac: If I H(+) = 10 mA at 25 C, then IH(+) 7.5 mA at 65 C
Relationship of Gating, Latching, and Holding Currents
Although gating, latching, and holding currents are independent of each other in some ways, the parameter values are related. If gating is very sensitive, latching and holding will also be very sensitive and vice versa. One way to obtain a sensitive gate and not-so-sensitive latching-holding characteristic is to have an "amplified gate" as shown in Figure AN1002.8.
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Application Notes
The following table and Figure AN1002.9 show the relationship of gating, latching, and holding of a 4 A device.
*
A
Sensitive SCR
A
Power SCR
Typical 4 A Triac Gating, Latching, and Holding Relationship Quadrants or Operating Mode Parameter IGT (mA) IL (mA) IH (mA)
Quadrant I 10 12 10 Quadrant II 17 48 10 Quadrant III 18 12 12 Quadrant IV 27 13 12
G
K G
K
*
MT2
Sensitive Triac
MT2
Power Triac
G
MT1 G
MT1
*
Resistor is provided for limiting gate current (IGTM) peaks to power device.
Figure AN1002.8
"Amplified Gate" Thyristor Circuit
(mA) IH(+) QUADRANT II 20 QUADRANT I IGT (Solid Line) IL (Dotted Line) (mA) 50 40 30 20 10 0 10 10 20 30 40
10
QUADRANT III
Figure AN1002.9
20
IH(-)
QUADRANT IV
Typical Gating, Latching, and Holding Relationships of 4 A Triac at 25 C
The relationships of gating, latching, and holding for several device types are shown in the following table. For convenience all ratios are referenced to Quadrant I gating.
Typical Ratio of Gating, Latching, and Holding Currents at 25 C Ratio
I GT ( II ) ----------------I GT ( I ) 1.6 1.5 1.5 - - I GT ( III ) ------------------I GT ( I ) 2.5 1.4 1.8 - - I GT ( IV ) -------------------I GT ( I ) 2.7 3.1 - - - IL ( I ) --------------I GT ( I ) 1.2 1.6 2.4 25 3.2 I L ( II ) --------------I GT ( I ) 4.8 4.0 7.0 - - I L ( III ) --------------I GT ( I ) 1.2 1.8 2.1 - - I L ( IV ) --------------I GT ( I ) 1.3 2.0 - - - IH ( + ) --------------I GT ( I ) 1.0 1.1 2.2 25 2.6 I H (-) --------------I GT ( I ) 1.2 1.6 1.9 - -
Devices 4 A Triac 10 A Triac 15 A Alternistor 1 A Sensitive SCR 6 A SCR
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AN1002
Examples of a 10 A triac: If IGT(I) = 10 mA, then IGT(II) = 15 mA IGT(III) = 14 mA IGT(IV) = 31 mA If IL(I) = 16 mA, then IL(II) = 40 mA IL(III) = 18 mA IL(IV) = 20 mA If IH(+) = 11 mA at 25 C, then IH(+) = 16 mA
Summary
Gating, latching, and holding current characteristics of thyristors are quite important yet predictable (once a single parameter value is known). Their interrelationships (ratios) can also be used to help designers in both initial circuit application design as well as device selection.
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Notes
AN1003
AN10039
Phase Control Using Thyristors
Introduction
Due to high-volume production techniques, thyristors are now priced so that almost any electrical product can benefit from electronic control. A look at the fundamentals of SCR and triac phase controls shows how this is possible. It is important to note that the circuit current is determined by the load and power source. For simplification, assume the load is resistive; that is, both the voltage and current waveforms are identical.
Full-wave Rectified Operation Voltage Applied to Load
Output Power Characteristics
Phase control is the most common form of thyristor power control. The thyristor is held in the off condition -- that is, all current flow in the circuit is blocked by the thyristor except a minute leakage current. Then the thyristor is triggered into an "on" condition by the control circuitry. For full-wave AC control, a single triac or two SCRs connected in inverse parallel may be used. One of two methods may be used for full-wave DC control -- a bridge rectifier formed by two SCRs or an SCR placed in series with a diode bridge as shown in Figure AN1003.1.
Delay (Triggering) Angle Conduction Angle
Figure AN1003.2
Sine Wave Showing Principles of Phase Control
Different loads respond to different characteristics of the AC waveform. For example, some are sensitive to average voltage, some to RMS voltage, and others to peak voltage. Various voltage characteristics are plotted against conduction angle for half- and full-wave phase control circuits in Figure AN1003.3 and Figure AN1003.4.
Control Circuit
Control Circuit
Line
Load
Line
Load
Two SCR AC Control
Triac AC Control
Line
Line
Control Circuit
Control Circuit
Load
Load
One SCR DC Control
Figure AN1003.1
Two SCR DC Control
SCR/Triac Connections for Various Methods of Phase Control
Figure AN1003.2 illustrates voltage waveform and shows common terms used to describe thyristor operation. Delay angle is the time during which the thyristor blocks the line voltage. The conduction angle is the time during which the thyristor is on.
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AN1003
Application Notes
phase angle. Thus, a 180 conduction angle in a half-wave circuit provides 0.5 x full-wave conduction power. In a full-wave circuit, a conduction angle of 150 provides 97% full power while a conduction angle of 30 provides only 3% of full power control. Therefore, it is usually pointless to obtain conduction angles less than 30 or greater than 150. Figure AN1003.5 and Figure AN1003.6 give convenient direct output voltage readings for 115 V/230 V input voltage. These curves also apply to current in a resistive circuit.
HALF WAVE 1.8 1.6 Normalized Sine Wave RMS Voltage Power as Fraction of Full Conduction Peak Voltage 1.4 1.2 1.0
RMS 0.8 Power 0.6 0.4 0.2 AVG 0 0 20 40 60 80 100 120 140 160 180 Conduction Angle ()
Input Voltage 230 V 115 V 360 180 320 160
HALF WAVE
Peak Voltage 280 140 240 120
Output Voltage
200 100 RMS 160 120 80 60 40 AVG 40 20 0
Figure AN1003.3
Half-Wave Phase Control (Sinusoidal)
80
FULL WAVE
0
Figure AN1003.5
0
20
40
60
80
100 120 140 160 180
Conduction Angle ()
1.8 1.6 Peak Voltage
Normal Sine Wave RMS Voltage Power as Fraction of Full Conduction
Output Voltage of Half-wave Phase
1.4 1.2 RMS 1.0 Power 0.8 0.6 0.4 AVG 0.2 0 0 20 40 60 80 100 120 140 160 180 Conduction Angle ()
80 40 20 0 0 20 40 60 80 320 160 Peak Voltage 280 140 240 120
Output Voltage
Input Voltage 230 V 115 V 360 180
FULL WAVE
RMS 200 100 160 120 80 AVG 60
Figure AN1003.4
Symmetrical Full-Wave Phase Control (Sinusoidal)
40 0
Figure AN1003.3 and Figure AN1003.4 also show the relative power curve for constant impedance loads such as heaters. Because the relative impedance of incandescent lamps and motors change with applied voltage, they do not follow this curve precisely. To use the curves, find the full-wave rated power of the load, and then multiply by the ratio associated with the specific
100 120 140 160 180
Conduction Angle ()
Figure AN1003.6
Output Voltage of Full-wave Phase Control
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Application Notes
AN1003
Control Characteristics
A relaxation oscillator is the simplest and most common control circuit for phase control. Figure AN1003.7 illustrates this circuit as it would be used with a thyristor. Turn-on of the thyristor occurs when the capacitor is charged through the resistor from a voltage or current source until the breakover voltage of the switching device is reached. Then, the switching device changes to its on state, and the capacitor is discharged through the thyristor gate. Trigger devices used are neon bulbs, unijunction transistors, and three-, four-, or five-layer semiconductor trigger devices. Phase control of the output waveform is obtained by varying the RC time constant of the charging circuit so the trigger device breakdown occurs at different phase angles within the controlled half or full cycle.
Upon final selection of the capacitor, the curve shown in Figure AN1003.8 can be used in determining the charging resistance needed to obtain the desired control characteristics. Many circuits begin each half-cycle with the capacitor voltage at or near zero. However, most circuits leave a relatively large residual voltage on the capacitor after discharge. Therefore, the charging resistor must be determined on the basis of additional charge necessary to raise the capacitor to trigger potential. For example, assume that we want to trigger an S2010L SCR with a 32 V trigger diac. A 0.1 F capacitor will supply the necessary SCR gate current with the trigger diac. Assume a 50 V dc power supply, 30 minimum conduction angle, and 150 maximum conduction angle with a 60 Hz input power source. At approximately 32 V, the diac triggers leaving 0.66 VBO of diac voltage on the capacitor. In order for diac to trigger, 22 V must be added to the capacitor potential, and 40 V additional (50-10) are available. The capacitor must be charged to 22/40 or 0.55 of the available charging voltage in the desired time. Looking at Figure AN1003.8, 0.55 of charging voltage represents 0.8 time constant. The 30 conduction angle required that the firing pulse be delayed 150 or 6.92 ms. (The period of 1/2 cycle at 60 Hz is 8.33 ms.) To obtain this time delay: 6.92 ms = 0.8 RC RC = 8.68 ms if C = 0.10 F
R
Switching Device
Voltage or Current Source
SCR Triac C
Figure AN1003.7
Relaxation Oscillator Thyristor Trigger Circuit
Figure AN1003.8 shows the capacitor voltage-time characteristic if the relaxation oscillator is to be operated from a pure DC source.
then,
R = ------------------------- = 86,000 -
8.68 x10 0.1 x10
-3
-6
To obtain the minimum R (150 conduction angle), the delay is 30 or (30/180) x 8.33 = 1.39 ms 1.39 ms = 0.8 RC RC = 1.74 ms 1.74 x10 R = -------------------------- = 17,400 -6 0.1 x10 Using practical values, a 100 k potentiometer with up to 17 k minimum (residual) resistance should be used. Similar calculations using conduction angles between the maximum and minimum values will give control resistance versus power characteristic of this circuit.
-3
1.0 0.9
)
Capacitor Voltage Supply Source Voltage
0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 0 1 2 3 4 5 6 Time Constants
(
Ratio of
Triac Phase Control
The basic full-wave triac phase control circuit shown in Figure AN1003.9 requires only four components. Adjustable resistor R1 and C 1 are a single-element phase-shift network. When the voltage across C1 reaches breakover voltage (V BO) of the diac, C1 is partially discharged by the diac into the triac gate. The triac is then triggered into the conduction mode for the remainder of that half-cycle. In this circuit, triggering is in Quadrants I and III. The unique simplicity of this circuit makes it suitable for applications with small control range.
Figure AN1003.8
Capacitor Charging from DC Source
Usually, the design starting point is the selection of a capacitance value which will reliably trigger the thyristor when the capacitance is discharged. Trigger devices and thyristor gate triggering characteristics play a part in the selection. All the device characteristics are not always completely specified in applications, so experimental determination is sometimes needed.
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AN1003
Application Notes
Load R1 R2 250 k 3.3 k (For Inductive Loads) C1 0.1 F Diac HT34B 0.1 F Triac (Q2010L5) 100 120 V (60 Hz)
Load R4 R2 120 V (60 Hz) C2 0.1 F 68 k R3 100 k Trim R1 250 k 3.3 k Triac (Q2010L5)
C1 0.1 F
Diac HT34B
Figure AN1003.9
Basic Diac-Triac Phase Control
The hysteresis (snap back) effect is somewhat similar to the action of a kerosene lantern. That is, when the control knob is first rotated from the off condition, the lamp can be lit only at some intermediate level of brightness, similar to turning up the wick to light the lantern. Brightness can then be turned down until it finally reaches the extinguishing point. If this occurs, the lamp can only be relit by turning up the control knob again to the intermediate level. Figure AN1003.10 illustrates the hysteresis effect in capacitor-diac triggering. As R1 is brought down from its maximum resistance, the voltage across the capacitor increases until the diac first fires at point A, at the end of a half-cycle (conduction angle i). After the gate pulse, however, the capacitor voltage drops suddenly to about half the triggering voltage, giving the capacitor a different initial condition. The capacitor charges to the diac, triggering voltage at point B in the next half-cycle and giving a steady-state conduction angle shown as for the triac.
Figure AN1003.11
Extended Range Full-wave Phase Control
By using one of the circuits shown in Figure AN1003.12, the hysteresis effect can be eliminated entirely. The circuit (a) resets the timing capacitor to the same level after each positive half-cycle, providing a uniform initial condition for the timing capacitor. This circuit is useful only for resistive loads since the firing angle is not symmetrical throughout the range. If symmetrical firing is required, use the circuit (b) shown in Figure AN1003.12.
Load
(a)
120 V (60 Hz)
R2
R3 15 k 1/2 W D1 R1
3.3 k
Triac (Q2010L5)
250 k
D2
C1 0.1 F
Diac
D1, D2 = 200 V Diodes
AC Line Diac Triggers at "A"
(b)
[+Diac VBO]
Load R2 120 V (60 Hz)
[-Diac VBO]
R4 R3 R1 D1 D3 D4
Triac (Q2010L5)
A B Diac Does Not Trigger at "A"
Capacitor Voltage
i
D2
C1 0.1 F
Diac
Figure AN1003.10
Relationship of AC Line Voltage and Triggering Voltage
R1 = 250 k POT R2, R3 = 15 k, 1/2 W
R4 = 3.3 k D1, D2, D3, D4 = 200 V Diodes
Figure AN1003.12
Wide-range Hysteresis Free Phase Control
In the Figure AN1003.11 illustration, the addition of a second RC phase-shift network extends the range on control and reduces the hysteresis effect to a negligible region. This circuit will control from 5% to 95% of full load power, but is subject to supply voltage variations. When R1 is large, C1 is charged primarily through R3 from the phase-shifted voltage appearing across C2. This action provides additional range of phase-shift across C1 and enables C2 to partially recharge C1 after the diac has triggered, thus reducing hysteresis. R3 should be adjusted so that the circuit just drops out of conduction when R1 is brought to maximum resistance.
For more complex control functions, particularly closed loop controls, the unijunction transistor may be used for the triggering device in a ramp and pedestal type of firing circuit as shown in Figure AN1003.13.
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Application Notes
AN1003
Ramp UJT Triggering Level Cool Pedestal UJT Emitter Voltage Hot 0 Time
L1 Load C1 R2 3.3 k R3 * 100 AC Input R1 D1 C2
R8 Q1 Q2 Triac
Load
Q1
D1 R1
D2
R2
R6
"Gain"
0.1 F 100 V
HT-32
C3 *
R3 120 V (60 Hz) D3 D4 D5 R5 Temp R4 T
R7 D6 C1 T1
Note: L1 and C1 form an RFI filter that may be eliminated
* dv/dt snubber network when required
AC Input Voltage
120 V ac 60 Hz 240 V ac 50/60 Hz
AC Load Current
12 A
R1 250 k
C1, C3 0.1 F 200 V
L1 100 H
Q1 Q2015L9
R1, R2 = 2.2 k, 2 W R3 = 2.2 k, 1/2 W R4 = Thermistor, approx. 5 k at operating temperature R5 = 10 k Potentiometer R6 = 5 M Potentiometer R7 = 100 k, 1/2 W R8 = 1 k, 1/2 W
Q1 = 2N2646 Q2 = Q2010L5 T1 = Dale PT 10-101 or equivalent D1-4 = 200 V Diode D5 = 20 V Zener D6 = 100 V Diode C1 = 0.1 F, 30 V
3A
500 k
0.1 F 400 V
200 H
Q4004L4
Figure AN1003.14
Figure AN1003.13
Precision Proportional Temperature Control
Single-time-constant Circuit for Incandescent Light Dimming, Heat Control, and Motor Speed Control
Several speed control and light dimming (phase) control circuits have been presented that give details for a complete 120 V application circuit but none for 240 V. Figure AN1003.14 and Figure AN1003.15 show some standard phase control circuits for 240 V, 60 Hz/50 Hz operation along with 120 V values for comparison. Even though there is very little difference, there are a few key things that must be remembered. First, capacitors and triacs connected across the 240 V line must be rated at 400 V. Secondly, the potentiometer (variable resistor) value must change considerably to obtain the proper timing or triggering for 180 in each halfcycle. Figure AN1003.14 shows a simple single-time-constant light dimmer (phase control) circuit, giving values for both 120 V and 240 V operation.
The circuit shown in Figure AN1003.15 is a double-time-constant circuit which has improved performance compared to the circuit shown in Figure AN1003.14. This circuit uses an additional RC network to extend the phase angle so that the triac can be triggered at small conduction angles. The additional RC network also minimizes any hysteresis effect explained and illustrated in Figure AN1003.10 and Figure AN1003.11.
L1 Load R1 3.3 k AC Input C1 Q1 R2 R3 15 k 1/2 W C3 0.1 F 100 V Note: L1 and C1 form an RFI filter that may be eliminated D1 R4 * 100
C2
HT-32
C4 *
* dv/dt snubber network when required
AC Input Voltage 120 V ac 60 Hz 240 V ac 50 Hz 240 V ac 60 Hz
AC Load Current 8A
R2 250 k
C1, C2, C4 0.1 F 200 V
L1 100 H
Q1 Q2010L5
6A
500 k
0.1 F 400 V
200 H
Q4008L4
6A
500 k
0.1 F 400 V
200 H
Q4008L4
Figure AN1003.15
Double-time-constant Circuit for Incandescent Light Dimming, Heat Control, and Motor Speed Control
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Application Notes
Permanent Magnet Motor Control
Figure AN1003.16 illustrates a circuit for phase controlling a permanent magnet (PM) motor. Since PM motors are also generators, they have characteristics that make them difficult for a standard triac to commutate properly. Control of a PM motor is easily accomplished by using an alternistor triac with enhanced commutating characteristics.
Load R1 SCR1 AC Input CR1 R2 2.2 k
+
DC MTR
R3
1.5 A 3.3 k Q4006LH4 250 k 100 MT2
AC Input Voltage AC Load Current
-
R2 500 k
CR1 IN4003
SCR1 EC103B
R3 1k Not Required 1k
115 V ac Input
15 k 1/2 W
G HT-32
MT1 0.1 F 400 V
120 V ac 60 Hz 120 V ac 60 Hz 240 V ac 60 Hz 240 V ac 60 Hz 240 V ac 50Hz
0.8 A
8.5 A
100 k
IN4003
S2010F1
0.1 F 400 V
0.1 F 100 V
0.8 A
1M
IN4004
EC103D Not Required 1k
Figure AN1003.16
Circuit for Phase Controlling a Permanent Magnet Motor
8.5 A
250 k 1M
IN4004
S4010F1
PM motors normally require full-wave DC rectification. Therefore, the alternistor triac controller should be connected in series with the AC input side of the rectifier bridge. The possible alternative of putting an SCR controller in series with the motor on the DC side of the rectifier bridge can be a challenge when it comes to timing and delayed turn-on near the end of the half cycle. The alternistor triac controller shown in Figure AN1003.16 offers a wide range control so that the alternistror triac can be triggered at a small conduction angle or low motor speed; the rectifiers and alternistors should have similar voltage ratings, with all based on line voltage and actual motor load requirements.
2.5 A
IN4004
T106D1
Figure AN1003.17
Half-wave Control, 0 to 90 Conduction
Figure AN1003.18 shows a half-wave phase control circuit using an SCR to control a universal motor. This circuit is better than simple resistance firing circuits because the phase-shifting characteristics of the RC network permit the firing of the SCR beyond the peak of the impressed voltage, resulting in small conduction angles and very slow speed.
Universal Motor M R1 3.3 k D1 AC Supply R2
SCR Phase Control
Figure AN1003.17 shows a very simple variable resistance halfwave circuit. It provides phase retard from essentially zero (SCR full on) to 90 electrical degrees of the anode voltage wave (SCR half on). Diode CR 1 blocks reverse gate voltage on the negative half-cycle of anode supply voltage. This protects the reverse gate junction of sensitive SCRs and keeps power dissipation low for gate resistors on the negative half cycle. The diode is rated to block at least the peak value of the AC supply voltage. The retard angle cannot be extended beyond the 90-degree point because the trigger circuit supply voltage and the trigger voltage producing the gate current to fire are in phase. At the peak of the AC supply voltage, the SCR can still be triggered with the maximum value of resistance between anode and gate. Since the SCR will trigger and latch into conduction the first time IGT is reached, its
conduction cannot be delayed beyond 90 electrical degrees with this circuit.
SCR1
CR1
HT-32
C1
AC Input Voltage
AC Load Current
R2 150 k
CR1 IN4003
SCR1 S2015L
C1 0.1F 200 V
120 V ac 60 Hz 240 V ac 60 Hz 240 V ac 50 Hz
8A
6.5 A
200 k
IN4004
S4008L
0.1F 400 V
6.5 A
200 k
IN4004
S4008L
0.1F 400 V
Figure AN1003.18
Half-wave Motor Control
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Application Notes
AN1003
Phase Control from Logic (DC) Inputs
Triacs can also be phase-controlled from pulsed DC unidirectional inputs such as those produced by a digital logic control system. Therefore, a microprocessor can be interfaced to AC load by using a sensitive gate triac to control a lamp's intensity or a motor's speed. There are two ways to interface the unidirectional logic pulse to control a triac. Figure AN1003.19 illustrates one easy way if load current is approximately 5 A or less. The sensitive gate triac serves as a direct power switch controlled by HTL, TTL, CMOS, or integrated circuit operational amplifier. A timed pulse from the system's logic can activate the triac anywhere in the AC sinewave producing a phase-controlled load.
For a circuit to control a heavy-duty inductive load where an alternistor is not compatible or available, two SCRs can be driven by an inexpensive TO-92 triac to make a very high current triac or alternistor equivalent, as shown in Figure AN1003.21. See "Relationship of IAV, IRMS, and IPK' in AN1009 for design calculations.
Hot Load MT2 Triac A K K G A Non-sensitive Gate SCRs Gate Pulse Input
G MT1
G
OR
VDD = 15 VDC VDD OV 16 G 8
MT2
Load
Hot Neutral
Sensitive Gate Triac MT1
Figure AN1003.21
120 V 60 Hz
Triac Driving Two Inverse Parallel Non-Sensitive Gate SCRs
Neutral
Figure AN1003.19
Sensitive Gate Triac Operating in Quadrants I and IV
Figure AN1003.22 shows another way to interface a unidirectional pulse signal and activate AC loads at various points in the AC sine wave. This circuit has an electrically-isolated input which allows load placement to be flexible with respect to AC line. In other words, connection between DC ground and AC neutral is not required.
The key to DC pulse control is correct grounding for DC and AC supply. As shown in Figure AN1003.19, DC ground and AC ground/neutral must be common plus MT1 must be connected to common ground. MT1 of the triac is the return for both main terminal junctions as well as the gate junction. Figure AN1003.20 shows an example of a unidirectional (all negative) pulse furnished from a special I.C. that is available from LSI Computer Systems in Melville, New York. Even though the circuit and load is shown to control a Halogen lamp, it could be applied to a common incandescent lamp for touch-controlled dimming.
Rin Timed Input Pulse
1 2
6
100 0.1 F 250 V
100 C1 G
Load MT2 120 V 60 Hz
Hot
4
MT1
Triac or Alternistor
Neutral Load could be here instead of upper location
Figure AN1003.22
Opto-isolator Driving a Triac or Alternistor
Microcontroller Phase Control
L R3 G MT1 T MT2 115 V ac 220 V ac C1 C2 R1 N R2 NOTE: As a precaution, transformer should have thermal protection. Halogen Lamp 115 V ac C1 = 0.15 F, 200 V C2 = 0.22 F, 200 V C3 = 0.02 F, 12 V C4 = 0.002 F, 12 V C5 = 100 F, 12 V R1 = 270, 1/4 W R2 = 680 k, 1/4 W R3 = 62, 1/4 W R4 = 1 M to 5 M, 1/4 W (Selected for sensitivity) R5, R6 = 4.7 M, 1/4 W D1 = 1N4148 Z = 5.6 V, 1 W Zener T = Q4006LH4 Alternistor L = 100 H (RFI Filter) 220 V ac C1 = 0.15 F, 400 V C2 = 0.1 F, 400 V C3 = 0.02 F, 12 V C4 = 0.002 F, 12 V C5 = 100 F, 12 V R1 = 1 k, 1/4 W R2 = 1.5 M, 1/4 W R3 = 62, 1/4 W R4 = 1 M to 5 M, 1/4 W (Selected for sensitivity) R5, R6 = 4.7 M, 1/4 W D1 = 1N4148 Z = 5.6 V, 1 W Zener T = Q6006LH4 Alternistor L = 200 H (RFI Filter) 1 D1 8 7 6
EXT
+ Z
C5
L
R5 5
SENS TRIG VSS
R6
Touch Plate
Traditionally, microcontrollers were too large and expensive to be used in small consumer applications such as a light dimmer. Microchip Technology Inc. of Chandler, Arizona has developed a line of 8-pin microcontrollers without sacrificing the functionality of their larger counterparts. These devices do not provide high drive outputs, but when combined with a sensitive triac can be used in a cost-effective light dimmer. Figure AN1003.23 illustrates a simple circuit using a transformerless power supply, PIC 12C508 microcontroller, and a sensitive triac configured to provide a light dimmer control. R 3 is connected to the hot lead of the AC power line and to pin GP 4. The ESD protection diodes of the input structure allow this connection without damage. When the voltage on the AC power line is positive, the protection diode form the input to V DD is forward biased, and the input buffer will see approximately VDD + 0.7 V. The software will read this pin as high. When the voltage on the line is negative, the protection diode from VSS to the input pin is forward biased, and the input buffer sees approximately VSS - 0.7 V. The software will read the pin as low. By polling GP 4 for a change in state, the software can detect zero crossing.
LS7631 / LS7632
VDD MODE CAP SYNC
2
3 C3
4 C4
R4
Figure AN1003.20
Typical Touch Plate Halogen Lamp Dimmer
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AN1003
Application Notes
120 V ac (High)
R1 47
C3 0.1 F
D1 1N4001
VDD
RV1 Varistor AC (Return) White 150 W Lamp +5 V
R2 1M
D1 1N4001
D3 1N5231
C1 220 F
C2 0.01 F
U1 VDD VSS GP0 GP1 GP2 12C508 R6 470 Q1 L4008L5
R3 20 M
GP5 GP4 GP3
Remote Switch Connector JP1 3 2 1 Bright S2 Dim S1
R4 470
R5 470
Figure AN1003.23
Microcontroller Light Dimmer Control
With a zero crossing state detected, software can be written to turn on the triac by going from tri-state to a logic high on the gate and be synchronized with the AC phase cycles (Quadrants I and IV). Using pull-down switches connected to the microcontoller inputs, the user can signal the software to adjust the duty cycle of the triac. For higher amperage loads, a small 0.8 A, TO-92 triac (operating in Quadrants I and IV) can be used to drive a 25 A alternistor triac (operating in Quadrants I and III) as shown in the heater control illustration in Figure AN1003.24. For a complete listing of the software used to control this circuit, see the Microchip application note PICREF-4. This application note can be downloaded from Microchip's Web site at www.microchip.com.
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Application Notes
AN1003
120VAC (HIGH)
R1 47
C3 .1F
D1 1N4001
VDD
RV1 VARISTOR
R2 1M
D1 1N4001
D3 1N5231
C1 220F
C2 .01F
AC (RETURN) WHITE 2000 W +5V VDD U1 VSS Q1 L4X8E5 R6 470 R70 100 Q2 Q4025L6
R3 20M
GP5
GP0
GP4
GP1
GP3 12C508
GP2
DECREASE HEAT S1
R4 470
S2
R5 470
INCREASE HEAT
Figure AN1003.24
Microcontroller Heater Control
Summary
The load currents chosen for the examples in this application note were strictly arbitrary, and the component values will be the same regardless of load current except for the power triac or SCR. The voltage rating of the power thyristor devices must be a minimum of 200 V for 120 V input voltage and 400 V for 240 V input voltage. The use of alternistors instead of triacs may be much more acceptable in higher current applications and may eliminate the need for any dv/dt snubber network. For many electrical products in the consumer market, competitive thyristor prices and simplified circuits make automatic control a possibility. These simple circuits give the designer a good feel for the nature of thyristor circuits and their design. More sophistication, such as speed and temperature feedback, can be developed as the control techniques become more familiar. A remarkable phenomenon is the degree of control obtainable with very simple circuits using thyristors. As a result, industrial and consumer products will greatly benefit both in usability and marketability.
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Notes
AN1004
4
Mounting and Handling of Semiconductor Devices
These are suitable only for vibration-free environments and lowpower, free-air applications. For best results, the device should be in a vertical position for maximum heat dissipation from convection currents.
Introduction
Proper mounting and handling of semiconductor devices, particularly those used in power applications, is an important, yet sometimes overlooked, consideration in the assembly of electronic systems. Power devices need adequate heat dissipation to increase operating life and reliability and allow the device to operate within manufacturers' specifications. Also, in order to avoid damage to the semiconductor chip or internal assembly, the devices should not be abused during assembly. Very often, device failures can be attributed directly to a heat sinking or assembly damage problem. The information in this application note guides the semiconductor user in the proper use of Teccor devices, particularly the popular and versatile TO-220 and TO-202 epoxy packages. Contact the Teccor Applications Engineering Group for further details or suggestions on use of Teccor devices.
Standard Lead Forms
Teccor encourages users to allow factory production of all lead and tab form options. Teccor has the automated machinery and expertise to produce pre-formed parts at minimum risk to the device and with greater convenience for the consumer. See the "Lead Form Dimensions" section of this catalog for a complete list of readily available lead form options. Contact Teccor for information regarding custom lead form designs.
Lead Bending Method
Leads may be bent easily and to any desired angle, provided that the bend is made at a minimum 0.063" (0.1" for TO-218 package) away from the package body with a minimum radius of 0.032" (0.040" for TO-218 package) or 1.5 times lead thickness rule. DO-15X device leads may be bent with a minimum radius of 0.050", and DO-35 device leads may be bent with a minimum radius of 0.028". Leads should be held firmly between the package body and the bend so that strain on the leads is not transmitted to the package body, as shown in Figure AN1004.2. Also, leads should be held firmly when trimming length.
Lead Forming -- Typical Configurations
A variety of mounting configurations are possible with Teccor power semiconductor TO-202, TO-92, DO-15X, and TO-220 packages, depending upon such factors as power requirements, heat sinking, available space, and cost considerations. Figure AN1004.1 shows typical examples and basic design rules.
A
B
C
SOCKET TYPE MOUNTING: D
Useful in applications for testing or where frequent removal is necessary. Excellent selection of socket products available from companies such as Molex.
Figure AN1004.1
Component Mounting
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Application Notes
Figure AN1004.4 through Figure AN1004.6 show additional examples of acceptable heat sinks.
Incorrect
(A)
Correct
Figure AN1004.4
Examples of PC Board Mounts
Heat Sink
(B)
Figure AN1004.2
Lead Bending Method
A
Printed Circuit Board B
When bending leads in the plane of the leads (spreading), bend only the narrow part. Sharp angle bends should be done only once as repetitive bending will fatigue and break the leads. The mounting tab of the TO-202 package may also be bent or formed into any convenient shape as long as it is held firmly between the plastic case and the area to be formed or bent. Without this precaution, bending the tab may fracture the chip and permanently damage the unit.
Figure AN1004.5
Vertical Mount Heat Sink
Several types of vertical mount heat sinks are available. Keep heat sink vertical for maximum convection.
Heat Sinking
Use of the largest, most efficient heat sink as is practical and cost effective extends device life and increases reliability. In the illustration shown in Figure AN1004.3, each device is electrically isolated.
Heat Sink
Figure AN1004.6 Examples of Extruded Aluminum
When coupled with fans, extruded aluminum mounts have the highest efficiency.
Heat Sinking Notes
Figure AN1004.3 Several Isolated TO-220 Devices Mounted to a Common Heat Sink
Care should be taken not to mount heat sinks near other heatproducing elements such as power resistors, because black anodized heat sinks may absorb more heat than they dissipate. Some heat sinks can hold several power devices. Make sure that if they are in electrical contact to the heat sink, the devices do not short-circuit the desired functions. Isolate the devices electrically or move to another location. Recall that the mounting tab of Teccor isolated TO-220 devices is electrically isolated so that several devices may be mounted on the same heat sink without extra insulating components. If using an external insulator such as mica, with a thickness of 0.004", an additional thermal resistance of 0.8 C/W for TO-220 or 0.5 C/W for TO-218 devices is added to the R JC device rating.
Many power device failures are a direct result of improper heat dissipation. Heat sinks with a mating area smaller than the metal tab of the device are unacceptable. Heat sinking material should be at least 0.062" thick to be effective and efficient. Note that in all applications the maximum case temperature (TC) rating of the device must not be exceeded. Refer to the individual device data sheet rating curves (T C versus IT) as well as the individual device outline drawings for correct T C measurement point.
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Application Notes
AN1004
Allow for adequate ventilation. If possible, route heat sinks to outside of assembly for maximum airflow.
Mounting Surface Selection
Proper mounting surface selection is essential to efficient transfer of heat from the semiconductor device to the heat sink and from the heat sink to the ambient. The most popular heat sinks are flat aluminum plates or finned extruded aluminum heat sinks. The mounting surface should be clean and free from burrs or scratches. It should be flat within 0.002 inch per inch, and a surface finish of 30 to 60 microinches is acceptable. Surfaces with a higher degree of polish do not produce better thermal conductivity. Many aluminum heat sinks are black anodized to improve thermal emissivity and prevent corrosion. Anodizing results in high electrical but negligible thermal insulation. This is an excellent choice for isolated TO-220 devices. For applications of TO-202 devices where electrical connection to the common anode tab is required, the anodization should be removed. Iridite or chromate acid dip finish offers low electrical and thermal resistance. Either TO-202 or isolated TO-220 devices may be mounted directly to this surface, regardless of application. Both finishes should be cleaned prior to use to remove manufacturing oils and films. Some of the more economical heat sinks are painted black. Due to the high thermal resistance of paint, the paint should be removed in the area where the semiconductor is attached. Bare aluminum should be buffed with #000 steel wool and followed with an acetone or alcohol rinse. Immediately, thermal grease should be applied to the surface and the device mounted down to prevent dust or metal particles from lodging in the critical interface area. For good thermal contact, the use of thermal grease is essential to fill the air pockets between the semiconductor and the mounting surface. This decreases the thermal resistance by 20%. For example, a typical TO-220 with R JC of 1.2 C/W may be lowered to 1 C/W by using thermal grease. Teccor recommends Dow-Corning 340 as a proven effective thermal grease. Fibrous applicators are not recommended as they may tend to leave lint or dust in the interface area. Ensure that the grease is spread adequately across the device mounting surface, and torque down the device to specification. Contact Teccor Applications Engineering for assistance in choosing and using the proper heat sink for specific application.
* Screw head must not touch the epoxy body of the device
str es s
* Mounting screw 6-32
oid Av
ax
ial
Heatsink Lockwasher 6-32 Nut
of Boundary metal tab exposed
High potential appication using Isolated TO-220 On heavy aluminum heatsinks
Figure AN1004.7
TO-220 Mounting
Punched holes are not acceptable due to cratering around the hole which can cause the device to be pulled into the crater by the fastener or can leave a significant portion of the device out of contact with the heat sink. The first effect may cause immediate damage to the package and early failure, while the second can create higher operating temperatures which will shorten operating life. Punched holes are quite acceptable in thin metal plates where fine-edge blanking or sheared-through holes are employed. Drilled holes must have a properly prepared surface. Excessive chamfering is not acceptable as it may create a crater effect. Edges must be deburred to promote good contact and avoid puncturing isolation materials. For high-voltage applications, it is recommended that only the metal portion of the TO-220 package (as viewed from the bottom of the package) be in contact with the heat sink. This will provide maximum oversurface distance and prevent a high voltage path over the plastic case to a grounded heat sink.
TO-202
The mounting hole for the Teccor TO-202 devices should not exceed 0.112" (4/40) clearance. (Figure AN1004.8) Since tab is electrically common with anode, heat sink may or may not need to be electrically isolated from tab. If not, use 4/40 screw with lock washer and nut. Mounting torque is 6 inch-lbs.
A
B
Appropriate Screw Tab Form 4/40 Nylon Bushing Mica Insulator
Hardware And Methods
TO-220
The mounting hole for the Teccor TO-220 devices should not exceed 0.140" (6/32) clearance. (Figure AN1004.7) No insulating bushings are needed for the L Package (isolated) devices as the tab is electrically isolated from the semiconductor chip. 6/32 mounting hardware, especially round head or Fillister machine screws, is recommended and should be torqued to a value of 6 inch-lbs.
Heat Sink Heat Sink at Case Potential
Nut Compression Washer
Figure AN1004.8
TO-202 Mounting
A nylon bushing and mica insulation are required to insulate the tab in an isolated application. A compression washer is recommended to avoid damage to the bushing. Do not attempt to mount non-formed tabs to a plane surface, as the resulting strain on the case may cause it or the semiconductor chip assembly to fail. Teccor has the facilities and expertise to properly tab form TO-202 devices for the convenience of the consumer.
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Application Notes
TO-218
The mounting hole for the TO-218 device should not exceed 0.164" (8/32) clearance. Isolated versions of TO-218 do not require any insulating material since mounting tab is electrically isolated from the semiconductor chip. Round lead or Fillister machine screws are recommended. Maximum torque to be applied to mounting tab should not exceed 8 inch-lbs. The same precautions given for the TO-220 package concerning punched holes, drilled holes, and proper prepared heat sink mounting surface apply to the TO-218 package. Also for highvoltage applications, it is recommended that only the metal portion of the mounting surface of the TO-218 package be in contact with heat sink. This achieves maximum oversurface distance to prevent a high-voltage path over the device body to grounded heat sink.
the device. The curve shown in Figure AN1004.10 illustrates the effect of proper torque.
C-S C/Watt
Effect of Torque on Case to Sink Thermal Resistance Torque - inch-lbs
1/2 Rated Rated Torque Torque
Figure AN1004.10
Effect of Torque to Sink Thermal Resistance
General Mounting Notes
Care must be taken on both packages at all times to avoid strain to the tab or leads. For easy insertion of the part onto the board or heat sink, avoid axial strain on the leads. Carefully measure mounting holes for the tab and the leads, and do any forming of the tab or leads before mounting. Refer to the "Lead Form Dimensions" section of this catalog before attempting lead form operations. Rivets may be used for less demanding and more economical applications. 1/8" all-aluminum pop rivets can be used on both TO-220 and TO-202 packages. Use a 0.129"-0.133" (#30) drill for the hole and insert the rivet from the top side, as shown in Figure AN1004.9. An insertion tool, similar to a "USM" PRG 430 hand riveter, is recommended. A wide selection of grip ranges is available, depending upon the thickness of the heat sink material. Use an appropriate grip range to securely anchor the device, yet not deform the mounting tab. The recommended rivet tool has a protruding nipple that will allow easy insertion of the rivet and keep the tool clear of the plastic case of the device.
With proper care, the mounting tab of a device can be soldered to a surface. However, the heat required to accomplish this operation can damage or destroy the semiconductor chip or internal assembly. See "Surface Mount Soldering Recommendations" (AN1005) in this catalog. Spring-steel clips can be used to replace torqued hardware in assembling thyristors to heat sinks. Clips snap into heat sink slots to hold the device in place for PC board insertion. Clips are available in several sizes for various heat sink thicknesses and thyristor case styles from Aavid Thermalloy in Concord, New Hampshire. A typical heatsink is shown in Figure AN1004.11
Figure AN1004.9
Pop Riveting Technique
A Milford #511 (Milford Group, Milford, CT) semi-tubular steel rivet set into a 0.129" receiving hole with a riveting machine similar to a Milford S256 is also acceptable. Contact the rivet machine manufacturer for exact details on application and set-up for optimum results. Pneumatic or other impact riveting devices are not recommended due to the shock they may apply to the device. Under no circumstance should any tool or hardware come into contact with the case. The case should not be used as a brace for any rotation or shearing force during mounting or in use. Nonstandard size screws, nuts, and rivets are easily obtainable to avoid clearance problems. Always use an accurate torque wrench to mount devices. No gain is achieved by overtorquing devices. In fact, overtorquing may cause the tab and case to deform or rupture, seriously damaging
Figure AN1004.11
Typical Heat Sink Using Clips
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Application Notes
AN1004
Soldering Of Leads
A prime consideration in soldering leads is the soldering of device leads into PC boards, heat sinks, and so on. Significant damage can be done to the device through improper soldering. In any soldering process, do not exceed the data sheet lead solder temperature of +230 C for 10 seconds, maximum, 1/16" from the case. This application note presents details about the following three types of soldering: * * * Hand soldering Wave soldering Dip soldering
Use a clean pre-tinned iron, and solder the joint as quickly as possible. Avoid overheating the joint or bringing the iron or solder into contact with other leads that are not heat sinked.
Wave Solder
Wave soldering is one of the most efficient methods of soldering large numbers of PC boards quickly and effectively. Guidelines for soldering by this method are supplied by equipment manufacturers. The boards should be pre-heated to avoid thermal shock to semiconductor components, and the time-temperature cycle in the solder wave should be regulated to avoid heating the device beyond the recommended temperature rating. A mildly activated resin flux is recommended. Figure AN1004.12 shows typical heat and time conditions.
Hand Soldering
This method is mostly used in prototype breadboarding applications and production of small modules. It has the greatest potential for misuse. The following recommendations apply to Teccor TO-92, TO-202, TO-220, and TO-218 packages. Select a small- to medium-duty electric soldering iron of 25 W to 45 W designed for electrical assembly application. Tip temperature should be rated from 600 F to 800 F (300 C to 425 C). The iron should have sufficient heat capacity to heat the joint quickly and efficiently in order to minimize contact time to the part. Pencil tip probes work very well. Neither heavy-duty electrical irons of greater than 45 W nor flame-heated irons and large heavy tips are recommended, as the tip temperatures are far too high and uncontrollable and can easily exceed the time-temperature limit of the part. Teccor Fastpak devices require a different soldering technique. Circuit connection can be done by either quick-connect terminals or solder. Since most quick-connect 0.250" female terminals have a maximum rating of 30 A, connection to terminals should be made by soldering wires instead of quick-connects. Recommended wire is 10 AWG stranded wire for use with MT1 and MT2 for load currents above 30 A. Soldering should be performed with a 100-watt soldering iron. The iron should not remain in contact with the wire and terminal longer than 40 seconds so the Fastpak triac is not damaged. For the Teccor TO-218X package, the basic rules for hand soldering apply; however, a larger iron may be required to apply sufficient heat to the larger leads to efficiently solder the joint. Remember not to exceed the lead solder temperatures of +230 C for 10 seconds, maximum, 1/16" (1.59mm) from the case. A 60/40 or 63/37 Sn/Pb solder is acceptable. This low meltingpoint solder, used in conjunction with a mildly activated rosin flux, is recommended. Insert the device into the PC board and, if required, attach the device to the heat sink before soldering. Each lead should be individually heat sinked as it is soldered. Commercially available heat sink clips are excellent for this use. Hemostats may also be used if available. Needle-nose pliers are a good heat sink choice; however, they are not as handy as stand-alone type clips. In any case, the lead should be clipped or grasped between the solder joint and the case, as near to the joint as possible. Avoid straining or twisting the lead in any way.
Temperature - C
260 240 220 200 180 160 140 120 100 80 60 40 20 0 0 30 60 90 120 150 180 210 240 270 300 <2.5 C/s 0.5 - 0.6 C/s Soaking Zone
60 - 90 s typical ( 2 min. MAX )
Pre-heat
Soak
Peak Temperature 220 C - 245 C 1.3 - 1.6 C/s
Reflow
Cool Down
<2.5 C/s
Reflow Zone
30 - 60 s typical ( 2 min. MAX )
Pre-heating Zone
( 2-4 min MAX )
Time (Seconds)
Figure AN1004.12 Reflow Soldering with Pre-heating
Dip Soldering
Dip soldering is very similar to wave soldering, but it is a hand operation. Follow the same considerations as for wave soldering, particularly the time-temperature cycle which may become operator dependent because of the wide process variations that may occur. This method is not recommended. Board or device clean-up is left to the discretion of the customer. Teccor devices are tolerant of a wide variety of solvents, and they conform to MIL-STD 202E method 215 "Resistance to Solvents."
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Notes
AN1005
5AN1005
Surface Mount Soldering Recommendations
With the components in position, the substrate is heated to a point where the solder begins to flow. This can be done on a heating plate, on a conveyor belt running through an infrared tunnel, or by using vapor phase soldering. In the vapor phase soldering process, the entire PC board is uniformly heated within a vapor phase zone at a temperature of approximately 215 C. The saturated vapor phase zone is obtained by heating an inert (inactive) fluid to the boiling point. The vapor phase is locked in place by a secondary vapor. (Figure AN1005.1) Vapor phase soldering provides uniform heating and prevents overheating.
Transport
Introduction
The most important consideration in reliability is achieving a good solder bond between surface mount device (SMD) and substrate since the solder provides the thermal path from the chip. A good bond is less subject to thermal fatiguing and will result in improved device reliability. The most economic method of soldering is a process in which all different components are soldered simultaneously, such as DO-214, Compak, TO-252 devices, capacitors, and resistors.
Reflow Of Soldering
The preferred technique for mounting microminiature components on hybrid thick- and thin-film is reflow soldering. The DO-214 is designed to be mounted directly to or on thick-film metallization which has been screened and fired on a substrate. The recommended substrates are Alumina or P.C. Board material. Recommended metallization is silver palladium or molymanganese (plated with nickel or other elements to enhance solderability). For more information, consult Du Pont's Thick-Film handbook or the factory. It is best to prepare the substrate by either dipping it in a solder bath or by screen printing a solder paste. After the substrate is prepared, devices are put in place with vacuum pencils. The device may be laid in place without special alignment procedures since it is self-aligning during the solder reflow process and will be held in place by surface tension. For reliable connections, keep the following in mind: (1) Maximum temperature of the leads or tab during the soldering cycle does not exceed 275 C. (2) Flux must affect neither components nor connectors. (3) Residue of the flux must be easy to remove. Good flux or solder paste with these properties is available on the market. A recommended flux is Alpha 5003 diluted with benzyl alcohol. Dilution used will vary with application and must be determined empirically. Having first been fluxed, all components are positioned on the substrate. The slight adhesive force of the flux is sufficient to keep the components in place. Because solder paste contains a flux, it has good inherent adhesive properties which eases positioning of the components. Allow flux to dry at room temperature or in a 70 C oven. Flux should be dry to the touch. Time required will depend on flux used.
Vapor lock (secondary medium) Vapor phase zone
Cooling pipes PC board Heating elements
Boiling liquid (primary medium)
Figure AN1005.1
Principle of Vapor Phase Soldering
No matter which method of heating is used, the maximum allowed temperature of the plastic body must not exceed 250 C during the soldering process. For additional information on temperature behavior during the soldering process, see Figure AN1005.2 and Figure AN1005.3.
Pre-heat Soak
Peak Temperature 220 C - 245 C 1.3 - 1.6 C/s <2.5 C/s 0.5 - 0.6 C/s Soaking Zone <2.5 C/s
60 - 90 s typical ( 2 min. MAX )
260 240 220
Reflow
Cool Down
Temperature - C
200 180 160 140 120 100 80 60 40 20 0 0 30 60 90
Reflow Zone
30 - 60 s typical ( 2 min. MAX )
Pre-heating Zone
( 2-4 min MAX )
120
150
180
210
240
270
300
Time (Seconds)
Figure AN1005.2
Reflow Soldering Profile
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Application Notes
Reflow Soldering Zones
Zone 1: Initial Pre-heating Stage (25 C to 150 C)
* * * Excess solvent is driven off. PCB and Components are gradually heated up. Temperature gradient shall be <2.5 C/Sec.
0.110 (2.8) 0.079 (2.0) 0.079 (2.0) 0.079 (2.0) 0.040 (1.0) 0.030 (0.76)
Zone 2: Soak Stage (150 C to 180 C)
* * * * Flux components start activation and begin to reduce the oxides on component leads and PCB pads. PCB components are brought nearer to the temperature at which solder bonding can occur. Soak allows different mass components to reach the same temperature. Activated flux keeps metal surfaces from re-oxidizing.
Pad Outline
Dimensions are in inches (and millimeters).
Figure AN1005.4
Modified DO-214 Compak -- Three-leaded Surface Mount Package
Zone 3: Reflow Stage (180 C to 235 C)
* * Paste is brought to the alloy's melting point. Activated flux reduces surface tension at the metal interface so metallurgical bonding occurs.
1. Screen print solder paste (or flux)
Zone 4: Cool-down Stage (180 C to 25 C)
Assembly is cooled evenly so thermal shock to the components or PCB is reduced. The surface tension of the liquid solder tends to draw the leads of the device towards the center of the soldering area and so has a correcting effect on slight mispositionings. However, if the layout is not optimized, the same effect can result in undesirable shifts, particularly if the soldering areas on the substrate and the components are not concentrically arranged. This problem can be solved by using a standard contact pattern which leaves sufficient scope for the self-positioning effect (Figure AN1005.3 and Figure AN1005.4) Figure AN1005.5 shows the reflow soldering procedure.
2. Place component (allow flux to dry)
0.079 (2.0)
Pad Outline
0.110 (2.8)
0.079 (2.0) Dimensions are in inches (and millimeters).
3. Reflow solder
Figure AN1005.5
Reflow Soldering Procedure
Figure AN1005.3
Minimum Required Dimensions of Metal Connection of Typical DO-214 Pads on Hybrid Thick- and Thinfilm Substrates
After the solder is set and cooled, visually inspect the connections and, where necessary, correct with a soldering iron. Finally, the remnants of the flux must be removed carefully. Use vapor degrease with an azeotrope solvent or equivalent to remove flux. Allow to dry. After the drying procedure is complete, the assembly is ready for testing and/or further processing.
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Application Notes
AN1005
Wave Soldering
Wave soldering is the most commonly used method for soldering components in PCB assemblies. As with other soldering processes, a flux is applied before soldering. After the flux is applied, the surface mount devices are glued into place on a PC board. The board is then placed in contact with a molten wave of solder at a temperature between 240 C and 260 C, which affixes the component to the board. Dual wave solder baths are also in use. This procedure is the same as mentioned above except a second wave of solder removes excess solder. Although wave soldering is the most popular method of PCB assembly, drawbacks exist. The negative features include solder bridging and shadows (pads and leads not completely wetted) as board density increases. Also, this method has the sharpest thermal gradient. To prevent thermal shock, some sort of pre-heating device must be used. Figure AN1005.6 shows the procedure for wave soldering PCBs with surface mount devices only. Figure AN1005.7 shows the procedure for wave soldering PCBs with both surface mount and leaded components.
PC board
Insert leaded components Turn over the PC board Apply glue
Place SMDs
Cure glue
or
Turn over the PC board
Apply glue
Screen print glue
Wave solder
Place component
Figure AN1005.7
Wave Soldering PCBs With Both Surface Mount and Leaded Components
Immersion Soldering
Maximum allowed temperature of the soldering bath is 235 C. Maximum duration of soldering cycle is five seconds, and forced cooling must be applied.
Cure glue
Hand Soldering
It is possible to solder the DO-214, Compak, and TO-252 devices with a miniature hand-held soldering iron, but this method has particular drawbacks and should be restricted to laboratory use and/or incidental repairs on production circuits.
Recommended Metal-alloy
Wave solder
(1) 63/37 Sn/Pb (2) 60/40 Sn/Pb
Figure AN1005.6
Wave Soldering PCBs With Surface Mount Devices Only
Pre-Heating
Pre-heating is recommended for good soldering and to avoid damage to the DO-214, Compak, TO-252 devices, other components, and the substrate. Maximum pre-heating temperature is 165 C while the maximum pre-heating duration may be 10 seconds. However, atmospheric pre-heating is permissible for several minutes provided temperature does not exceed 125 C.
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Application Notes
Gluing Recommendations
Prior to wave soldering, surface mount devices (SMDs) must be fixed to the PCB or substrate by means of an appropriate adhesive. The adhesive (in most cases a multicomponent adhesive) has to fulfill the following demands: * * * Uniform viscosity to ensure easy coating No chemical reactions upon hardening in order not to deteriorate component and PC board Straightforward exchange of components in case of repair
(3) Cut small pieces of the alloy solder and flow each piece onto each of the other legs of the component. Indium-tin solder is available from ACI Alloys, San Jose, CA and Indium Corporation of America, Utica, NY.
Multi-use Footprint
Package soldering footprints can be designed to accommodate more than one package. Figure AN1005.8 shows a footprint design for using both the Compak and an SOT-223. Using the dual pad outline makes it possible to use more than one supplier source.
Low-temperature Solder for Reducing PC Board Damage
In testing and troubleshooting surface-mounted components, changing parts can be time consuming. Moreover, desoldering and soldering cycles can loosen and damage circuit-board pads. Use low-temperature solder to minimize damage to the PC board and to quickly remove a component. One low-temperature alloy is indium-tin, in a 50/50 mixture. It melts between 118 C and 125 C, and tin-lead melts at 183 C. If a component needs replacement, holding the board upside down and heating the area with a heat gun will cause the component to fall off. Performing the operation quickly minimizes damage to the board and component. Proper surface preparation is necessary for the In-Sn alloy to wet the surface of the copper. The copper must be clean, and you must add flux to allow the alloy to flow freely.You can use rosin dissolved in alcohol. Perform the following steps: (1) Cut a small piece of solder and flow it onto one of the pads. (2) Place the surface-mount component on the pad and melt the soldered pad to its pin while aligning the part. (This operation places all the pins flat onto their pads.)
Cleaning Recommendations
Using solvents for PC board or substrate cleaning is permitted from approximately 70 C to 80 C. The soldered parts should be cleaned with azeotrope solvent followed by a solvent such as methol, ethyl, or isopropyl alcohol. Ultrasonic cleaning of surface mount components on PCBs or substrates is possible. The following guidelines are recommended when using ultrasonic cleaning: * * * * * Cleaning agent: Isopropanol Bath temperature: approximately 30 C Duration of cleaning: MAX 30 seconds Ultrasonic frequency: 40 kHz Ultrasonic changing pressure: approximately 0.5 bar
Cleaning of the parts is best accomplished using an ultrasonic cleaner which has approximately 20 W of output per one liter of solvent. Replace the solvent on a regular basis.
Gate MT2 / Anode MT1 / Cathode
0.079 (2.0)
0.079 (2.0)
0.079 (2.0) 0.040 (1.0)
Compak Footprint
0.110 (2.8)
0.030 (.76)
Gate M T 2 MT1 Not used
Footprint for either Compak or SOT-223
Pad Outline
0.328 (8.33) 0.019 (.48) 0.040 (1.0) 0.150 (3.8) 0.030 (.76)
0.079 (2.0)
0.059 (1.5) TYP 0.091 TYP (2.31)
Gate MT2 / Anode
MT2 / Anode
SOT-223 Footprint
0.079 (2.0)
0.079 (2.0)
.055 (1.4)
MT1 / Cathode
Dual Pad Outline
Dimensions are in inches (and millimeters).
Figure AN1005.8
Dual Footprint for Compak Package
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AN1006
6
Testing Teccor Semiconductor Devices Using Curve Tracers
through several values, and a different trace is drawn on each sweep to generate a family of curves.
Introduction
One of the most useful and versatile instruments for testing semiconductor devices is the curve tracer (CT). Tektronix is the best known manufacturer of curve tracers and produces four basic models: 575, 576, 577 and 370. These instruments are specially adapted CRT display screens with associated electronics such as power supplies, amplifiers, and variable input and output functions that allow the user to display the operating characteristics of a device in an easy-to-read, standard graph form. Operation of Tektronix CTs is simple and straightforward and easily taught to non-technical personnel. Although widely used by semiconductor manufacturers for design and analytical work, the device consumer will find many uses for the curve tracer, such as incoming quality control, failure analysis, and supplier comparison. Curve tracers may be easily adapted for go-no go production testing. Tektronix also supplies optional accessories for specific applications along with other useful hardware.
Limitations, Accuracy, and Correlation
Although the curve tracer is a highly versatile device, it is not capable of every test that one may wish to perform on semiconductor devices such as dv/dt, secondary reverse breakdown, switching speeds, and others. Also, tests at very high currents and/or voltages are difficult to conduct accurately and without damaging the devices. A special high-current test fixture available from Tektronix can extend operation to 200 A pulsed peak. Kelvin contacts available on the 576 and 577 eliminate inaccuracy in voltage measured at high current (VTM) by sensing voltage drop due to contact resistance and subtracting from the reading. Accuracy of the unit is within the published manufacturer's specification. Allow the curve tracer to warm up and stabilize before testing begins. Always expand the horizontal or vertical scale as far as possible to increase the resolution. Be judicious in recording data from the screen, as the trace line width and scale resolution factor somewhat limit the accuracy of what may be read. Regular calibration checks of the instrument are recommended. Some users keep a selection of calibrated devices on hand to verify instrument operation when in doubt. Re-calibration or adjustment should be performed only by qualified personnel. Often discrepancies exist between measurements taken on different types of instrument. In particular, most semiconductor manufacturers use high-speed, computerized test equipment to test devices. They test using very short pulses. If a borderline unit is then measured on a curve tracer, it may appear to be out of specification. The most common culprit here is heat. When a semiconductor device increases in temperature due to current flow, certain characteristics may change, notably gate characteristics on SCRs, gain on transistors, leakage, and so on. It is very difficult to operate the curve tracer in such a way as to eliminate the heating effect. Pulsed or single-trace operation helps reduce this problem, but care should be taken in comparing curve tracer measurements to computer tests. Other factors such as stray capacitances, impedance matching, noise, and device oscillation also may create differences.
Tektronix Equipment
Although Tektronix no longer produces curve tracer model 575, many of the units are still operating in the field, and it is still an extremely useful instrument. The 576, 577 and 370 are current curve tracer models and are more streamlined in their appearance and operation. The 577 is a less elaborate version of the 576, yet retains all necessary test functions. The following basic functions are common to all curve tracers: * Power supply supplies positive DC voltage, negative DC voltage, or AC voltage to bias the device. Available power is varied by limiting resistors. Step generator supplies current or voltage in precise steps to control the electrode of the device. The number, polarity, and frequency of steps are selectable. Horizontal amplifier displays power supply voltage as applied to the device. Scale calibration is selectable. Vertical amplifier displays current drawn from the supply by the device. Scale calibration is selectable.
*
* *
Curve tracer controls for beam position, calibration, pulse operation, and other functions vary from model to model. The basic theory of operation is that for each curve one terminal is driven with a constant voltage or current and the other one is swept with a half sinewave of voltage. The driving voltage is stepped
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AN1006
Application Notes
Safety (Cautions and Warnings)
Adhere rigidly to Tektronix safety rules supplied with each curve tracer. No attempt should be made to defeat any of the safety interlocks on the device as the curve tracer can produce a lethal shock. Also, older 575 models do not have the safety interlocks as do the new models. Take care never to touch any device or open the terminal while energized. WARNING: Devices on the curve tracer may be easily damaged from electrical overstress. Follow these rules to avoid destroying devices: * * * * * * Familiarize yourself with the expected maximum limits of the device. Limit the current with the variable resistor to the minimum necessary to conduct the test. Increase power slowly to the specified limit. Watch for device "runaway" due to heating. Apply and increase gate or base drive slowly and in small steps. Conduct tests in the minimum time required.
Model 576 Curve Tracer Procedures
The following test procedures are written for use with the model 576 curve tracer. (Figure AN1006.1) See "Model 370 Curve Tracer Procedure Notes" on page AN1006-16 and "Model 577 Curve Tracer Procedure Notes" on page AN1006-18 for setting adjustments required when using model 370 and 577 curve tracers. The standard 575 model lacks AC mode, voltage greater than 200 V, pulse operations, DC mode, and step offset controls. The 575 MOD122C does allow voltage up to 400 V, including 1500 V in an AC mode. Remember that at the time of design, the 575 was built to test only transistors and diodes. Some ingenuity, experience, and external hardware may be required to test other types of devices. For further information or assistance in device testing on Tektronix curve tracers, contact the Teccor Applications Engineering group.
General Test Procedures
Read all manuals before operating a curve tracer. Perform the following manufacturer's equipment check: 1. Turn on and warm up curve tracer, but turn off, or down, all power supplies. 2. Correctly identify terminals of the device to be tested. Refer to the manufacturer's guide if necessary. 3. Insert the device into the test fixture, matching the device and test terminals. 4. Remove hands from the device and/or close interlock cover. 5. Apply required bias and/or drive. 6. Record results as required. 7. Disconnect all power to the device before removing.
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Application Notes
AN1006
TYPE 576
TEKTRONIX, INC.
CURVE TRACER
PORTLAND, ORE, U.S.A.
VERTICAL
PER
V E R T
DIV
PER
DISPLAY OFFSET
H O R I Z
CRT
DIV
PER
S T E P
()k DIV 9m PER DIV
HORIZONTAL HORIZONTAL VOLTAGE CONTROL Note: All Voltage Settings Will Be Referenced to "Collector" STEP GENERATOR
AMPLITUDE
COLLECTOR SUPPLY VARIABLE COLLECTOR SUPPLY VOLTAGE RANGE MAX PEAK POWER (POWER DISSIPATION)
STEP/OFFSET AMPLITUDE (AMPS/VOLTS)
OFFSET
STEP/OFFSET POLARITY STEP FAMILY RATE
TERMINAL JACKS
C MT2/ANODE VARIABLE COLLECTOR SUPPLY VOLTAGE B GATE/TRIGGER E MT1/CATHODE
C
TERMINAL SELECTOR
B LEFT-RIGHT SELECTOR FOR TERMINAL JACKS
E
KELVIN TERMINALS USED WHEN MEASURING VTM OR VFM
Figure AN1006.1
Tektronix Model 576 Curve Tracer
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AN1006
Application Notes
Power Rectifiers
The rectifier is a unidirectional device which conducts when forward voltage (above 0.7 V) is applied. To connect the rectifier: 1. Connect Anode to Collector Terminal (C). 2. Connect Cathode to Emitter Terminal (E). To begin testing, perform the following procedures.
tronix model 176 high-current module. The procedure below is done at IT(RMS) = 10 A (20 APK). This test parameter allows the use of a standard curve tracer and still provides an estimate of whether VFM is within specification.
SOCKET
Procedure 1: VRRM and IRM
To measure the VRRM and IRM parameter: 1. Set Variable Collector Supply Voltage Range to 1500 V. (2000 V on 370) 2. Set Horizontal knob to sufficient scale to allow viewing of trace at the required voltage level (100 V/DIV for 400 V and 600 V devices and 50 V/DIV for 200 V devices). 3. Set Mode to Leakage. 4. Set Vertical knob to 100 A/DIV. (Due to leakage setting, the CRT readout will be 100 nA per division.) 5. Set Terminal Selector to Emitter Grounded-Open Base. 6. Set Polarity to (-). 7. Set Power Dissipation to 2.2 W. (2 W on 370) 8. Set Left-Right Terminal Jack Selector to correspond with location of test fixture. 9. Increase Variable Collector Supply Voltage to the rated V RRM of the device and observe the dot on the CRT. Read across horizontally from the dot to the vertical current scale. This measured value is the leakage current. (Figure AN1006.2)
Figure AN1006.3
PER
SOCKET PINS One set of pins wired to Collector (C), Base (B), and Emitter (E) Terminals
Socket used must have two sets of pins
The pins which correspond to the anode and cathode of the device are wired to the terminals marked C SENSE (MT2/Anode) and E SENSE (MT1/Cathode). The gate does not require a Kelvin connection.
Instructions for Wiring Kelvin Socket
IRM VRRM
V E R T
DIV
100 nA
To measure the VFM parameter: 1. Set Variable Collector Supply Voltage Range to 15 Max Peak Volts. (16 V on 370) 2. Set Horizontal knob to 0.5 V/DIV. 3. Set Mode to Norm. 4. Set Vertical knob to 2 A/DIV. 5. Set Power Dissipation to 220 W (100 W on 577). 6. Set Polarity to (+). 7. Set Left-Right Terminal Jack Selector to correspond with location of test fixture. 8. Increase Variable Collector Supply Voltage until current reaches 20 A. WARNING: Limit test time to 15 seconds maximum. To measure V FM, follow along horizontal scale to the point where the trace crosses the 20 A axis. The distance from the left-hand side of scale to the crossing point is the VFM value. (Figure AN1006.4) Note: Model 370 current is limited to 10 A.
PER
H O R I Z
DIV
100 V
PER
S T E P
()k DIV 9m PER DIV
Figure AN1006.2
IRM = 340 nA at VRRM = 600 V
Procedure 2: VFM
Before testing, note the following: * A Kelvin test fixture is required for this test. If a Kelvin fixture is not used, an error in measurement of VFM will result due to voltage drop in fixture. If a Kelvin fixture is not available, Figure AN1006.3 shows necessary information to wire a test fixture with Kelvin connections. Due to the current limitations of standard curve tracer model 576, VFM cannot be tested at rated current without a Tek-
*
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Application Notes
AN1006
Procedure 2: VDRM, IDRM
PER
VFM
V E R T
DIV
2 A
To measure the VDRM and IDRM parameter: 1. Set Left-Right Terminal Jack Selector to correspond with location of test fixture. 2. Set Variable Collector Supply Voltage to the rated VDRM of the device and observe the dot on CRT. Read across horizontally from the dot to the vertical current scale. This measured value is the leakage current. (Figure AN1006.5) WARNING: Do NOT exceed VDRM/V RRM rating of SCRs, triacs, or Quadracs. These devices can be damaged.
PER
PER
H O R I Z
DIV
500 mV
IT
PER
S T E P
()k DIV 9m PER DIV
Figure AN1006.4
VFM = 1 V at IPK = 20 A
V E R T
DIV
100 nA
PER
SCRs
SCRs are half-wave unidirectional rectifiers turned on when current is supplied to the gate terminal. If the current supplied to the gate is to be in the range of 12 A and 500 A, then a sensitive SCR is required; if the gate current is between 1 mA and 50 mA, then a non-sensitive SCR is required. To connect the rectifier: 1. Connect Anode to Collector Terminal (C). 2. Connect Cathode to Emitter Terminal (E). Note: When sensitive SCRs are being tested, a 1 k resistor must be connected between the gate and the cathode, except when testing IGT. To begin testing, perform the following procedures.
Figure AN1006.5 IDRM = 350 nA at VDRM = 600 V
H O R I Z
DIV
100 V
VDRM IDRM
PER
S T E P
()k DIV 9m PER DIV
Procedure 3: VRRM, IRRM
To measure the VRRM and IRRM parameter: 1. Set Polarity to (-). 2. Repeat Steps 1 and 2 (V DRM, IDRM) except substitute V RRM value for VDRM. (Figure AN1006.6)
.
PER
Procedure 1: VDRM, VRRM, IDRM, IRRM
To measure the VDRM, V RRM, IDRM, and IRRM parameter: 1. Set Variable Collector Supply Voltage Range to appropriate Max Peak Volts for device under test. (Value selected should be equal to or greater than the device's V DRM rating.) 2. Set Horizontal knob to sufficient scale to allow viewing of trace at the required voltage level. (The 100 V/DIV scale should be used for testing devices having a V DRM value of 600 V or greater; the 50 V/DIV scale for testing parts rated from 300 V to 500 V, and so on.) 3. Set Mode to Leakage. 4. Set Polarity to (+). 5. Set Power Dissipation to 0.5 W. (0.4 W on 370) 6. Set Terminal Selector to Emitter Grounded-Open Base. 7. Set Vertical knob to approximately ten times the maximum leakage current (I DRM, IRRM) specified for the device. (For sensitive SCRs, set to 50 A.) Note: The CRT screen readout should show 1% of the maximum leakage current if the vertical scale is divided by 1,000 when leakage current mode is used.
IRRM VRRM
V E R T
DIV
100 nA
PER
H O R I Z
DIV
100 V
PER
S T E P
()k DIV 9m PER DIV
Figure AN1006.6
IRRM = 340 nA at VRRM = 600 V
Procedure 4: VTM
To measure the VTM parameter: 1. Set Terminal Selector to Step Generator-Emitter Grounded. 2. Set Polarity to (+). 3. Set Step/Offset Amplitude to twice the maximum I GT rating of the device (to ensure the device turns on). For sensitive SCRs, set to 2 mA. 4. Set Max Peak Volts to 15 V. (16 V on 370) 5. Set Offset by depressing 0 (zero).
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AN1006
Application Notes
6. Set Rate by depressing Norm. 7. Set Step Family by depressing Rep (repetitive). 8. Set Mode to DC. 9. Set Horizontal knob to 0.5 V/DIV. 10. Set Power Dissipation to 220 W (100 W on 577). 11. Set Number of Steps to 1. (Set steps to 0 (zero) on 370.) 12. Set Vertical knob to a sufficient setting to allow the viewing of 2 times the IT(RMS) rating of the device (IT(peak)) on CRT. Before continuing with testing, note the following: (1) Due to the excessive amount of power that can be generated in this test, only parts with an I T(RMS) rating of 6 A or less should be tested on standard curve tracer. If testing devices above 6 A, a Tektronix model 176 high-current module is required. (2) A Kelvin test fixture is required for this test. If a Kelvin fixture is not used, an error in measurement of V TM will result due to voltage drop in the fixture. If a Kelvin fixture is not available, Figure AN1006.3 shows necessary information to wire a test fixture with Kelvin connectors. 13. Set Left-Right Terminal Jack Selector to correspond with the location of the test fixture. 14. Increase Variable Collector Supply Voltage until current reaches rated I T(peak), which is twice the IT(RMS) rating of theSCR under test. Note: Model 370 current is limited to 10 A. WARNING: Limit test time to 15 seconds maximum after the Variable Collector Supply has been set to IT(peak), After the Variable Collector Supply Voltage has been set to IT(peak), the test time can automatically be shortened by changing Step Family from repetitive to single by depressing the Single button. To measure V TM, follow along horizontal scale to the point where the trace crosses the IT(peak) value. The distance from the lefthand side of scale to the intersection point is the VTM value. (Figure AN1006.7)
PER
3. Set Max Peak Volts to 75 V. (80 V on 370) 4. Set Mode to DC. 5. Set Horizontal knob to Step Generator. 6. Set Vertical knob to approximately 10 percent of the maximum IH specified. Note: Due to large variation of holding current values, the scale may have to be adjusted to observe holding current. 7. Set Number of Steps to 1. 8. Set Offset by depressing 0 (zero). (Press Aid and Oppose at the same time on 370.) 9. Set Step/Offset Amplitude to twice the maximum I GT of the device. 10. Set Terminal Selector to Step Generator-Emitter Grounded. 11. Set Step Family by depressing Single. 12. Set Left-Right Terminal Jack Selector to correspond with location of test fixture. 13. Increase Variable Collector Supply Voltage to maximum position (100). 14. Set Step Family by depressing Single. (This could possibly cause the dot on CRT to disappear, depending on the vertical scale selected.) 15. Change Terminal Selector from Step Generator-Emitter Grounded to Open Base-Emitter Grounded. 16. Decrease Variable Collector Supply Voltage to the point where the line on the CRT changes to a dot. The position of the beginning point of the line, just before the line becomes a dot, represents the holding current value. (Figure AN1006.8)
PER
V E R T
DIV
500 A
PER
H O R I Z
DIV
PER
S T E P
V E R T
DIV
2 A
IH
Figure AN1006.8 IH = 1.2 mA
VTM
PER
()k DIV 9m PER DIV
H O R I Z
DIV
500 mV
PER
Procedure 6: IGT and VGT
100 mA
IPK
S T E P
To measure the IGT and VGT parameter: 1. Set Polarity to (+). 2. Set Number of Steps to 1. 3. Set Offset by depressing Aid. 4. Set Offset Multiplier to 0 (zero). (Press Aid and Oppose at the same time on 370.) 5. Set Terminal Selector to Step Generator-Emitter Grounded. 6. Set Mode to Norm. 7. Set Max Peak Volts to 15 V. (16 V on 370)
()k DIV 9m PER DIV
20
Figure AN1006.7
VTM = 1.15 V at IT(peak) = 12 A
Procedure 5: IH
To measure the IH parameter: 1. Set Polarity to (+). 2. Set Power Dissipation to 2.2 W. (2 W on 370)
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Application Notes
AN1006
8. Set Power Dissipation to 2.2 W. (2 W on 370) For sensitive SCRs, set at 0.5 W. (0.4 W on 370) 9. Set Horizontal knob to 2 V/DIV. 10. Set Vertical knob to 50 mA/DIV. 11. Increase Variable Collector Supply Voltage until voltage reaches 12 V on CRT. 12. After 12 V setting is completed, change Horizontal knob to Step Generator.
Procedure 9: GT will be numerically displayed on screen under offset value.)
PER
V E R T
DIV
50 mA
PER
H O R I Z
DIV
Procedure 7: IGT
To measure the IGT parameter: 1. Set Step/Offset Amplitude to 20% of maximum rated I GT. Note: R GK should be removed when testing I GT. 2. Set Left-Right Terminal Jack Selector to correspond with location of the test fixture. 3. Gradually increase Offset Multiplier until device reaches the conduction point. (Figure AN1006.9) Measure IGT by following horizontal axis to the point where the vertical line crosses axis. This measured value is I GT. (On 370, IGT will be numerically displayed on screen under offset value.)
PER
PER
VGT
S T E P
200 mV
()k DIV 9m PER DIV
250m
Figure AN1006.10 VGT = 580 mV
Triacs
Triacs are full-wave bidirectional AC switches turned on when current is supplied to the gate terminal of the device. If gate control in all four quadrants is required, then a sensitive gate triac is needed, whereas a standard triac can be used if gate control is only required in Quadrants I through III. To connect the triac: 1. Connect the Gate to the Base Terminal (B). 2. Connect MT1 to the Emitter Terminal (E). 3. Connect MT2 to the Collector Terminal (C).
V E R T
DIV
50 mA
PER
H O R I Z
DIV
PER
IGT
S T E P
10 A
To begin testing, perform the following procedures.
()k DIV 9m PER DIV
Procedure 1: (+)VDRM, (+)IDRM, (-)VDRM, (-)IDRM
5K
Note: The (+) and (-) symbols are used to designate the polarity MT2 with reference to MT1. To measure the (+)VDRM, (+)IDRM, (-)V DRM, and (-)IDRM parameter: 1. Set Variable Collector Supply Voltage Range to appropriate Max Peak Volts for device under test. (Value selected should be equal to the device's V DRM rating.) WARNING: Do NOT exceed V DRM/VRRM rating of SCRs, triacs, or Quadracs. These devices can be damaged. 2. Set Horizontal knob to sufficient scale to allow viewing of trace at the required voltage level. (The 100 V/DIV scale should be used for testing devices having a V DRM rating of 600 V or greater; the 50 V/DIV scale for testing parts rated from 30 V to 500 V, and so on.) 3. Set Mode to Leakage. 4. Set Polarity to (+). 5. Set Power Dissipation to 0.5 W. (0.4 W on 370) 6. Set Terminal Selector to Emitter Grounded-Open Base. 7. Set Vertical knob to ten times the maximum leakage current (IDRM) specified for the device. Note: The CRT screen readout should show 1% of the maximum leakage current. The vertical scale is divided by 1,000 when leakage mode is used.
Figure AN1006.9
IGT = 25 A
Procedure 8: VGT
To measure the VGT parameter: 1. Set Offset Multiplier to 0 (zero). (Press Aid and Oppose at the same time on 370.) 2. Set Step Offset Amplitude to 20% rated VGT. 3. Set Left-Right Terminal Jack Selector to correspond with location of test fixture. 4. Gradually increase Offset Multiplier until device reaches the conduction point. (Figure AN1006.10) Measure V GT by following horizontal axis to the point where the vertical line crosses axis. This measured value is V GT. (On 370, V GT will be numerically displayed on screen, under offset value.)
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Application Notes
Procedure 2: (+)VDRM, (+)IDRM
To measure the (+)V DRM and (+)IDRM parameter: 1. Set Left-Right Terminal Jack Selector to correspond with location of the test fixture. 2. Increase Variable Collector Supply Voltage to the rated V DRM of the device and observe the dot on the CRT. Read across horizontally from the dot to the vertical current scale. This measured value is the leakage current. (Figure AN1006.11)
PER
*
A Kelvin test fixture is required for this test. If a Kelvin fixture is not used, an error in measurement of VTM will result due to voltage drop in fixture. If a Kelvin fixture is not available, Figure AN1006.3 shows necessary information to wire a test fixture with Kelvin connections.
Procedure 5: VTM (Forward)
To measure the VTM (Forward) parameter: 1. Set Polarity to (+). 2. Set Left-Right Terminal Jack Selector to correspond with location of test fixture.
V E R T
DIV
50 nA
PER
H O R I Z
DIV
3. Increase Variable Collector Supply Voltage until current reaches rated IT(peak), which is 1.4 times IT(RMS) rating of the triac under test. Note: Model 370 current is limited to 10 A. WARNING: Limit test time to 15 seconds maximum. After the Variable Collector Supply Voltage has been set to IT(peak), the test time can automatically be set to a short test time by changing Step Family from repetitive to single by depressing the Single button. To measure V TM, follow along horizontal scale to the point where the trace crosses the IT(peak) value. The distance from the lefthand side of scale to the crossing point is the VTM value. (Figure AN1006.12)
PER
100 V
PER
VDRM IDRM
S T E P
()k DIV 9m PER DIV
Figure AN1006.11 (+)IDRM = 205 nA at (+)VDRM = 600 V
Procedure 3: (-)VDRM, (-)IDRM
To measure the (-)V DRM and (-)IDRM parameter: 1. Set Polarity to (-). 2. Repeat Procedures 1 and 2. (Read measurements from upper right corner of the screen.)
V E R T
DIV
2 A
PER
VTM
H O R I Z
DIV
500 mV
Procedure 4: VTM (Forward and Reverse)
To measure the VTM (Forward and Reverse) parameter: 1. Set Terminal Selector to Step Generator-Emitter Grounded. 2. Set Step/Offset Amplitude to twice the maximum IGT rating of the device (to insure the device turns on). 3. Set Variable Collector Supply Voltage Range to 15 V Max Peak volts. (16 V on 370) 4. Set Offset by depressing 0 (zero). 5. Set Rate by depressing Norm. 6. Set Step Family by depressing Rep (Repetitive). 7. Set Mode to Norm. 8. Set Horizontal knob to 0.5 V/DIV. 9. Set Power Dissipation to 220 W (100 W on 577). 10. Set Number of Steps to 1. 11. Set Step/Offset Polarity to non-inverted (button extended; on 577 button depressed). 12. Set Vertical knob to a sufficient setting to allow the viewing of 1.4 times the IT(RMS) rating of the device [IT(peak) on CRT]. Note the following: * Due to the excessive amount of power that can be generated in this test, only parts with an IT(RMS) rating of 8 A or less should be tested on standard curve tracer. If testing devices above 8 A, a Tektronix model 176 high-current module is required.
PER
IPK
S T E P
100 mA
()k DIV 9m PER DIV
20
Figure AN1006.12 VTM (forward) = 1.1 V at IPK = 11.3 A (8 A rms)
Procedure 6: VTM (Reverse)
To measure the VTM (Reverse) parameter: 1. Set Polarity to (-). 2. Set Left-Right Terminal Jack Selector to correspond with the location of the test fixture. 3. Increase Variable Collector Supply Voltage until current reaches rated IT(peak). 4. Measure V TM(Reverse) similar to Figure AN1006.12, except from upper right hand corner of screen.
Procedure 7: IH(Forward and Reverse)
To measure the IH (Forward and Reverse) parameter: 1. Set Step/Offset Amplitude to twice the I GT rating of the device. 2. Set Power Dissipation to 10 W.
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Application Notes
AN1006
3. Set Max Peak Volts to 75 V. (80 V on 370) 4. Set Mode to DC. 5. Set Horizontal knob to Step Generator. 6. Set Vertical knob to approximately 10% of the maximum I H specified. Note: Due to large variation of holding current values, the scale may have to be adjusted to observe holding current. 7. Set Number of Steps to 1. 8. Set Step/Offset Polarity to non-inverted (button extended, on 577 button depressed). 9. Set Offset by depressing 0 (zero). (Press Aid and Oppose at same time on 370.) 10. Set Terminal Selector to Step Generator-Emitter Grounded.
Procedure 10: IGT
To measure the IGT parameter: 1. Set Polarity to (+). 2. Set Number of Steps to 1. (Set number of steps to 0 (zero) on 370.) 3. Set Offset by depressing Aid. (On 577, also set Zero button to Offset. Button is extended.) 4. Set Offset Multiplier to 0 (zero). (Press Aid and Oppose at same time on 370.) 5. Set Terminal Selector to Step Generator-Emitter Grounded. 6. Set Mode to Norm. 7. Set Max Peak Volts to 15 V. (16 V on 370) 8. Set Power Dissipation to 10 W. 9. Set Step Family by depressing Single. 10. Set Horizontal knob to 2 V/DIV. 11. Set Vertical knob to 50 mA/DIV. 12. Set Step/Offset Polarity to non-inverted position (button extended, on 577 button depressed). 13. Set Variable Collector Supply Voltage until voltage reaches 12 V on CRT. 14. After 12 V setting is completed, change Horizontal knob to Step Generator.
Procedure 8: IH(Forward)
To measure the IH (Forward) parameter: 1. Set Polarity to (+). 2. Set Left-Right Terminal Jack Selector to correspond with location of test fixture. 3. Increase Variable Collector Supply Voltage to maximum position (100). 4. Set Step Family by depressing Single. This could possibly cause the dot on the CRT to disappear, depending on the vertical scale selected). 5. Decrease Variable Collector Supply Voltage to the point where the line on the CRT changes to a dot. The position of the beginning point of the line, just before the line becomes a dot, represents the holding current value. (Figure AN1006.13)
PER
Procedure 11: IGT - Quadrant I [MT2 (+) Gate (+)]
To measure the IGT - Quadrant I parameter: 1. Set Step/Offset Amplitude to approximately 10% of rated IGT. 2. Set Left-Right Terminal Jack Selector to correspond with location of test fixture. 3. Gradually increase Offset Multiplier until device reaches conduction point. (Figure AN1006.14) Measure IGT by following horizontal axis to the point where the vertical line passes through the axis. This measured value is I GT. (On 370, IGT is numerically displayed on screen under offset value.)
PER
V E R T
DIV
5 mA
PER
H O R I Z
DIV
PER
S T E P
50 mA
V E R T
DIV
50 mA
IH
Figure AN1006.13 I H (Forward) = 8.2 mA
()k DIV 9m PER DIV
PER
100m
H O R I Z
DIV
PER
Procedure 9: IH(Reverse)
To measure the IH (Reverse) parameter: 1. Set Polarity to (-). 2. Repeat Procedure 7 measuring IH(Reverse). (Read measurements from upper right corner of the screen.)
S T E P
5 mA
IGT
Figure AN1006.14 IGT in Quadrant I = 18.8 mA
()k DIV 9m PER DIV
10
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AN1006
Application Notes
Procedure 12: IGT - Quadrant II [MT2 (+) Gate (-)]
To measure the IGT - Quadrant II parameter: 1. Set Step/Offside Polarity by depressing Invert (release button on 577). 2. Set Polarity to (+). 3. Set observed dot to bottom right corner of CRT grid by turning the horizontal position knob. When Quadrant II testing is complete, return dot to original position. 4. Repeat Procedure 11.
9. Set Step Family by depressing Single. 10. Set Horizontal knob to 2 V/DIV. 11. Set Step/Offset Polarity to non-inverted position (button extended, on 577 button depressed). 12. Set Current Limit to 500 mA (not available on 577). 13. Increase Variable Collector Supply Voltage until voltage reaches 12 V on CRT. 14. After 12 V setting is complete, change Horizontal knob to Step Generator.
Procedure 13: IGT - Quadrant III [MT2 (-) Gate (-)]
To measure the IGT - Quadrant III parameter: 1. Set Polarity to (-). 2. Set Step/Offset Polarity to non-inverted position (button extended, on 577 button depressed). 3. Repeat Procedure 11. (Figure AN1006.15)
PER
Procedure 16: VGT - Quadrant I [MT2 (+) Gate (+)]
To measure the VGT - Quadrant I parameter: 1. Set Step/Offset Amplitude to 20% of rated V GT. 2. Set Left-Right Terminal Jack Selector to correspond with location of test fixture. 3. Gradually increase Offset Multiplier until device reaches conduction point. (Figure AN1006.16) Measure VGT by following horizontal axis to the point where the vertical line passes through the axis. This measured value will be V GT. (On 370, VGT will be numerically displayed on screen under offset value.)
PER
IGT
V E R T
DIV
50 mA
PER
H O R I Z
DIV
V E R T
DIV
50 mA
PER
S T E P
5 mA
PER
()k DIV 9m PER DIV
VGT
10
H O R I Z
DIV
PER
Figure AN1006.15 IGT in Quadrant III = 27 mA
S T E P
500 mV
Procedure 14: IGT - Quadrant IV [MT2 (-) Gate (+)]
To measure the IGT - Quadrant IV parameter: 1. Set Polarity to (-). 2. Set Step/Offset Polarity by depressing Invert (release button on 577). 3. Set observed dot to top left corner of CRT grid by turning the Horizontal position knob. When Quadrant IV testing is complete, return dot to original position. 4. Repeat Procedure 11.
Figure AN1006.16 VGT in Quadrant I = 780 mV
()k DIV 9m PER DIV
100m
Procedure 17: VGT - Quadrant II [MT2 (+) Gate (-)]
To measure the VGT - Quadrant II parameter: 1. Set Step/Offset Polarity by depressing Invert (release button on 577). 2. Set Polarity to (+). 3. Set observed dot to bottom right corner of CRT grid by turning the horizontal position knob. When Quadrant II testing is complete, return dot to original position. 4. Repeat Procedure 16.
Procedure 15: VGT
To measure the VGT parameter: 1. Set Polarity to (+). 2. Set Number of Steps to 1. (Set steps to 0 (zero) on 370.) 3. Set Offset by depressing Aid. (On 577, also set 0 (zero) button to Offset. Button is extended.) 4. Set Offset Multiplier to 0 (zero). (Press Aid and Oppose at same time on 370.) 5. Set Terminal Selector to Step Generator-Emitter Grounded. 6. Set Mode to Norm. 7. Set Max Peak Volts to 15 V. (16 V on 370) 8. Set Power Dissipation to 10 W.
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Procedure 18: VGT - Quadrant III [MT2 (-) Gate (-)]
To measure the VGT - Quadrant III parameter: 1. Set Polarity to (-). 2. Set Step/Offset Polarity to non-inverted position (button extended, on 577 button depressed).
AN1006 - 10
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Application Notes
AN1006
3. Repeat Procedure 16. (Figure AN1006.17)
PER
7. Set Vertical knob to ten times the maximum leakage current (IDRM) specified for the device.
V E R T
50 mA
VGT
DIV
Note: The CRT readout should show 1% of the maximum leakage current. The vertical scale is divided by 1,000 when the leakage mode is used.
PER
H O R I Z
DIV
Procedure 2: (+)VDRM and (+)IDRM
To measure the (+)VDRM and (+)IDRM parameter:
500 mV
PER
S T E P
1. Set Left-Right Terminal Jack Selector to correspond with the location of the test fixture. 2. Increase Variable Collector Supply Voltage to the rated V DRM of the device and observe the dot on the CRT. (Read across horizontally from the dot to the vertical current scale.) This measured value is the leakage current. (Figure AN1006.18) WARNING: Do NOT exceed VDRM/V RRM rating of SCRs, triacs, or Quadracs. These devices can be damaged.
PER
()k DIV 9m PER DIV
100m
Figure AN1006.17 VGT in Quadrant III = 820 mV
Procedure 19: VGT - Quadrant IV [MT2 (-) Gate (+)]
To measure the VGT - Quadrant IV parameter: 1. Set Polarity to (-). 2. Set Step/Offset Polarity by depressing Invert (release button on 577). 3. Set observed dot to top left corner of CRT grid by turning the Horizontal position knob. When testing is complete in Quadrant IV, return dot to original position. 4. Repeat Procedure 16.
V E R T
DIV
50 nA
PER
H O R I Z
DIV
50 V
PER
S T E P
Quadracs
Quadracs are simply triacs with an internally-mounted diac. As with triacs, Quadracs are bidirectional AC switches which are gate controlled for either polarity of main terminal voltage. To connect the Quadrac: 1. Connect Trigger to Base Terminal (B). 2. Connect MT1 to Emitter Terminal (E). 3. Connect MT2 to Collector Terminal (C). To begin testing, perform the following procedures.
VDRM IDRM
()k DIV 9m PER DIV
Figure AN1006.18 (+)I DRM = 51 nA at (+)VDRM = 400 V
Procedure 3: (-)VDRM and (-)IDRM
To measure the (-)VDRM and (-)IDRM parameter: 1. Set Polarity to (-). 2. Repeat Procedures 1 and 2. (Read measurements from upper right corner of screen).
Procedure 1: (+)VDRM, (+)IDRM, (-)VDRM, (-)IDRM
Note: The (+) and (-) symbols are used to designate the polarity of MT2 with reference to MT1. To measure the (+)V DRM, (+)IDRM, (-)VDRM, and (-)IDRM parameter: 1. Set Variable Collector Supply Voltage Range to appropriate Max Peak Volts for device under test. (Value selected should be equal to or greater than the device's V DRM rating). 2. Set Horizontal knob to sufficient scale to allow viewing of trace at the required voltage level. (The 100 V/DIV scale should be used for testing devices having a V DRM rating of 600 V or greater; the 50 V/DIV scale for testing parts rated from 300 V to 500 V, and so on). 3. Set Mode to Leakage. 4. Set Polarity to (+). 5. Set Power Dissipation to 0.5 W. (0.4 W on 370) 6. Set Terminal Selector to Emitter Grounded-Open Base.
Procedure 4: VBO, IBO, VBO (Quadrac Trigger Diac or Discrete Diac)
To connect the Quadrac: 1. Connect MT1 to Emitter Terminal (E). 2. Connect MT2 to Collector Terminal (C). 3. Connect Trigger Terminal to MT2 Terminal through a 10 resistor. To measure the VBO, IBO, and VBO parameter: 1. Set Variable Collector Supply Voltage Range to 75 Max Peak Volts.(80 V on 370) 2. Set Horizontal knob to 10 V/DIV. 3. Set Vertical knob to 50 A/DIV. 4. Set Polarity to AC. 5. Set Mode to Norm. 6. Set Power Dissipation to 0.5 W. (0.4 W on 370)
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AN1006
Application Notes
7. Set Terminal Selector to Emitter Grounded-Open Base.
*
Procedure 5: VBO (Positive and Negative)
To measure the VBO (Positive and Negative) parameter: 1. Set Left-Right Terminal Jack Selector to correspond with the location of the test fixture. 2. Set Variable Collector Supply Voltage to 55 V (65 V on 370) and apply voltage to the device under test (D.U.T.) using the Left Hand Selector Switch. The peak voltage at which current begins to flow is the VBO value. (Figure AN1006.19)
PER
A Kelvin test fixture is required for this test. If a Kelvin fixture is not used, an error in measurement of VTM will result due to voltage drop in fixture. If a Kelvin fixture is not available, Figure AN1006.3 shows necessary information to wire a test fixture with Kelvin connections.
To measure the VTM (Forward and Reverse) parameter: 1. Set Terminal Selector to Emitter Grounded-Open Base. 2. Set Max Peak Volts to 75 V. (80 V on 370) 3. Set Mode to Norm. 4. Set Horizontal knob to 0.5 V/DIV. 5. Set Power Dissipation to 220 watts (100 watts on a 577). 6. Set Vertical knob to a sufficient setting to allow the viewing of 1.4 times the IT(RMS) rating of the device IT(peak) on the CRT.
V E R T
DIV
50 A
VBO
+IBO
PER
H O R I Z
DIV
Procedure 9: VTM(Forward)
10 V
To measure the VTM (Forward) parameter: 1. Set Polarity to (+). 2. Set Left-Right Terminal Jack Selector to correspond with the location of the test fixture. 3. Increase Variable Collector Supply Voltage until current reaches rated IT(peak), which is 1.4 times the I T(RMS) rating of the triac under test. Note: Model 370 current is limited to 10 A. WARNING: Limit test time to 15 seconds maximum. 4. To measure V TM, follow along horizontal scale to the point where the trace crosses the I T(peak) value. This horizontal distance is the V TM value. (Figure AN1006.20)
PER
PER
IBO
+VBO
S T E P
()k DIV 9m PER DIV
Figure AN1006.19 (+)VBO = 35 V; (-)VBO = 36 V; ()IBO < 10 A
Procedure 6: IBO (Positive and Negative)
To measure the IBO (Positive and Negative) parameter, at the VBO point, measure the amount of device current just before the device reaches the breakover point. The measured current at this point is the IBO value. Note: If IBO is less than 10 A, the current cannot readily be seen on curve tracer.
V E R T
DIV
1 A
Procedure 7: VBO (Voltage Breakover Symmetry)
To measure the VBO (Voltage Breakover Symmetry) parameter: 1. Measure positive and negative VBO values per Procedure 5. 2. Subtract the absolute value of VBO (-) from V BO (+). The absolute value of the result is: V BO = [ I+V BO I - I -V BO I ]
VTM
PER
H O R I Z
DIV
500 mV
PER
IPK
S T E P
()k DIV 9m PER DIV
Procedure 8: VTM (Forward and Reverse)
To test VTM, the Quadrac must be connected the same as when testing VBO, IBO, and VBO. To connect the Quadrac: 1. Connect MT1 to Emitter Terminal (E). 2. Connect MT2 to Collector Terminal (C). 3. Connect Trigger Terminal to MT2 Terminal through a 10 resistor. Note the following: * Due to the excessive amount of power that can be generated in this test, only parts with an IT(RMS) rating of 8 A or less should be tested on standard curve tracer. If testing devices above 8 A, a Tektronix model 176 high-current module is required.
Figure AN1006.20 VTM (Forward) = 1.1 V at IPK = 5.6 A
Procedure 10: VTM(Reverse)
To measure the VTM (Reverse) parameter: 1. Set Polarity to (-). 2. Set Left-Right Terminal Jack Selector to correspond with the location of the test fixture. 3. Increase Variable Collector Supply Voltage until current reaches rated IT(peak). 4. Measure VTM(Reverse) the same as in Procedure 8. (Read measurements from upper right corner of screen).
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AN1006 - 12
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Application Notes
AN1006
Procedure 11: IH(Forward and Reverse)
For these steps, it is again necessary to connect the Trigger to MT2 through a 10 resistor. The other connections remain the same. To measure the IH (Forward and Reverse) parameter: 1. Set Power Dissipation to 50 W. 2. Set Max Peak Volts to 75 V. (80 V on 370) 3. Set Mode to DC. 4. Set Horizontal knob to 5 V/DIV. 5. Set Vertical knob to approximately 10% of the maximum I H specified. Note: Due to large variations of holding current values, the scale may have to be adjusted to observe holding current. 6. Set Terminal Selector to Emitter Grounded-Open Base.
Sidacs
The sidac is a bidirectional voltage-triggered switch. Upon application of a voltage exceeding the sidac breakover voltage point, the sidac switches on through a negative resistance region (similar to a diac) to a low on-state voltage. Conduction continues until current is interrupted or drops below minimum required holding current. To connect the sidac: 1. Connect MT1 to the Emitter Terminal (E). 2. Connect MT2 to the Collector Terminal (C). To begin testing, perform the following procedures.
Procedure 1: (+) VDRM, (+)IDRM, (-)VDRM, (-)IDRM
Note: The (+) and (-) symbols are used to designate the polarity of MT2 with reference to MT1. To measure the (+)VDRM, (+)IDRM, (-)V DRM, and (-)IDRM parameter: 1. Set Variable Collector Supply Voltage Range to 1500 Max Peak Volts. 2. Set Horizontal knob to 50 V/DIV. 3. Set Mode to Leakage. 4. Set Polarity to (+). 5. Set Power Dissipation to 2.2 W. (2 W on 370) 6. Set Terminal Selector to Emitter Grounded-Open Base. 7. Set Vertical knob to 50 A/DIV. (Due to leakage mode, the CRT readout will show 50 nA.)
Procedure 12: IH(Forward)
To measure the IH (Forward) parameter: 1. Set Polarity to (+). 2. Set Left-Right Terminal Jack Selector to correspond with the location of the test fixture. 3. Increase Variable Collector Supply Voltage to maximum position (100). Note: Depending on the vertical scale being used, the dot may disappear completely from the screen. 4. Decrease Variable Collector Supply Voltage to the point where the line on the CRT changes to a dot. The position of the beginning point of the line, just before the line changes to a dot, represents the I H value. (Figure AN1006.21)
PER
Procedure 2: (+)VDRM and (+)IDRM
To measure the (+)VDRM and (+)IDRM parameter: 1. Set Left-Right Terminal Jack Selector to correspond with the location of the test fixture. 2. Increase Variable Collector Supply Voltage to the rated V DRM of the device and observe the dot on the CRT. Read across horizontally from the dot to the vertical current scale. This measured value is the leakage current. (Figure AN1006.22)
PER
V E R T
DIV
5 mA
PER
H O R I Z
DIV
5 V
PER
S T E P
IH
()k DIV 9m PER DIV
V E R T
DIV
50 nA
PER
Figure AN1006.21 I H (Forward) = 18 mA
H O R I Z
DIV
50 V
Procedure 13: IH(Reverse)
To measure the IH (Reverse) parameter: 1. Set Polarity to (-). 2. Continue testing per Procedure 12 for measuring IH (Reverse).
PER
S T E P
VDRM IDRM
Figure AN1006.22 IDRM = 50 nA at VDRM = 90 V
()k DIV 9m PER DIV
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AN1006
Application Notes
Procedure 3: (-) VDRM and (-) IDRM
To measure the (-)V DRM and (-)IDRM parameter: 1. Set Polarity to (-). 2. Repeat Procedures 1 and 2. (Read measurements from upper right corner of the screen).
Procedure 7: IH(Forward and Reverse)
To measure the IH (Forward and Reverse) parameter: 1. Set Variable Collector Supply Voltage Range to 1500 Max Peak Volts (400 V on 577; 2000 V on 370). 2. Set Horizontal knob to a sufficient scale to allow viewing of trace at the required voltage level (50 V/DIV for devices with V BO range from 95 V to 215 V and 100 V/DIV for devices having V BO 215 V). 3. Set Vertical knob to 20% of maximum holding current specified. 4. Set Polarity to AC. 5. Set Mode to Norm. 6. Set Power Dissipation to 220 W (100 W on 577). 7. Set Terminal Selector to Emitter Grounded-Open Base. 8. Set Left-Right Terminal Jack Selector to correspond with the location of the test fixture. WARNING: Limit test time to 15 seconds maximum. 9. Increase Variable Collector Supply Voltage until device breaks over and turns on. (Figure AN1006.24)
PER
Procedure 4: VBO and IBO
To measure the VBO and IBO parameter: 1. Set Variable Collector Supply Voltage Range to 1500 Max Peak Volts. (2000 V on 370) 2. Set Horizontal knob to a sufficient scale to allow viewing of trace at the required voltage level (50 V/DIV for 95 V to 215 V V BO range devices and 100 V/DIV for devices having V BO 15 V). 3. Set Vertical knob to 50 A/DIV. 4. Set Polarity to AC. 5. Set Mode to Norm. 6. Set Power Dissipation to 10 W. 7. Set Terminal Selector to Emitter Grounded-Open Base. 8. Set Left-Right Terminal Jack Selector to correspond with location of test fixture.
Procedure 5: VBO
To measure the VBO parameter, increase Variable Collector Supply Voltage until breakover occurs. (Figure AN1006.23) The voltage at which current begins to flow and voltage on CRT does not increase is the V BO value.
PER
V E R T
DIV
20 mA
PER
IH IH
H O R I Z
DIV
50 V
PER
S T E P
V E R T
DIV
50 A
VBO +VBO
+IBO
PER
()k DIV 9m PER DIV
H O R I Z
DIV
50 V
Figure AN1006.24 IH = 48 mA in both forward and reverse directions
PER
IBO
S T E P
IH is the vertical distance between the center horizontal axis and the beginning of the line located on center vertical axis.
()k DIV 9m PER DIV
Procedure 8: VTM(Forward and Reverse)
To measure the VTM (Forward and Reverse) parameter: 1. Set Variable Collector Supply Voltage Range to 350 Max Peak Volts. (400 V on 370) 2. Set Horizontal knob to 0.5 V/DIV. 3. Set Vertical knob to 0.5 A/DIV. 4. Set Polarity to (+). 5. Set Mode to Norm. 6. Set Power Dissipation to 220 W (100 W on 577). 7. Set Terminal Selector to Emitter Grounded-Open Base. Before continuing with testing, note the following: * A Kelvin test fixture is required for this test. If a Kelvin fixture is not used, an error in measurement of VTM will result due to voltage drop in fixture. If a Kelvin fixture is not available, Figure AN1006.3 shows necessary information to wire a test fixture with Kelvin Connections.
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Figure AN1006.23 (+)VBO = 100 V; (-)VBO = 100 V; ()IBO < 10 A
Procedure 6: IBO
To measure the IBO parameter, at the VBO point, measure the amount of device current just before the device reaches the breakover mode. The measured current at this point is the IBO value. Note: If IBO is less than 10 A, the current cannot readily be seen on the curve tracer.
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AN1006 - 14
Application Notes
AN1006
To continue testing, perform the following procedures.
3. Set Vertical knob to 50 A/DIV. 4. Set Polarity to AC. 5. Set Mode to Norm. 6. Set Power Dissipation to 0.5 W. (0.4 W on 370) 7. Set Terminal Selector to Emitter Grounded-Open Base.
Procedure 9: VTM(Forward)
To measure the VTM (Forward) parameter: 1. Set Left-Right Terminal Jack Selector to correspond with the location of the test fixture. 2. Increase Variable Collector Supply Voltage until current reaches rated I T(peak), which is 1.4 times the I T(RMS) rating of the sidac. Note: Model 370 current is limited. Set to 400 mA. Check for 1.1 V MAX. WARNING: Limit test time to 15 seconds. 3. To measure V TM, follow along horizontal scale to the point where the trace crosses the IT(peak) value. This horizontal distance is the V TM value. (Figure AN1006.25)
PER
Procedure 2: VBO
To measure the VBO parameter: 1. Set Left-Right Terminal Jack Selector to correspond with the location of the test fixture. 2. Set Variable Collector Supply Voltage to 55 V (65 V for 370) and apply voltage to device under test (D.U.T.), using Left-Right-Selector Switch. The peak voltage at which current begins to flow is the V BO value. (Figure AN1006.26)
PER
V E R T
DIV
500 mA
V E R T
DIV
50 A
+IBO
500 mV
PER
PER
H O R I Z
DIV
H O R I Z
DIV
10 V
PER
VTM
PER
S T E P
IBO
VBO
+VBO
S T E P
IPK
()k DIV 9m PER DIV
()k DIV 9m PER DIV
Figure AN1006.25 VTM (Forward) = 950 mV at IPK = 1.4 A
Figure AN1006.26 (+)V BO = 35 V; (-)VBO = 36 V; ()IBO < 15 A; (-)IBO < 10 A and Cannot Be Read Easily
Procedure 10: VTM(Reverse)
To measure the VTM (Reverse) parameter: 1. Set Polarity to (-). 2. Repeat Procedure 8 to measure V TM(Reverse).
Procedure 3: IBO
To measure the IBO parameter, at the VBO point, measure the amount of device current just before the device reaches the breakover mode. The measured current at this point is the IBO value. Note: If IBO is less than 10 A, the current cannot readily be seen on the curve tracer.
Diacs
Diacs are voltage breakdown switches used to trigger-on triacs and non-sensitive SCRs in phase control circuits. Note: Diacs are bi-directional devices and can be connected in either direction. To connect the diac: 1. Connect one side of the diac to the Collector Terminal (C). 2. Connect other side of the diac to the Emitter Terminal (E). To begin testing, perform the following procedures.
Procedure 4: VBO(Voltage Breakover Symmetry)
To measure the V BO (Voltage Breakover Symmetry) parameter: 1. Measure positive and negative values of V BO as shown in Figure AN1006.26. 2. Subtract the absolute value of V BO(-) from V BO(+). The absolute value of the result is:
V BO = [ I +V BO I - I -V BO I ]
Procedure 1: Curve Tracer Setup
To set the curve tracer and begin testing: 1. Set Variable Collector Supply Voltage Range to 75 Max Peak Volts. (80 V on 370) 2. Set Horizontal knob to sufficient scale to allow viewing of trace at the required voltage level (10 V to 20 V/DIV depending on device being tested).
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AN1006
Application Notes
Model 370 Curve Tracer Procedure Notes
Because the curve tracer procedures in this application note are written for the Tektronix model 576 curve tracer, certain settings must be adjusted when using model 370. Variable Collector Supply Voltage Range and Power Dissipation controls have different scales than model 576. The following table shows the guidelines for setting Power Dissipation when using model 370. (Figure AN1006.27)
Model 576
If power dissipation is 0.1 W, If power dissipation is 0.5 W, If power dissipation is 2.2 W, If power dissipation is 10 W, If power dissipation is 50 W, If power dissipation is 220 W,
Although the maximum power setting on the model 370 curve tracer is 200 W, the maximum collector voltage available is only 400 V at 220 W. The following table shows the guidelines for adapting Collector Supply Voltage Range settings for model 370 curve tracer procedures:
Model 576
If voltage range is 15 V, If voltage range is 75 V, If voltage range is 350 V, If voltage range is 1500 V,
Model 370
set at 16 V. set at 80 V. set at 400 V. set at 2000 V.
Model 370
set at 0.08 W. set at 0.4 W. set at 2 W. set at 10 W. set at 50 W. set at 220 W.
The following table shows the guidelines for adapting terminal selector knob settings for model 370 curve tracer procedures:
Model 576 Model 370
If Step generator (base) is emitter grounded, then Base Step generator is emitter common. If Emitter grounded is open base, then Base open is emitter common.
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Application Notes
AN1006
PROGRAMMABLE CURVE TRACER
INTENSITY
HORIZONTAL VOLTAGE CONTROL
Note: All Voltage Settings Will Be Referenced to "Collector"
DISPLAY
SETUP
MEMORY
STEP GENERATOR
VERT/DIV CURSOR
VERTICAL CURRENT/DIV
HORIZONTAL VOLTS/DIV
POLARITY
STEP/OFFSET AMPLITUDE
STEP/OFFSET POLARITY STEP/OFFSET AMPLITUDE (AMPS/VOLTS)
COLLECTOR
HORZ/DIV CURSOR
CRT
PER STEP OFFSET
OFFSET
OFFSET
OR gm/DIV
POSITION
AUX SUPPLY
CURSOR GPIB PLOTTER MEASUREMENT
STEP FAMILY
AUX SIPPLY
COLLECTOR SUPPLY
VARIABLE COLLECTOR SUPPLY VOLTAGE RANGE
TERMINAL JACKS
CONFIGURATION
COLLECTOR SUPPLY
MAX PEAK VOLTS MAX PEAK POWER WATTS POLARITY
MAX PEAK POWER (POWER DISSIPATION)
C
C C SENSE C SENSE
MT2/ANODE
VARIABLE
GATE/TRIGGER
B E SENSE E E B SENSE B E SENSE B SENSE
VARIABLE COLLECTOR SUPPLY VOLTAGE
LEFT
RIGHT
BOTH
POWER
LEFT-RIGHT SELECTOR FOR TERMINAL JACKS
MT1/CATHODE
KELVIN TERMINALS USED WHEN MEASURING V TM OR V FM
TERMINAL SELECTOR
Figure AN1006.27 Tektronix Model 370 Curve Tracer
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AN1006
Application Notes
Model 577 Curve Tracer Procedure Notes
Because the curve tracer procedures in this application note are written for the Tektronix model 576 curve tracer, certain settings must be adjusted when using model 577. Model 576 curve tracer has separate controls for polarity (AC,+,-) and mode (Norm, DC, Leakage), whereas Model 577 has only a polarity control. The following table shows the guidelines for setting Collector Supply Polarity when using model 577. (Figure AN1006.28)
Model 576
If using Leakage mode along with polarity setting of +(NPN) and -(PNP), [vertical scale divided by 1,000], If using DC mode along with either +(NPN) or -(PNP) polarity, If using Norm mode along with either +(NPN) or -(PNP) polarity, If using Norm mode with AC polarity,
Model 577
set Collector Supply Polarity to either +DC or -DC, depending on polarity setting specified in the procedure. The vertical scale is read directly from the scale on the control knob. set Collector Supply Polarity to either +DC or -DC depending on polarity specified. set Collector Supply Polarity to either +(NPN) or -(PNP) per specified procedure. set Collector Supply Polarity to AC.
One difference between models 576 and 577 is the Step/Offset Polarity setting. The polarity is inverted when the button is depressed on the Model 576 curve tracer. The Model 577 is opposite the Step/Offset Polarity is "inverted" when the button is extended and "Normal" when the button is depressed. The Step/Offset Polarity is used only when measuring IGT and VGT of triacs and Quadracs in Quadrants l through lV. Also, the Variable Collector Supply Voltage Range and Power Dissipation controls have different scales than model 576. The following table shows the guidelines for setting Power Dissipation when using model 577.
Model 576
If power dissipation is 0.1 W, If power dissipation is 0.5 W, If power dissipation is 2.2 W, If power dissipation is 10 W, If power dissipation is 50 W, If power dissipation is 220 W,
Model 577
set at 0.15 W. set at 0.6 W. set at 2.3 W. set at 9 W. set at 30 W. set at 100 W.
Although the maximum power setting on model 576 curve tracer is 220 W (compared to 100 W for model 577), the maximum collector current available is approximately the same. This is due to the minimum voltage range on model 577 curve tracer being 6.5 V compared to 15 V for model 576. The following table shows the guidelines for adapting Collector Voltage Supply Range settings for model 577 curve tracer procedures:
Model 576
If voltage range is 15 V,
Model 577
set at either 6.5 V or 25 V, depending on parameter being tested. Set at 6.5 V when measuring VTM (to allow maximum collector current) and set at 25 V when measuring IGT and VGT. set at 100 V. set at 1600 V.
If voltage range is 75 V, If voltage range is 1500 V,
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Application Notes
AN1006
BRIGHTNESS
STORE
INTENSITY
CRT
FOCUS
Avoid extremely bright display Adjust for best focus
BEAM FINDER
VARIABLE COLLECTOR SUPPLY VOLTAGE RANGE VARIABLE COLLECTOR SUPPLY VOLTAGE
STEP FAMILY VARIABLE COLLECTOR% MAX PEAK VOLTS STEP/OFFSET AMPLIFIER
POWER
STEP GENERATOR SECTION NUMBER OF STEPS
MAX PEAK POWER (POWER DISSIPATION) Watch high power settings. Can damage device under test
POLARITY COLLECTOR SUPPLY POLARITY DISPLAY
OFFSET MULTI
STEP/OFFSET POLARITY
POSITION
Indicates Collector Supply Disabled
STEP RATE POSITION
HORIZONTAL VOLTAGE CONTROL Note: All Voltage Settings Will Be Referenced to "Collector"
COLLECTOR SUPPLY
TERMINAL JACKS
Terminal Selector C SENSE
MT2/ANODE
C
C SENSE
C
GATE/TRIGGER
B
B
MT1/CATHODE
E
E SENSE
E
E SENSE
Indicates Dangerous Voltages on Test jacks
VERTICAL (off)
LEFT-RIGHT SELECTOR FOR TERMINAL JACKS
LEFT
RIGHT
KELVIN TERMINALS USED WHEN MEASURING VTM OR VFM
VARIABLE VOLTAGE STEP GEN OUTPUT
VERTICAL CURRENT SUPPLY
GROUND
LOOPING COMPENSATION
VARIABLE OUTPUT
EXT BASE OR EMIT INPUT
Figure AN1006.28 Tektronix Model 577 Curve Tracer
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Notes
AN1007
7
Thyristors Used as AC Static Switches and Relays
would be 25 mA since Q 1 has a 25 mA maximum IGT rating. Additionally, no arcing of a current value greater than 25 mA when opening S 1 will occur when controlling an inductive load. It is important also to note that the triac Q1 is operating in Quadrants I and III, the more sensitive and most suitable gating modes for triacs. The voltage rating of S1 (mechanical switch or reed switch) must be equivalent to or greater than line voltage applied.
Introduction
Since the SCR and the triac are bistable devices, one of their broad areas of application is in the realm of signal and power switching. This application note describes circuits in which these thyristors are used to perform simple switching functions of a general type that might also be performed non-statically by various mechanical and electromechanical switches. In these applications, the thyristors are used to open or close a circuit completely, as opposed to applications in which they are used to control the magnitude of average voltage or energy being delivered to a load. These latter types of applications are described in detail in "Phase Control Using Thyristors" (AN1003).
Load RL R1 100 VRMS S1 Triac Control Device Reed Switch C1 0.1 F R2 100 For Inductive Loads
Static AC Switches
Normally Open Circuit
The circuit shown in Figure AN1007.1 provides random (anywhere in half-cycle), fast turn-on (<10 s) of AC power loads and is ideal for applications with a high-duty cycle. It eliminates completely the contact sticking, bounce, and wear associated with conventional electromechanical relays, contactors, and so on. As a substitute for control relays, thyristors can overcome the differential problem; that is, the spread in current or voltage between pickup and dropout because thyristors effectively drop out every half cycle. Also, providing resistor R1 is chosen correctly, the circuits are operable over a much wider voltage range than is a comparable relay. Resistor R 1 is provided to limit gate current (IGTM) peaks. Its resistance plus any contact resistance (RC) of the control device and load resistance (RL) should be just greater than the peak supply voltage divided by the peak gate current rating of the triac. If R 1 is set too high, the triacs may not trigger at the beginning of each cycle, and phase control of the load will result with consequent loss of load voltage and waveform distortion. For inductive loads, an RC snubber circuit, as shown in Figure AN1007.1, is required. However, a snubber circuit is not required when an alternistor is used. Figure AN1007.2 illustrates an analysis to better understand a typical static switch circuit. The circuit operation occurs when switch S1 is closed, since the triac Q1 will initially be in the blocking condition. Current flow will be through load R L, S1, R 1, and gate to MT1 junction of the thyristor. When this current reaches the required value of IGT, the MT2 to MT1 junctions will switch to the conduction state and the voltage from MT2 to MT1 will be VT. As the current approaches the zero crossing, the load current will fall below holding current turning the triac Q 1 device off until it is refired in the next half cycle. Figure AN1007.3 illustrates the voltage waveform appearing across the MT2 to MT1 terminals of Q1. Note that the maximum peak value of current which S1 will carry
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R1
2*V IGTM
(RL + RC) Where IGTM is Peak Gate Current Rating of Triac
Figure AN1007.1
Basic Triac Static Switch
Load RL Q1 S1 AC Voltage Input 120 V rms, 60 Hz VIN Q2008L4 MT2
+ I GT
R1
G
- I GT
V GT
MT1
Figure AN1007.2
Analysis of Static Switch
AN1007 - 1
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Application Notes
Normally Closed Circuit
120 V rms (170 V peak)
VP+
VT+ 1 V rms or 1.6 V peak MAX
VTVP-
With a few additional components, the thyristor can provide a normally closed static switch function. The critical design portion of this static switch is a clamping device to turn off/eliminate gate drive and maintain very low power dissipation through the clamping component plus have low by-pass leakage around the power thyristor device. In selecting the power thyristor for load requirements, gate sensitivity becomes critical to maintain low power requirements. Either sensitive SCRs or sensitive logic triacs must be considered, which limits the load in current capacity and type. However, this can be broader if an extra stage of circuitry for gating is permitted. Figure AN1007.4 illustrates an application using a normally closed circuit driving a sensitive SCR for a simple but precise temperature controller. The same basic principle could be applied to a water level controller for a motor or solenoid. Of course, SCR and diode selection would be changed depending on load current requirements.
1000 W Heater Load
Figure AN1007.3
Waveform Across Static Switch
A typical example would be in the application of this type circuit for the control of 5 A resistive load with 120 V rms input voltage. Choosing a value of 100 for R1 and assuming a typical value of 1 V for the gate to MT1 (VGT) voltage, we can solve for VP by the following: V P = IGT (R L + R 1) + V GT Note: RC is not included since it is negligible. V P = 0.025 (24 + 100) + 1.0 = 4.1 V Additionally the turn-on angle is = Sin -1 4.1 -------------------170V PK [ = 1.4]
CR1 S2010LS2 SCR1
CR2 120 V ac 60 CPS
CR3
CR4 R1 510 k
D2015L CR1--CR4
0.1 F
The power lost by the turn-on angle is essentially zero. The power dissipation in the gate resistor is very minute. A 100 , 0.25 W rated resistor may safely be used. The small turn-on angle also ensures that no appreciable RFI is generated. The relay circuit shown in Figure AN1007.1 and Figure AN1007.2 has several advantages in that it eliminates contact bounce, noise, and additional power consumption by an energizing coil and can carry an in-rush current of many times its steady state rating. The control device S 1 indicated can be either electrical or mechanical in nature. Light-dependent resistors and light- activated semiconductors, optocoupler, magnetic cores, and magnetic reed switches are all suitable control elements. Regardless of the switch type chosen, it must have a voltage rating equal to or greater than the peak line voltage applied. In particular, the use of hermetically sealed reed switches as control elements in combination with triacs offers many advantages. The reed switch can be actuated by passing DC current through a small coiled wire or by the proximity of a small magnet. In either case, complete electrical isolation exists between the control signal input, which may be derived from many sources, and the switched power output. Long life of the triac/reed switch combination is ensured by the minimal volt-ampere switching load placed on the reed switch by the triac triggering requirements. The thyristor ratings determine the amount of load power that can be switched.
Twist Leads to Minimize Pickup Hg in Glass Thermostat
Figure AN1007.4
Normally Closed Temperature Controller
A mercury-in-glass thermostat is an extremely sensitive measuring instrument, capable of sensing changes in temperature as small as 0.1 C. Its major limitation lies in its very low currenthandling capability for reliability and long life, and contact current should be held below 1 mA. In the circuit of Figure AN1007.4, the S2010LS2 SCR serves as both current amplifier for the Hg thermostat and as the main load switching element. With the thermostat open, the SCR will trigger each half cycle and deliver power to the heater load. When the thermostat closes, the SCR can no longer trigger and the heater shuts off. Maximum current through the thermostat in the closed position is less than 250 A rms. Figure AN1007.5 shows an all solid state, optocoupled, normally closed switch circuit. By using a low voltage SBS triggering device, this circuit can turn on with only a small delay in each half cycle and also keep gating power low. When the optocoupled transistor is turned on, the gate drive is removed with only a few milliamps of bypass current around the triac power device. Also, by use of the BS08D and 0.1 F, less sensitive triacs and alternistors can be used to control various types of high current loads.
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Application Notes
AN1007
Load
Q2008L4 Triac
51 k
120 V ac BS08D (4) IN4004 0.02 F
+
wave voltage as illustrated in Figure AN1007.2. The load resistance is also important, since it can also limit the amount of available triac gate current. A 100 gate resistor would be a better choice in most 120 V applications with loads greater than 200 W and optocouplers from Quality Technologies or Vishay with optocoupler output triacs that can handle 1.7 A PK (ITSM rating) for a few microseconds at the peak of the line. For loads less than 200 W, the resistor can be dropped to 22 . Remember that if the gate resistor is too large in value, the triac will not turn on at all or not turn on fully, which can cause excessive power dissipation in the gate resistor, causing it to burn out. Also, the voltage and dv/ dt rating of the optocoupler's output device must be equal to or greater than the voltage and dv/dt rating of the triac or alternistor it is driving. Figure AN1007.7 illustrates a circuit with a dv/dt snubber network included. This is a typical circuit presented by optocoupler manufacturers.
PS2502
Figure AN1007.5
Normally Closed Switch Circuit
ZL Rin 1 2 4 6 100 100 MT2
Hot
Optocoupled Driver Circuits
Random Turn-on, Normally Open
Many applications use optocouplers to drive thyristors. The combination of a good optocoupler and a triac or alternistor makes an excellent, inexpensive solid state relay. Application information provided by the optocoupler manufacturers is not always best for application of the power thyristor. Figure AN1007.6 shows a standard circuit for a resistive load.
Figure AN1007.7
Hot RL Rin 1 VCC 2 4 G MT1 Neutral Load Could Be in Either Leg 6 120 V 60 Hz
VCC
120 V 60 Hz
0.1 F C1
G
MT1 Neutral
Optocoupler Circuit for Inductive Loads (Triac or Alternistor)
This "T" circuit hinges around one capacitor to increase dv/dt capability to either the optocoupler output triac or the power triac. The sum of the two resistors then forms the triac gate resistor. Both resistors should then be standardized and lowered to 100 . Again, this sum resistance needs to be low, allowing as much gate current as possible without exceeding the instantaneous current rating of the opto output triac or triac gate junction. By having 100 for current limit in either direction from the capacitor, the optocoupler output triac and power triac can be protected against di/dt produced by the capacitor. Of course, it is most important that the capacitor be connected between proper terminals of triac. For example, if the capacitor and series resistor are accidentally connected between the gate and MT2, the triac will turn on from current produced by the capacitor, resulting in loss of control. For low current (mA) and/or highly inductive loads, it may be necessary to have a latching network (3.3 k + 0.047 F) connected directly across the power triac. The circuit shown in Figure AN1007.8 illustrates the additional latching network.
180 MT2
Figure AN1007.6
Optocoupled Circuit for Resistive Loads (Triac or Alternistor)
A common mistake in this circuit is to make the series gate resistor too large in value. A value of 180 is shown in a typical application circuit by optocoupler manufacturers. The 180 is based on limiting the current to 1 A peak at the peak of a 120 V line input. This is good for protection of the optocoupler output triac, as well as the gate of the power triac on a 120 V line; however, it must be lowered if a 24 V line is being controlled, or if the R L (resistive load) is 200 W or less. This resistor limits current for worst case turn-on at the peak line voltage, but it also sets turnon point (conduction angle) in the sine wave, since triac gate current is determined by this resistor and produced from the sine
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AN1007
Application Notes
Rin 1 Vcc 2
6
180
180 MT2 3.3 k
Rin
1 6
Load could be here instead of lower location 180 for 120 V ac 360 for 240 V ac MT2 100 G
4
5
240 V ac
Input
5 2
0.1 F
4 G MT1
Hot
MT1 120/240 V ac
3
0.047 F
Load
3
Triac or Alternistor
0.1f Neutral Load
Figure AN1007.8
Optocoupler Circuit for Lower Current Inductive Loads (Triac or Alternistor)
Figure AN1007.10
Random Turn-on Triac Driver
In this circuit, the series gate resistors are increased to 180 each, since a 240 V line is applied. Note that the load is placed on the MT1 side of the power triac to illustrate that load placement is not important for the circuit to function properly. Also note that with standard U.S. residential 240 V home wiring, both sides of the line are hot with respect to ground (no neutral). Therefore, for some 240 V line applications, it will be necessary to have a triac switch circuit in both sides of the 240 V line input. If an application requires back-to-back SCRs instead of a triac or alternistor, the circuit shown in Figure AN1007.9 may be used.
Select the triac for the voltage of the line being used, the current through the load, and the type of load. Since the peak voltage of a 120 V ac line is 170 V, you would choose a 200 V (MIN) device. If the application is used in an electrically noisy industrial environment, a 400 V device should be used. If the line voltage to be controlled is 240 V ac with a peak voltage of 340 V, then use at least a 400 V rated part or 600 V for more design margin. Selection of the voltage rating of the opto-driver must be the same or higher than the rating of the power triac. In electrically noisy industrial locations, the dv/dt rating of the opto-driver and the triac must be considered. The RMS current through the load and main terminals of the triac should be approximately 70% of the maximum rating of the device. However, a 40 A triac should not be chosen to control a 1 A load due to low latching and holding current requirements. Remember that the case temperature of the triac must be maintained at or below the current versus temperature curve specified on its data sheet. As with all semiconductors the lower the case temperature the better the reliability. Opto-driven gates normally do not use a sensitive gate triac. The opto-driver can supply up to 1 A gate pulses and less sensitive gate triacs have better dv/dt capability. If the load is resistive, it is acceptable to use a standard triac. However, if the load is a heavy inductive type, then an alternistor triac, or back-to-back SCRs as shown in Figure AN1007.9, is recommended. A series RC snubber network may or may not be necessary when using an alternistor triac. Normally a snubber network is not needed when using an alternistor because of its high dv/dt and dv/dt(c) capabilities. However, latching network as described in Figure AN1007.8 may be needed for low current load variations.
1 Vcc Rin 2
6 5 4
G K
NSSCR
100 A
120 V ac
NS-SCR
A 100
G
K
3
0.1F
Load
Figure AN1007.9
Optocoupled Circuit for Heavy-duty Inductive Loads
All application comments and recommendations for optocoupled switches apply to this circuit. However, the snubber network can be applied only across the SCRs as shown in the illustration. The optocoupler should be chosen for best noise immunity. Also, the voltage rating of the optocoupler output triac must be equal to or greater than the voltage rating of SCRs.
Summary of Random Turn-on Relays
As shown in Figure AN1007.10, if the voltage across the load is to be phase controlled, the input control circuitry must be synchronized to the line frequency and the trigger pulses delayed from zero crossing every half cycle. If the series gate resistor is chosen to limit the peak current through the opto-driver to less than 1 A, then on a 120 V ac line the peak voltage is 170 V; therefore, the resistor is 180 . On a 240 V ac line the peak voltage is 340 V; therefore, the resistor should be 360 . These gate pulses are only as long as the device takes to turn on (typically, 5 s to 6 s); therefore, 0.25 W resistor is adequate.
Zero Crossing Turn-on, Normally Open Relay Circuits
When a power circuit is mechanically switched on and off mechanically, generated high-frequency components are generated that can cause interference problems such as RFI. When power is initially applied, a step function of voltage is applied to the circuit which causes a shock excitation. Random switch opening stops current off, again generating high frequencies. In addition, abrupt current interruption in an inductive circuit can lead to high induced-voltage transients. The latching characteristics of thyristors are ideal for eliminating interference problems due to current interruption since these devices can only turn off when the on-state current approaches zero, regardless of load power factor. On the other hand, interference-free turn-on with thyristors requires special trigger circuits. It has been proven experimen-
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Application Notes
AN1007
tally that general purpose AC circuits will generate minimum electromagnetic interference (EMI) if energized at zero voltage. The ideal AC circuit switch, therefore, consists of a contact which closes at the instant when voltage across it is zero and opens at the instant when current through it is zero. This has become known as "zero-voltage switching." For applications that require synchronized zero-crossing turn-on, the illustration in Figure AN1007.11 shows a circuit which incorporates an optocoupler with a built-in zero-crossing detector
Load could be here instead of lower location Rin Input
2 1 6
22 MT2 100 G MT1 120/240 V ac Triac or Alternistor 0.1f Neutral Load Hot
5
3
Zero Crossing Circuit
4
Rin Vcc
1
6 5
22 Hot MT2 G MT1 100 120 V ac
Non-sensitive Gate SCRs Load
Figure AN1007.12
Zero Crossing Turn-on Opto Triac Driver
2 4 3 Zero Crossing Circuit
0.1 F Neutral Load
Rin 1 Input 2
Zero Crossing Circuit
100 6 5 4 22 A G K G A K 120/240 V ac
Figure AN1007.11
Optocoupled Circuit with Zero-crossing Turn-on (Triac or Alternistor)
3
0.1F
Also, this circuit includes a dv/dt snubber network connected across the power triac. This typical circuit illustrates switching the hot line; however, the load may be connected to either the hot or neutral line. Also, note that the series gate resistor is low in value (22 ), which is possible on a 120 V line and above, since zerocrossing turn-on is ensured in any initial half cycle.
Load could be here instead of lower location
Figure AN1007.13
Zero Crossing Turn-on Non-sensitive SCR Driver
Sensitive Gate SCRs
Load 1K
Summary of Zero Crossing Turn-on Circuits
Zero voltage crossing turn-on opto-drivers are designed to limit turn-on voltage to less than 20 V. This reduces the amount of RFI and EMI generated when the thyristor switches on. Because of this zero turn-on, these devices cannot be used to phase control loads. Therefore, speed control of a motor and dimming of a lamp cannot be accomplished with zero turn-on opto-couplers. Since the voltage is limited to 20 V or less, the series gate resistor that limits the gate drive current has to be much lower with a zero crossing opto-driver. With typical inhibit voltage of 5 V, an alternistor triac gate could require a 160 mA at -30 C (5 V/ 0.16 A = 31 gate resistor). If the load has a high inrush current, then drive the gate of the triac with as much current as reliably possible but stay under the ITSM rating of the opto-driver. By using 22 for the gate resistor, a current of at least 227 mA is supplied with only 5 V, but limited to 909 mA if the voltage goes to 20 V. As shown in Figure AN1007.12, Figure AN1007.13, and Figure AN1007.14, a 22 gate resistor is a good choice for various zero crossing controllers.
Rin 1 Input 2 3
Zero Crossing Circuit
6 5 4 22 1K
*
G K AG A K
100 120/240 V ac
*
0.1 F
* Gate Diodes to Have
Same PIV as SCRs
Load could be here instead of lower location
Figure AN1007.14
Zero Crossing Turn-on Opto-sensitive Gate SCR Driver
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AN1007
Application Notes
Time Delay Relay Circuit
By combining a 555 timer IC with a triac, various time delays of several seconds can be achieved for delayed activation of solid state relays or switches. Figure AN1007.15 shows a solid state timer delay relay using a sensitive gate triac and a 555 timer IC. The 555 timer precisely controls time delay of operation using an external resistor and capacitor, as illustrated by the resistor and capacitor combination curves. (Figure AN1007.16)
IR Motion Control
An example of a more complex triac switch is an infrared (IR) motion detector controller circuit. Some applications for this circuit are alarm systems, automatic lighting, and auto doorbells. Figure AN1007.17 shows an easy- to-implement automatic lighting system using an infrared motion detector control circuit. A commercially available LSI circuit HT761XB, from Holtek, integrates most of the analog functions. This LSI chip, U2, contains the op amps, comparators, zero crossing detection, oscillators, and a triac output trigger. An external RC that is connected to the OSCD pin determines the output trigger pulse width. (Holtek Semiconductor Inc. is located at No.3, Creation Road II, ScienceBased Industrial Park, Hsinchu, Taiwan, R.O.C.) Device U1 provides the infrared sensing. Device R13 is a photo sensor that serves to prevent inadvertent triggering under daylight or other high light conditions. Choosing the right triac depends on the load characteristics. For example, an incandescent lamp operating at 110 V requires a 200 V, 8 A triac. This gives sufficient margin to allow for the high current state during lamp burn out. U2 provides a minimum output triac negative gate trigger current of 40 mA, thus operating in QII & QIII. This meets the requirements of a 25 mA gate triac. Teccor also offers alternistor triacs for inductive load conditions. This circuit has three operating modes (ON, AUTO, OFF), which can be set through the mode pin. While the LSI chip is working in the auto mode, the user can override it and switch to the test mode, or manual on mode, or return to the auto mode by switching the power switch. More information on this circuit, such as mask options for the infrared trigger pulse and flash options, are available in the Holtek HT761X General Purpose PIR Controller specifications.
1K LOAD MT2 10 K 4 2 5 0.1 F 555 1 0.01 F 1N4003 3.5 K 250 V _ + 10 F 3 8 6 7 R 10 M C 1 F G MT1 120 V 60 Hz
-10 V 1N4740
Figure AN1007.15
555 timer circuit with 10 second delay
100
10
C, (CAPACITANCE) (F)
K
K
K
10 0
10
M
0.1
0.01
0.001 10ms
100ms
1ms
10ms
100ms
1.0
10
10
1
1
M
1.0
100
td TIME DELAY (s)
Figure AN1007.16
Resistor (R) and capacitor (C) combination curves
C7 3900pF C3 100pF AC+ 110 R6 1M U2 1 2 SW1 ON/OFF OVERRIDE LP1 Lamp 60 to 600 Watt C8 0.1F D3 1N4002 R9 1M R7 1M R8 569K 3 4 5 6 7 8 R2 2.4M D5 1N4002 C10 0.33F 350V Q1 TRIAC Q2008L4 D4 1N4002 SW2 Mode ON OFF AUTO VSS TRIAC OSCD OSCS ZC CDS MODE VDD OP20 OP2N OP2P OP10 OP1N OP1P RSTB VEE 16 15 14 13 12 11 10 9 C12 22F R12 22K C2 0.02F R4 1M C5 0.02F C6 22F R5 22K
R9 1M R14 68W 2W
HT761XB -16 DIP/SOP
C13 0.02F R3
*R10
C4 100F
56K 3 G D 1 2 S U1 PIR SD622 (Nippon Ceramic)
C9 10F
D2 1N4002 C11 330F
D1 12V
R13 CDS C1 100F
AC
Figure AN1007.17
I R motion control circuit
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AN1008
8
Explanation of Maximum Ratings and Characteristics for Thyristors
VDRM: Peak Repetitive Forward (Off-state) Voltage
SCR The peak repetitive forward (off-state) voltage rating (Figure AN1008.1) refers to the maximum peak forward voltage which may be applied continuously to the main terminals (anode, cathode) of an SCR. This rating represents the maximum voltage the SCR should be required to block in the forward direction. The SCR may or may not go into conduction at voltages above the VDRM rating. This rating is specified for an open-gate condition and gate resistance termination. A positive gate bias should be avoided since it will reduce the forward-voltage blocking capability. The peak repetitive forward (off-state) voltage rating applies for case temperatures up to the maximum rated junction temperature. Triac The peak repetitive off-state voltage rating should not be surpassed on a typical, non-transient, working basis. (Figure AN1008.2) VDRM should not be exceeded even instantaneously. This rating applies for either positive or negative bias on main terminal 2 at the rated junction temperature. This voltage is less than the minimum breakover voltage so that breakover will not occur during operation. Leakage current is controlled at this voltage so that the temperature rise due to leakage power does not contribute significantly to the total temperature rise at rated current.
+I
+I
Voltage Drop (VT) at Specified Current (iT)
Introduction
Data sheets for SCRs and triacs give vital information regarding maximum ratings and characteristics of thyristors. If the maximum ratings of the thyristors are surpassed, possible irreversible damage may occur. The characteristics describe various pertinent device parameters which are guaranteed as either minimums or maximums. Some of these characteristics relate to the ratings but are not ratings in themselves. The characteristic does not define what the circuit must provide or be restricted to, but defines the device characteristic. For example, a minimum value is indicated for the dv/dt because this value depicts the guaranteed worst-case limit for all devices of the specific type. This minimum dv/dt value represents the maximum limit that the circuit should allow.
Maximum Ratings
VRRM: Peak Repetitive Reverse Voltage -- SCR
The peak repetitive reverse voltage rating is the maximum peak reverse voltage that may be continuously applied to the main terminals (anode, cathode) of an SCR. (Figure AN1008.1) An opengate condition and gate resistance termination is designated for this rating. An increased reverse leakage can result due to a positive gate bias during the reverse voltage exposure time of the SCR. The repetitive peak reverse voltage rating relates to case temperatures up to the maximum rated junction temperature.
Voltage Drop (VT) at Specified Current (iT)
Latching Current (IL)
Latching Current (IL)
Reverse Leakage Current - (IRRM) at Specified VRRM
Off - State Leakage Current - (IDRM) at Specified VDRM
Minimum Holding Current (IH)
Off-state Leakage Current - (IDRM) at Specified VDRM Minimum Holding Current (IH)
-V
+V
Specified Minimum Off-state Blocking Voltage (VDRM)
+V
-V
Specified Minimum Reverse Blocking Voltage (VRRM)
Specified Minimum Off - State Blocking Voltage (VDRM)
Reverse Breakdown Voltage
-I
Forward Breakover Voltage
-I
Breakover Voltage
Figure AN1008.2
V-I Characteristics of Triac Device
Figure AN1008.1
V-I Characteristics of SCR Device
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AN1008
Application Notes
IT: Current Rating
SCR For RMS and average currents, the restricting factor is usually confined so that the power dissipated during the on state and as a result of the junction-to-case thermal resistance will not produce a junction temperature in excess of the maximum junction temperature rating. Power dissipation is changed to RMS and average current ratings for a 60 Hz sine wave with a 180 conduction angle. The average current for conduction angles less than 180 is derated because of the higher RMS current connected with high peak currents. The DC current rating is higher than the average value for 180 conduction since no RMS component is present. The dissipation for non-sinusoidal waveshapes can be determined in several ways. Graphically plotting instantaneous dissipation as a function of time is one method. The total maximum allowable power dissipation (PD) may be determined using the following equation for temperature rise: T J ( MAX ) - T C P D = ---------------------------------R JC where TJ(max) is the maximum rated junction temperature (at zero rated current), T C is the actual operating case temperature, and RJC is the published junction-to-case thermal resistance. Transient thermal resistance curves are required for short interval pulses. Triac The limiting factor for RMS current is determined by multiplying power dissipation by thermal resistance. The resulting current value will ensure an operating junction temperature within maximum value. For convenience, dissipation is converted to RMS current at a 360 conduction angle. The same RMS current can be used at a conduction angle of less than 360. For information on non-sinusoidal waveshapes and a discussion of dissipation, refer to the preceding description of SCR current rating.
Peak Surge (Non-repetitive) On-state Current (I TSM ) - Amps
1000 SUPPLY FREQUENCY: 60 Hz Sinusoidal LOAD: Resistive RMS ON-STATE CURRENT [ I T(RMS)]: Maximum Rated Value at Specified Case Temperature Notes: 1) Gate control may be lost during and immediately following surge current interval. 2) Overload may not be repeated until junction temperature has returned to steady-state rated value.
400 300 250
40 A TO-2 1
8
150 120 100 80 60 50 40 30 20
25 A T0-2
20
15 A T O -2
20
10 1 10 100 1000
Surge Current Duration - Full Cycles
Figure AN1008.3
Peak Surge Current versus Surge Current Duration
ITM: Peak Repetitive On-state Current -- SCR and Triac
The ITM rating specifies the maximum peak current that may be applied to the device during brief pulses. When the device operates under these circumstances, blocking capability is maintained. The minimum pulse duration and shape are defined and control the applied di/dt. The operating voltage, the duty factor, the case temperature, and the gate waveform are also defined. This rating must be followed when high repetitive peak currents are employed, such as in pulse modulators, capacitive-discharge circuits, and other applications where snubbers are required.
di/dt: Rate-of-change of On-state Current -- SCR and Triac
The di/dt rating specifies the maximum rate-of-rise of current through a thyristor device during turn-on. The value of principal voltage prior to turn-on and the magnitude and rise time of the gate trigger waveform during turn-on are among the conditions under which the rating applies. If the rate-of-change of current (di/dt) exceeds this maximum value, or if turn-on with high di/dt during minimum gate drive occurs (such as dv/dt or overvoltage events), then localized heating may cause device degradation. During the first few microseconds of initial turn-on, the effect of di/dt is more pronounced. The di/dt capability of the thyristor is greatly increased as soon as the total area of the pellet is in full conduction. The di/dt effects that can occur as a result of voltage or transient turn-on (non-gated) is not related to this rating. The di/dt rating is specified for maximum junction temperature. As shown in Figure AN1008.4, the di/dt of a surge current can be calculated by means of the following equation.
ITSM: Peak Surge (Non-repetitive) On-state Current -- SCR and Triac
The peak surge current is the maximum peak current that may be applied to the device for one full cycle of conduction without device degradation. The maximum peak current is usually specified as sinusoidal at 50 Hz or 60 Hz. This rating applies when the device is conducting rated current before the surge and, thus, with the junction temperature at rated values before the surge. The junction temperature will surpass the rated operating temperature during the surge, and the blocking capacity may be decreased until the device reverts to thermal equilibrium. The surge-current curve in Figure AN1008.3 illustrates the peak current that may be applied as a function of surge duration. This surge curve is not intended to depict an exponential current decay as a function of applied overload. Instead, the peak current shown for a given number of cycles is the maximum peak surge permitted for that time period. The current must be derated so that the peak junction temperature during the surge overload does not exceed maximum rated junction temperature if blocking is to be retained after a surge.
( I TM ) di ---- = ----------------t dt
As an example, surge current of 400 A at 60 Hz has a di/dt of 400/8.3 or 151.4 A/ms.
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Application Notes
AN1008
IDRM: Peak Repetitive Off-state (Blocking) Current
I di/dt ITM
t = 8.3 ms for 60 Hz 10 ms for 50 Hz
SCR IDRM is the maximum leakage current permitted through the SCR when the device is forward biased with rated positive voltage on the anode (DC or instantaneous) at rated junction temperature and with the gate open or gate resistance termination. A 1000 resistor connected between gate and cathode is required on all sensitive SCRs. Leakage current decreases with decreasing junction temperatures. Effects of the off-state leakage currents on the load and other circuitry must be considered for each circuit application. Leakage currents can usually be ignored in applications that control high power. Triac The description of peak off-state (blocking/leakage) current for the triac is the same as for the SCR except that it applies with either positive or negative bias on main terminal 2. (Figure AN1008.2)
di = dt
(ITM) t
0
t
Time
Figure AN1008.4
Relationship of Maximum Current Rating to Time
I2t Rating -- SCR and Triac
The rating gives an indication of the energy-absorbing capability of the thyristor device during surge-overload conditions. The rating is the product of the square of the RMS current (IRMS)2 that flows through the device and the time during which the current is present and is expressed in A 2s. This rating is given for fuse selection purposes. It is important that the I2t rating of the fuse is less than that of the thyristor device. Without proper fuse or current limit, overload or surge current will permanently damage the device due to excessive junction heating. I 2t
IRRM: Peak Repetitive Reverse Current -- SCR
This characteristic is essentially the same as the peak forward off-state (blocking/leakage) current except negative voltage is applied to the anode (reverse biased).
PG: Gate Power Dissipation -- SCR and Triac
Gate power dissipation ratings define both the peak power (P GM) forward or reverse and the average power (P G(AV)) that may be applied to the gate. Damage to the gate can occur if these ratings are not observed. The width of the applied gate pulses must be considered in calculating the voltage and current allowed since the peak power allowed is a function of time. The peak power that results from a given signal source relies on the gate characteristics of the specific unit. The average power resulting from high peak powers must not exceed the average-power rating.
VTM: Peak On-State Voltage -- SCR and Triac
The instantaneous on-state voltage (forward drop) is the principal voltage at a specified instantaneous current and case temperature when the thyristor is in the conducting state. To prevent heating of the junction, this characteristic is measured with a short current pulse. The current pulse should be at least 100 s duration to ensure the device is in full conduction. The forward-drop characteristic determines the on-state dissipation. See Figure AN1008.5, and refer to "IT: Current Rating" on page AN1008-2.
TS, TJ: Temperature Range -- SCR and Triac
The maximum storage temperature (TS) is greater than the maximum operating temperature (actually maximum junction temperature). Maximum storage temperature is restricted by material limits defined not so much by the silicon but by peripheral materials such as solders used on the chip/die and lead attachments as well as the encapsulating epoxy. The forward and off-state blocking capability of the device determines the maximum junction (T J) temperature. Maximum blocking voltage and leakage current ratings are established at elevated temperatures near maximum junction temperature; therefore, operation in excess of these limits may result in unreliable operation of the thyristor.
Positive or Negative Instantaneous On-state Current (iT) - Amps
90 80 70 60 50 40 30 20 10 15 and 25 A TO-220 0 0 0.6 0.8 1.0 1.2 1.4 1.6 1.8
TC = 25 C
40 A TO-218
Characteristics
VBO: Instantaneous Breakover Voltage -- SCR and Triac
Breakover voltage is the voltage at which a device turns on (switches to on state by voltage breakover). (Figure AN1008.1) This value applies for open-gate or gate-resistance termination. Positive gate bias lowers the breakover voltage. Breakover is temperature sensitive and will occur at a higher voltage if the junction temperature is kept below maximum T J value. If SCRs and triacs are turned on as a result of an excess of breakover voltage, instantaneous power dissipations may be produced that can damage the chip or die.
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Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Figure AN1008.5
On-state Current versus On-state Voltage (Typical)
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AN1008
Application Notes
IGT: DC Gate Trigger Current
SCR IGT is the minimum DC gate current required to cause the thyristor to switch from the non-conducting to the conducting state for a specified load voltage and current as well as case temperature. The characteristic curve illustrated in Figure AN1008.6 shows that trigger current is temperature dependent. The thyristor becomes less sensitive (requires more gate current) with decreasing junction temperatures. The gate current should be increased by a factor of two to five times the minimum threshold DC trigger current for best operation. Where fast turn-on is demanded and high di/dt is present or low temperatures are expected, the gate pulse may be 10 times the minimum IGT, plus it must be fast-rising and of sufficient duration in order to properly turn on the thyristor.
4.0
VGT: DC Gate Trigger Voltage
SCR VGT is the DC gate-cathode voltage that is present just prior to triggering when the gate current equals the DC trigger current. As shown in the characteristic curve in Figure AN1008.8, the gate trigger voltage is higher at lower temperatures. The gate-cathode voltage drop can be higher than the DC trigger level if the gate is driven by a current higher than the trigger current. Triac The difference in VGT for the SCR and the triac is that the triac can be fired in four possible modes. The threshold trigger voltage can be slightly different, depending on which of the four operating modes is actually used.
2.0
3.0
V GT
V GT (T C = 25 C)
I GT (T C = 25 C)
1.5
I GT
2.0
1.0
Ratio of
1.0
Ratio of
.5
0 -65 -40 -15 +25 +65 Case Temperature (T C ) - C +125
0 -65 -40 -15 +25 +65 +125 Case Temperature (T C ) - C
Figure AN1008.6
Normalized DC Gate Trigger Current for All Quadrants versus Case Temperature
Figure AN1008.8
Triac The description for the SCR applies as well to the triac with the addition that the triac can be fired in four possible modes (Figure AN1008.7): Quadrant Quadrant Quadrant Quadrant I (main terminal 2 positive, gate positive) II (main terminal 2 positive, gate negative) III (main terminal 2 negative, gate negative) IV (main terminal 2 negative, gate positive)
ALL POLARITIES ARE REFERENCED TO MT1 MT2 POSITIVE (Positive Half Cycle)
Normalized DC Gate Trigger Voltage for All Quadrants versus Case Temperature
IL: Latching Current
SCR Latching current is the DC anode current above which the gate signal can be withdrawn and the device stays on. It is related to, has the same temperature dependence as, and is somewhat greater than the DC gate trigger current. (Figure AN1008.1 and Figure AN1008.2) Latching current is at least equal to or much greater than the holding current, depending on the thyristor type. Latching current is greater for fast-rise-time anode currents since not all of the chip/die is in conduction. It is this dynamic latching current that determines whether a device will stay on when the gate signal is replaced with very short gate pulses. The dynamic latching current varies with the magnitude of the gate drive current and pulse duration. In some circuits, the anode current may oscillate and drop back below the holding level or may even go negative; hence, the unit may turn off and not latch if the gate signal is removed too quickly. Triac The description of this characteristic for the triac is the same as for the SCR, with the addition that the triac can be latched on in four possible modes (quadrants). Also, the required latching is significantly different depending on which gating quadrants are used. Figure AN1008.9 illustrates typical latching current requirements for the four possible quadrants of operation.
MT2
(-)
+
MT2
IGT GATE MT1
(+)
IGT GATE MT1
IGT
(-)
REF MT2 IGT GATE MT1 REF
QII QI QIII QIV
(+)
REF
+
MT2 IGT GATE MT1 REF
IGT
MT2 NEGATIVE (Negative Half Cycle)
-
NOTE: Alternistors will not operate in Q IV
Figure AN1008.7
Definition of Operating Quadrants
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Application Notes
AN1008
dv/dt, Static: Critical Rate-of-rise of Off-state Voltage -- SCR and Triac
7.0
6.0
5.0
II
I L -- mA
4.0
3.0
2.0 I 1.0 III
IV
Static dv/dt is the minimum rate-of-rise of off-state voltage that a device will hold off, with gate open, without turning on. Figure AN1008.11 illustrates the exponential definition. This value will be reduced by a positive gate signal. This characteristic is temperature-dependent and is lowest at the maximum-rated junction temperature. Therefore, the characteristic is determined at rated junction temperature and at rated forward off-state voltage which is also a worst-case situation. Line or other transients which might be applied to the thyristor in the off state must be reduced, so that neither the rate-ofrise nor the peak voltage are above specifications if false firing is to be prevented. Turn-on as result of dv/dt is non-destructive as long as the follow current remains within current ratings of the device being used.
Critical dv/dt
0 1.0 2.0 3.0 4.0 5.0 6.0 I GT -- mA
Figure AN1008.9
Typical Triac Latching (I L) Requirements for Four Quadrants versus Gate Current (IGT)
VD 63% of V D
IH: Holding Current -- SCR and Triac
The holding current is the DC principal on-state current below which the device will not stay in regeneration/on state after latching and gate signal is removed. This current is equal to or lower in value than the latching current (Figure AN1008.1 and Figure AN1008.2) and is related to and has the same temperature dependence as the DC gate trigger current shown in Figure AN1008.10. Both minimum and maximum holding current may be important. If the device is to stay in conduction at low-anode currents, the maximum holding current of a device for a given circuit must be considered. The minimum holding current of a device must be considered if the device is expected to turn off at a low DC anode current. Note that the low DC principal current condition is a DC turn-off mode, and that an initial on-state current (latching current) is required to ensure that the thyristor has been fully turned on prior to a holding current measurement.
4.0
0 t VD dv = 0.63 dt t t = RC
Figure AN1008.11
Exponential Rate-of-rise of Off-state Voltage Defining dv/dt
dv/dt, Commutating: Critical Rate-of-rise of Commutation Voltage -- Triac
Commutating dv/dt is the rate-of-rise of voltage across the main terminals that a triac can support (block without switching back on) when commutating from the on state in one half cycle to the off state in the opposite half cycle. This parameter is specified at maximum rated case temperature (equal to T J) since it is temperature-dependent. It is also dependent on current (commutating di/dt) and peak reapplied voltage (line voltage) and is specified at rated current and voltage. All devices are guaranteed to commutate rated current with a resistive load at 50 Hz to 60 Hz. Commutation of rated current is not guaranteed at higher frequencies, and no direct relationship can be made with regard to current/ temperature derating for higher-frequency operation. With inductive loading, when the voltage is out of phase with the load current, a voltage stress (dv/dt) occurs across the main terminals of the triac during the zero-current crossing. (Figure AN1008.12) A snubber (series RC across the triac) should be used with inductive loads to decrease the applied dv/dt to an amount below the minimum value which the triac can be guaranteed to commutate off each half cycle.
IH I H (T C = 25 C)
3.0
INITIAL ON-STATE CURRENT = 400 mA dc
2.0
Ratio of
1.0
0 -65
-40
-15
+25
+65
+125
Case Temperature (T C ) - C
Figure AN1008.10 Normalized DC Holding Current versus Case Temperature
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AN1008
Application Notes
Commutating dv/dt is specified for a half sinewave current at 60 Hz which fixes the di/dt of the commutating current. The commutating di/dt for 50 Hz is approximately 20% lower while IRMS rating remains the same. (Figure AN1008.4)
EM
ESOURCE
tq: Circuit-commutated Turn-off Time -- SCR
The circuit-commutated turn-off time of the device is the time during which the circuit provides reverse bias to the device (negative anode) to commutate it off. The turn-off time occurs between the time when the anode current goes negative and when the anode positive voltage may be reapplied. (Figure AN1008.14) Turn-off time is a function of many parameters and very dependent on temperature and gate bias during the turn-off interval. Turn-off time is lengthened for higher temperature so a high junction temperature is specified. The gate is open during the turn-off interval. Positive bias on the gate will lengthen the turn-off time; negative bias on the gate will shorten it.
TIME
IG
di/dt IT (di/dt) C
ITRM
ITM 50% ITM 50% IRM iR Reverse Current
di/dt
ID Off-State Leakage
Voltage across Triac 10% 63% VDRM (dv/dt) C
trr tq
VT VD
Off-State Voltage
dv/dt
Figure AN1008.12
Waveshapes of Commutating dv/dt and Associated Conditions Figure AN1008.14
t1
tgt: Gate-controlled Turn-on Time -- SCR and Triac
The tgt is the time interval between the application of a gate pulse and the on-state current reaching 90% of its steady-state value. (Figure AN1008.13) As would be expected, turn-on time is a function of gate drive. Shorter turn-on times occur for increased gate drives. This turn-on time is actually only valid for resistive loading. For example, inductive loading would restrict the rate-ofrise of anode current. For this reason, this parameter does not indicate the time that must be allowed for the device to stay on if the gate signal is removed. (Refer to the description of "IL: Latching Current" on page AN1008-4.) However, if the load was resistive and equal to the rated load current value, the device definitely would be operating at a current above the dynamic latching current in the turn-on time interval since current through the device is at 90% of its peak value during this interval.
Waveshapes of tq Rating Test and Associated Conditions
RJC, RJA: Thermal Resistance (Junction-to-case, Junction-to-ambient) -- SCR and Triac
The thermal-resistance characteristic defines the steady-state temperature difference between two points at a given rate of heat-energy transfer (dissipation) between the points. The thermal-resistance system is an analog to an electrical circuit where thermal resistance is equivalent to electrical resistance, temperature difference is equivalent to voltage difference, and rate of heat-energy transfer (dissipation) is equivalent to current. Dissipation is represented by a constant current generator since generated heat must flow (steady-state) no matter what the resistance in its path. Junction-to-case thermal resistance establishes the maximum case temperature at maximum rated steadystate current. The case temperature must be held to the maximum at maximum ambient temperature when the device is operating at rated current. Junction-to-ambient thermal resistance is established at a lower steady-state current, where the device is in free air with only the external heat sinking offered by the device package itself. For RJA, power dissipation is limited by what the device package can dissipate in free air without any additional heat sink: TJ - TC RJC = -------------------P ( AV )
90%
Off-state Voltage 10%
On-state Current
90%
10% Delay Time Gate Trigger Pulse 50% 10% Gate Pulse Width
Turn-on Time
Rise Time
50%
TJ - TA RJA = -------------------P ( AV )
Figure AN1008.13
Waveshapes for Turn-on Time and Associated Conditions
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AN1009
9
Miscellaneous Design Tips and Facts
dv/dt Definitions
The rate-of-rise of voltage (dv/dt) of an exponential waveform is 63% of peak voltage (excluding any overshoots) divided by the time at 63% minus 10% peak voltage. (Figure AN1009.2) Exponential dv/dt = 0.63 * [ V PK ] = ( t 2 - t 1 ) Resistor Capacitor circuit t = RC = ( t 2 - t ) 1 Resistor Capacitor circuit 4 * RC = ( t 3 - t 2 )
(Peak Value)
Introduction
This application note presents design tips and facts on the following topics: * * * * * * * Relationship of IAV, IRMS, and IPK dv/dt Definitions Examples of gate terminations Curves for Average Current at Various Conduction Angles Double-exponential Impulse Waveform Failure Modes of Thyristor Characteristics Formulas for Phase Control Circuits
100%
Relationship of IAV, IRMS, and IPK
Since a single rectifier or SCR passes current in one direction only, it conducts for only half of each cycle of an AC sinewave. The average current (IAV) then becomes half of the value determined for full-cycle conduction, and the RMS current (IRMS) is equal to the square root of half the mean-square value for fullcycle conduction or half the peak current (IPK). In terms of halfcycle sinewave conduction (as in a single-phase half-wave circuit), the relationships of the rectifier currents can be shown as follows: IPK = IAV = 3.14 IAV IAV = (1/) IPK = 0.32 IPK IPK = 2 IRMS IRMS = 0.5 IPK IAV = (2/) IRMS = 0.64 IRMS IRMS = (/2) IAV = 1.57 IAV When two identically rated SCRs are connected inverse parallel for full-wave operation, as shown in Figure AN1009.1, they can handle 1.41 times the RMS current rating of either single SCR. Therefore, the RMS value of two half sinewave current pulses in one cycle is 2 times the RMS value of one such pulse per cycle.
Percent of Voltage
63%
Numerical dv/dt 10% 0% t0 t1 t2 Time t3
Figure AN1009.2
Exponential dv/dt Waveform
The rate-of-rise of voltage (dv/dt) of a linear waveform is 80% of peak voltage (excluding any overshoots) divided by the time at 90% minus 10% peak voltage. (Figure AN1009.3) Linear dv/dt = 0.8 * [ V PK ] = ( t 2 - t ) 1 Linear dv/dt = [ 0.9 * V PK - 0.1 * V PK ] = ( t 2 - t ) 1
90%
Percent of Voltage
10% 0% t0 t1 t2 Time
Figure AN1009.1
SCR Anti-parallel Circuit
Figure AN1009.3
Linear dv/dt Waveform
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AN1009
Application Notes
Examples of Gate Terminations
Primary Purpose (1) Increase dv/dt capability (2) Keep gate clamped to ensure V DRM capability (3) Lower t q time Related Effect -- Raises the device latching and holding current Primary Purpose (1) Increase dv/dt capability (2) Remove high frequency noise Related Effects (1) (2) (3) (4) (5) Increases delay time Increases turn-on interval Lowers gate signal rise time Lowers di/dt capability Increases t q time
Zener optional
Primary Purpose -- Decrease threshold sensitivity Related Effects (1) Affects gate signal rise time and di/dt rating (2) Isolates the gate Primary Purpose -- Isolate gate circuit DC component Related Effects -- In narrow gate pulses and low impedance sources, Igt followed by reverse gate signals which may inhibit conduction
Curves for Average Current at Various Conduction Angles
SCR maximum average current curves for various conduction angles can be established using the factors for maximum average current at conduction angle of: 30 = 0.40 x Avg 180 60 = 0.56 x Avg 180 90 = 0.70 x Avg 180 120 = 0.84 x Avg 180 The reason for different ratings is that the average current for conduction angles less than 180 is derated because of the higher RMS current connected with high peak currents. Note that maximum allowable case temperature (TC) remains the same for each conduction angle curve but is established from average current rating at 180 conduction as given in the data sheet for any particular device type. The maximum T C curve is then derated down to the maximum junction (TJ). The curves illustrated in Figure AN1009.4 are derated to 125 C since the maximum T J for the non-sensitive SCR series is 125 C.
125
Primary Purpose (1) Decrease DC gate sensitivity (2) Decrease tq time Related Effects (1) Negative gate current increases holding current and causes gate area to drop out of conduction (2) In pulse gating gate signal tail may cause device to drop out of conduction Primary Purpose -- Select frequency Related Effects -- Unless circuit is "damped," positive and negative gate current may inhibit conduction or bring about sporadic anode current
Maximum Allowable Case Temperature (TC) - C
120 115 110 105
Current: Halfwave Sinusoidal Load: Resistive or Inductive Conduction Angle: As Given Below Case Temperature: Measured as Shown on Dimensional Drawings
Primary Purpose (1) Supply reverse bias in off period (2) Protect gate and gate supply for reverse transients (3) Lower t q time Related Effects -- Isolates the gate if high impedance signal source is used without sustained diode current in the negative cycle
Conduction Angle
100 95 90 85
0 12 90
0 18
30
60
5.1 0 2 4 6
80
7.2 8
10.8 12.8 10 12 14
16
Average On-state Current [IT(AV)] - Amps
Figure AN1009.4
Typical Curves for Average On-state Current at Various Conduction Angles versus T C for a SXX20L SCR
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Application Notes
AN1009
Double-exponential Impulse Waveform
A double-exponential impulse waveform or waveshape of current or voltage is designated by a combination of two numbers (tr/td or tr x td s). The first number is an exponential rise time (tr) or wave front and the second number is an exponential decay time (td) or wave tail. The rise time (tr) is the maximum rise time permitted. The decay time (td) is the minimum time permitted. Both the tr and the td are in the same units of time, typically microseconds, designated at the end of the waveform description as defined by ANSI/IEEE C62.1-1989. The rise time (tr) of a current waveform is 1.25 times the time for the current to increase from 10% to 90% of peak value. See Figure AN1009.5. tr = Rise Time = 1.25 * [tc - ta] tr = 1.25 * [t(0.9 IPK) - t(0.1 IPK)] = T1 - T 0 The rise time (tr) of a voltage waveform is 1.67 times the time for the voltage to increase from 30% to 90% of peak value. (Figure AN1009.5) tr = Rise Time = 1.67 * [tc - tb] tr = 1.67 * [t(0.9 VPK) - t(0.3 V PK)] = T 1 - T 0 The decay time (td) of a waveform is the time from virtual zero (10% of peak for current or 30% of peak for voltage) to the time at which one-half (50%) of the peak value is reached on the wave tail. (Figure AN1009.5) Current Waveform td = Decay Time = [t(0.5 IPK) - t(0.1 IPK)] = T 2 - T 0 Voltage Waveform td = Decay Time = [t(0.5 VPK) - t(0.3 VPK)] = T 2 - T 0
Degradation Failures
A significant change of on-state, gate, or switching characteristics is quite rare. The most vulnerable characteristic is blocking voltage. This type of degradation increases with rising operating voltage and temperature levels.
Catastrophic Failures
A catastrophic failure can occur whenever the thyristor is operated beyond its published ratings. The most common failure mode is an electrical short between the main terminals, although a triac can fail in a half-wave condition. It is possible, but not probable, that the resulting short-circuit current could melt the internal parts of the device which could result in an open circuit.
Failure Causes
Most thyristor failures occur due to exceeding the maximum operating ratings of the device. Overvoltage or overcurrent operations are the most probable cause for failure. Overvoltage failures may be due to excessive voltage transients or may also occur if inadequate cooling allows the operating temperature to rise above the maximum allowable junction temperature. Overcurrent failures are generally caused by improper fusing or circuit protection, surge current from load initiation, load abuse, or load failure. Another common cause of device failure is incorrect handling procedures used in the manufacturing process. Mechanical damage in the form of excessive mounting torque and/or force applied to the terminals or leads can transmit stresses to the internal thyristor chip and cause cracks in the chip which may not show up until the device is thermally cycled.
Prevention of Failures
Careful selection of the correct device for the application's operating parameters and environment will go a long way toward extending the operating life of the thyristor. Good design practice should also limit the maximum current through the main terminals to 75% of the device rating. Correct mounting and forming of the leads also help ensure against infant mortality and latent failures. The two best ways to ensure long life of a thyristor is by proper heat sink methods and correct voltage rating selection for worst case conditions. Overheating, overvoltage, and surge currents are the main killers of semiconductors.
Decay = e - 1.44 T2
100% Percent of Current or Voltage 90% (Peak Value) Virtual Start of Wavefront
t
50% 30% 10% 0% T0 ta tb tc T1 Time T2
Most Common Thyristor Failure Mode
When a thyristor is electrically or physically abused and fails either by degradation or a catastrophic means, it will short (full-wave or half-wave) as its normal failure mode. Rarely does it fail open circuit. The circuit designer should add line breaks, fuses, overtemperature interrupters or whatever is necessary to protect the end user and property if a shorted or partially shorted thyristor offers a safety hazard.
Figure AN1009.5
Double-exponential Impulse Waveform
Failure Modes of Thyristor
Thyristor failures may be broadly classified as either degrading or catastrophic. A degrading type of failure is defined as a change in some characteristic which may or may not cause a catastrophic failure, but could show up as a latent failure. Catastrophic failure is when a device exhibits a sudden change in characteristic that renders it inoperable. To minimize degrading and catastrophic failures, devices must be operated within maximum ratings at all times.
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AN1009
Application Notes
Characteristics Formulas for Phase Control Circuits
PRV Circuit Name
Half-wave Resistive Load
Max Thyristor Voltage
1.4 ERMS
SCR
EP
Max. Load Voltage Ed=Avg. Ea=RMS
EP E d = ----- EP E a = -----2 2E P E d = --------- EP E a = ------1.4
Max. Average Thyristor or Rectifier Current Load Voltage with Delayed Firing
EP E d = ------ ( 1 + cos ) 2 EP 1 E a = ---------- ae - + -- sin 2 o o 2 2e E d EP = ---------- ( 1 + cos ) 2
Avg. Amps
EP ------R
Cond. Period
180
Full-wave Bridge Full-wave AC Switch Resistive Load
1.4 ERMS 1.4 ERMS
EP EP
EP ------R EP ------R
180 180
EP 1 E a = ---------- ae - + -- sin 2 o o 2 2 e
NOTE: Angle alpha () is in radians.
EP
ERMS R Load
0
Half-wave Resistive Load - Schematic
Half-wave Resistive Load - Waveform
L Load E R
EP 0
Full-wave Bridge - Schematic Full-wave Bridge - Waveform
EP
ERMS R Load
0
Full-wave AC Switch Resistive Load - Schematic
Full-wave AC Switch Resistive Load - Waveform
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AN1010
10
Thyristors for Ignition of Fluorescent Lamps
Since thyristors (solid state switches) do not mechanically open and close, the conventional fluorescent lighting circuit concept must be changed in order to use thyristors. In order to ignite (strike) a fluorescent lamp, a high voltage spike must be produced. The spike needs to be several hundred volts to quickly initiate ionization in the fluorescent lamp. A series ballast can only produce high voltage if a mechanical switch is used in conjunction with it. Therefore, with a thyristor a standard series ballast (inductor) is only useful as a current limiter.
Introduction
One of the many applications for Teccor thyristors is in fluorescent lighting. Standard conventional and circular fluorescent lamps with filaments can be ignited easily and much more quickly by using thyristors instead of the mechanical starter switch, and solid state thyristors are more reliable. Thyristors produce a pure solid state igniting circuit with no mechanical parts in the fluorescent lamp fixture. Also, because the lamp ignites much faster, the life of the fluorescent lamp can be increased since the filaments are activated for less time during the ignition. The thyristor ignition eliminates any audible noise or flashing off and on which most mechanical starters possess.
Methods for Producing High Voltage
The circuits illustrated in Figure AN1010.2 through Figure AN1010.5 show various methods for producing high voltage to ignite fluorescent lamps using thyristors (solid state switches). Note: Due to many considerations in designing a fluorescent fixture, the illustrated circuits are not necessarily the optimum design. One 120 V ac circuit consists of triac and diac thyristors with a capacitor to ignite the fluorescent lamp. (Figure AN1010.2)
Standard Fluorescent Circuit
The standard starter assembly is a glow switch mechanism with option small capacitor in parallel. (Figure AN1010.1)
Starter Assembly Line Input Ballast
Lamp
Figure AN1010.1
Typical Standard Fluorescent Circuit
The glow switch is made in a small glass bulb containing neon or argon gas. Inside the bulb is a U-shaped bimetallic strip and a fixed post. When the line input current is applied, the voltage between the bimetallic strip and the fixed post is high enough to ionize and produce a glow similar to a standard neon lamp. The heat from the ionization causes the bimetallic strip to move and make contact to the fixed post. At this time the ionization ceases and current can flow through and pre-heat the filaments of the fluorescent lamp. Since ionization (glowing) has ceased, the bimetallic strip begins to cool down and in a few seconds opens to start ionization (glowing) again. The instant the bimetallic ceases to make contact (opens), an inductive kick from the ballast produces some high voltage spikes 400 V to 600 V, which can ignite (strike) the fluorescent lamp. If the lamp fails to ignite or start, the glow switch mechanically repeats its igniting cycle over and over until the lamp ignites, usually within a few seconds. In this concept the ballast (inductor) is able to produce high voltage spikes using a mechanical switch opening and closing, which is fairly slow.
This circuit allows the 5 F ac capacitor to be charged and added to the peak line voltage, developing close to 300 V peak or 600 V peak to peak. This is accomplished by using a triac and diac phase control network set to fire near the 90 point of the input line. A capacitor-charging network is added to ensure that the capacitor is charged immediately, letting tolerances of components or temperature changes in the triac and diac circuit to be less critical. By setting the triac and diac phase control to fire at near the 90 point of the sinewave, maximum line voltages appear across the lamp for ignition. As the triac turns on during each half cycle, the filaments are pre-heated and in less than a second the lamp is lit. Once the lamp is lit the voltage is clamped to approximately 60 V peak across the 15 W to 20 W lamp, and the triac and diac circuit no longer functions until the lamp is required to be ignited again.
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AN1010
Application Notes
Ballast 14 W - 22 W 120 V ac Line Input
5 F 400 V
MT2 47 k 220 k Q401E4 G 1N4004 0.047 F 50 V HT-32 MT1
Lamp 15 W - 20 W
Optional Charging Network
Figure AN1010.2
120 V ac Triac/Diac Circuit
Figure AN1010.3 illustrates a circuit using a sidac (a simpler thyristor) phase control network to ignite a 120 V ac fluorescent lamp. As in the triac/diac circuit, the 5 F ac capacitor is charged and added to the peak line voltage, developing greater than 200 V peak or 400 V peak to peak. Since the sidac is a voltage breakover (VBO) activated device with no gate, a charging network is essential in this circuit to charge the capacitor above the
peak of the line in order to break over (turn on) the sidac with a VBO of 220 V to 250 V. As the sidac turns on each half cycle, the filaments are preheated and in less than 1.5 seconds the lamp is lit. Once the lamp is lit, the voltage across it clamps to approximately 60 V peak (for a 15 W to 20 W lamp), and the sidac ceases to function until the lamp is required to be ignited again.
Ballast 14 W - 22W 120 V ac Line Input
5 F 400 V
47 k K2400E Sidac 1N4004
Lamp 15 W - 20W
Optional Charging Network
Figure AN1010.3
120 V ac Sidac Circuit
The circuits illustrated in Figure AN1010.2 and Figure AN1010.3 use 15 W to 20 W lamps. The same basic circuits can be applied to higher wattage lamps. However, with higher wattage lamps the voltage developed to fire (light) the lamp will need to be somewhat higher. For instance, a 40 W lamp is critical on line input voltage to ignite, and after it is lit the voltage across the lamp will clamp to approximately 130 V peak. For a given type of lamp, the current must be limited to constant current regardless of the wattage of the lamp. Figure AN1010.4 shows a circuit for igniting a fluorescent lamp with 240 V line voltage input using triac and diac networks.
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AN1010 - 2
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Application Notes
AN1010
Ballast 3.3 F 47 k 240 V ac Line Input 1N4004 0.047 F 50 V HT-32 470 k MT2 Q601E4 G MT1
Lamp 40 W
Optional Charging Network
Figure AN1010.4
240 V ac Triac/Diac Circuit
Figure AN1010.5 illustrates a circuit using a sidac phase control network to ignite a 240 V ac fluorescent lamp. This circuit works basically the same as the 120 V circuit shown in Figure AN1010.3, except that component values are changed to com-
pensate for higher voltage. The one major change is that two K2400E devices in series are used to accomplish high firing voltage for a fluorescent lamp.
Ballast 3.3 F 240 V ac Line Input 47 k K2400E Sidac K2400E Sidac
1N4004
Lamp 40 W
Optional Charging Network
Figure AN1010.5
240 V ac Sidac Circuit
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AN1010 - 3
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Notes
Cross Reference Guide
Triacs, SCRs, Diacs, Sidacs, and Rectifiers (Suggested Teccor Replacements for JEDEC and Industry House Numbers)
1
How To Use This Guide
This Cross Reference Guide will help you determine the competitive products that Teccor supplies on either a DIRECT REPLACEMENT or SUGGESTED REPLACEMENT basis. Teccor offers replacements for most competitive devices. If you do not find a desired competitive product type listed, please contact the factory for information on recent additions to this list. On the following pages, listed in alphanumeric order, you will find: * * * Competitive product number Teccor device part number "D" indicating the Direct replacement (Teccor device meets or exceeds the electrical and mechanical specifications of the competitive device); "S" indicates a Suggested replacement (The suggested replacements in this guide represent the nearest Teccor equivalent for the product listed and in most instances are replacements. However, Teccor assumes no responsibility and does not guarantee that the replacements
are exact; only that the replacements will meet the terms of its applicable published written specifications. The pertinent Teccor specification sheet should be used as the principle tool for actual replacements.) * Teccor package type For additional assistance, contact your nearest Teccor distributor, sales representative, or the factory.
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Cross Reference Guide
Appendix
Part Number
40431 03P05M 03P1M 03P2M 03P3M 03P4M 03P5M 10TTS08S 16TTS08 16TTS08S 25TTS08 25TTS08FP 25TTS08S 2N1595 2N1596 2N1597 2N1598 2N1599 2N2323 2N3001 2N3002 2N3003 2N3004 2N3005 2N3006 2N3007 2N3008 2N3228 2N3525 2N3528 2N3529 2N4101 2N4102 2N4441 2N4442 2N4443 2N4444 2N5060 2N5061 2N5062 2N5063 2N5064 2N5754 2N5755 2N5756 2N6068 2N6068A 2N6068B 2N6069 2N6069A 2N6069B 2N6070 2N6070A 2N6070B 2N6071 2N6071A 2N6071B 2N6072 2N6072A 2N6072B 2N6073 2N6073A 2N6073B 2N6074 2N6074A 2N6074B 2N6075 2N6075A 2N6075B 2N6236
Teccor Device
Q2006LT EC103B EC103B EC103B EC103D EC103D EC103M S8012D S8016R S8016N S8025R S8025L S8025N S201E S201E S201E S401E S401E TCR22-4 75 EC103B EC103B EC103B EC103B EC103B EC103B EC103B EC103B S2006R S4006R S2006F1 S4006F1 S6006L S6006F1 S2008R S2008R S4008R S6008R 2N5064 2N5064 2N5064 2N5064 2N5064 Q2004F41 Q2004F41 Q4004F41 Q2004F41 L2004F51 L2004F31 Q2004F41 L2004F51 L2004F31 Q2004F41 L2004F51 L2004F31 Q2004F41 L2004F51 L2004F31 Q4004F41 L4004F51 L4004F31 Q4004F41 L4004F51 L4004F31 Q6004F41 L6004F51 L6004F31 Q6004F41 L6004F51 L6004F31 T106B1
Direct or Suggested Replacement
S S S S S S S S D S D D S S S S S S S S S S S D D D D S S S S S S S S S S D D D D D S S S S S S S S S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-220 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-252 (SMDT) TO-220 (N.ISOL) TO-263 (SMT) TO-220 (N.ISOL) TO-220 (ISOL) TO-263 (SMT) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
Part Number
2N6237 2N6238 2N6239 2N6240 2N6241 2N6342 2N6342A 2N6343 2N6343A 2N6344 2N6344A 2N6345 2N6345A 2N6346A 2N6347A 2N6348A 2N6349 2N6349A 2N6394 2N6395 2N6396 2N6397 2N6398 2N6399 2N6400 2N6401 2N6402 2N6403 2N6404 2N6405 2N6504 2N6505 2N6506 2N6507 2N6508 2N6509 2N6564 2N6564 2N6565 2N6565 2N877 2N878 2N879 2N880 2N881 2N885 2N886 2N887 2N888 2N889 2P05M 2P1M 2P2M 2P4M 2P5M 2P6M 30TPS08 3P4J 40TPS08 5P05M 5P1M 5P2M 5P4M 5P5M 5P6M 8T04HA 8T04SH 8T14HA 8T14SH 8T24HA
Teccor Device
T106B1 T106B1 T106B1 T106D1 T106M1 Q2008R4 Q2012RH5 Q4008R4 Q4012RH5 Q6008R5 Q6012RH5 Q8008R5 Q8012RH5 Q2015R5 Q4015R5 Q6015R5 Q8010R5 Q8015R5 S2012R S2012R S2012R S4012R S6012R S8012R S2016R S2016R S2016R S4016R S6016R S8016R S2025R S2025R S2025R S4025R S6025R S8025R 2N6565 EC103D 2N6565 EC103D EC103B EC103B EC103B EC103B EC103B 2N5064 2N5064 2N5064 2N5064 2N5064 T106B1 T106B1 T106B1 T106D1 T106M1 T106M1 S8035K T106D2 S8035K S2008R S2008R S2008R S4008R S6008R S6008R Q2004F41 L2004F81 Q2004F41 L2004F81 Q2004F41
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S D D D D D D D D D D D D D D D D D D D S D S S S S S S D D D D D S S S S S S S S S S S S S S S D S D S D
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-218AC (ISOL) "K" TO-202 (N.ISOL) TO-218AC (ISOL) "K" TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
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Appendix
Cross Reference Guide
Part Number
8T24SH 8T34HA 8T34SH 8T44HA 8T44SH 8T54HA 8T64HA 8T64SH AC03BGM AC03DGM AC03EGM AC03FGM AC08BGM AC08BSM AC08DGM AC08DSM AC08EGM AC08ESM AC08FGM AC08FSM AC10BGML AC10BSM AC10DGML AC10DSM AC10EGML AC10ESM AC10FGML AC10FSM AC12BGML AC12BSM AC12DGML AC12DSM AC12EGML AC12ESM AC12FGML AC12FSM AC16BGM AC16BSM AC16DGM AC16DSM AC16EGM AC16ESM AC16FGM AC16FSM AC25B1FL AC25D1FL AC25E1FL AC25F1FL BCR3AS-12 BCR3AS-8 BT131W-600 BT136-500 BT136-500D BT136-500E BT136-500F BT136-500G BT136-600 BT136-600D BT136-600E BT136-600F BT136-600G BT136-800 BT136-800F BT136-800G BT136F-500 BT136F-500D BT136F-500E BT136F-500F BT136F-500G BT136F-600
Teccor Device
L2004F81 Q4004F41 L4004F81 Q4004F41 L4004F81 Q6004F41 Q6004F41 L6004F81 Q2004F41 Q4004F41 Q5004F41 Q6004F41 Q2008R5 Q2008LH4 Q4008R4 Q4008LH4 Q6008R4 Q6008LH4 Q6008R5 Q6008LH4 Q2010RH5 Q2010LH5 Q4010RH5 Q4010LH5 Q6010RH5 Q6010LH5 Q6010RH5 Q6010LH5 Q2012RH5 Q2012LH5 Q4012RH5 Q4012LH5 Q6012RH5 Q6012LH5 Q6012RH5 Q6012LH5 Q2015R5 Q2015L5 Q4015R5 Q4015L5 Q6015R5 Q6015L5 Q6015R5 Q6015L5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6006DH3 Q4006DH3 L6N3 Q6004F41 L6004F61 L6004F81 Q6004F41 Q6004F41 Q6004F41 L6004F61 L6004F81 Q6004F41 Q6004F41 Q8004L4 Q8004L4 Q8004L4 Q6004L4 L6004L6 L6004L8 Q6004L4 Q6004L4 Q6004L4
Direct or Suggested Replacement
S D S D S D D S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S D D S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) TO-252 (SMT) TO-252 (SMT) SOT223 / COMPAK TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL)
Part Number
BT136F-600D BT136F-600E BT136F-600F BT136F-600G BT136F-800 BT136F-800F BT136F-800G BT136S-600D BT136S-600E BT136S-600F BT136X-500 BT136X-500D BT136X-500E BT136X-500F BT136X-500G BT136X-600 BT136X-600D BT136X-600E BT136X-600F BT136X-600G BT136X-800 BT136X-800F BT136X-800G BT137-500 BT137-500D BT137-500E BT137-500F BT137-500G BT137-600D BT137-600E BT137-600G BT137-800G BT137B-600 BT137B-600F BT137F-500 BT137F-500D BT137F-500E BT137F-500F BT137F-500G BT137F-600D BT137F-600E BT137F-600G BT137F-800G BT137S-600E BT137X-500 BT137X-500D BT137X-500E BT137X-500F BT137X-500G BT137X-600D BT137X-600E BT137X-600G BT137X-800G BT138-500G BT138-600G BT138-800G BT138F-500G BT138F-600G BT138F-800G BT138X-500G BT138X-600G BT138X-800G BT139-500G BT139-600G BT139-800G BT139F-500G BT139F-600G BT139F-800G BT139X-500G BT139X-500H
Teccor Device
L6004L6 L6004L8 Q6004L4 Q6004L4 Q8004L4 Q8004L4 Q8004L4 L6004D5 L6004D6 L6004D8 Q6004L4 L6004L6 L6004L8 Q6004L4 Q6004L4 Q6004L4 L6004L6 L6004L8 Q6004L4 Q6004L4 Q8004L4 Q8004L4 Q8004L4 Q6008R4 L6008L6 L6008L8 Q6008R4 Q6008R4 L6008L6 L6008L8 Q6008R5 Q8008R5 Q6010N4 Q6010N4 Q6008L4 L6008L6 L6008L8 Q6008L4 Q6008L4 L6008L6 L6008L8 Q6008L5 Q8008L5 L6008D8 Q6008L4 L6008L6 L6008L8 Q6008L4 Q6008L4 L6008L6 L6008L8 Q6008L5 Q8008L5 Q6015R5 Q6015R5 Q8015R5 Q6015L5 Q6015L5 Q8015L5 Q6015L5 Q6015L5 Q8015L5 Q6015R5 Q6015R5 Q8015R5 Q6015L5 Q6015L5 Q8015L5 Q6015L5 Q6015L6
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-252 (SMT) TO-252 (SMT) TO-252 (SMT) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-263 (SMT) TO-263 (SMT) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-252 (SMT) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL)
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Cross Reference Guide
Appendix
Part Number
BT139X-600G BT139X-600H BT139X-800G BT139X-800H BT145-500R BT145-600R BT145-800R BT149B BT149D BT149E BT149G BT150-500R BT150-600R BT150S-600R BT151-500R BT151-650R BT151-800R BT151S-500R BT151S-650R BT151X-500 BT151X-650 BT151X-800 BT152-400R BT152-600R BT152-800R BT152B-400R BT152B-600R BT152B-800R BT168B BT168D BT168E BT168G BT169B BT169D BT169E BT169G BT300-500R BT300-600R BT300-800R BT300S-600R BTA04-200A BTA04-200D BTA04-200GP BTA04-200S BTA04-200T BTA04-400A BTA04-400D BTA04-400GP BTA04-400S BTA04-400T BTA04-600A BTA04-600D BTA04-600GP BTA04-600S BTA04-600T BTA06-200A BTA06-200B BTA06-200C BTA06-200D BTA06-200GP BTA06-200S BTA06-200SW BTA06-200T BTA06-200TW BTA06-400A BTA06-400B BTA06-400BW BTA06-400C BTA06-400CW BTA06-400D
Teccor Device
Q6015L5 Q6015L6 Q8015L5 Q8015L6 Q6025R Q6025R Q8025R EC103B EC103D EC103M EC103M T106M1 T106M1 S6004DS2 S6010R S8010R S8010R S6012D S8012D S6010L S8010L S8010L S4020L S6020L S8020L S4025N S6025N S8025N EC103B EC103D EC103M EC103M EC103B EC103D EC103M EC103M S6008R S6008R S8008R S6008D L2004L8 L2004L6 L2004L6 L2004L6 L2004L5 L4004L8 L4004L6 L4004L6 L4004L6 L4004L5 L6004L8 L6004L6 L6004L6 L6004L6 L6004L5 L2006L8 Q2006L4 Q2006L4 L2006L6 L2006L6 L2006L6 L2006L8 L2006L5 L2006L6 L4006L8 Q4006L4 Q4006LH4 Q4006L4 Q4006LH4 L4006L6
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S D D D D S S S D D D S D D D D S D D D D S D D D S S D S D D S D D S S S D D
Teccor Package
TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-252 (SMT) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-252 (SMT) TO-252 (SMT) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-263 (SMT) TO-263 (SMT) TO-263 (SMT) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-252 (SMT) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL)
Part Number
BTA06-400GP BTA06-400S BTA06-400SW BTA06-400T BTA06-400TW BTA06-600A BTA06-600B BTA06-600BW BTA06-600C BTA06-600CW BTA06-600D BTA06-600GP BTA06-600S BTA06-600SW BTA06-600T BTA06-600TW BTA06-700B BTA06-700BW BTA06-700C BTA06-700CW BTA06-800B BTA06-800BW BTA06-800C BTA06-800CW BTA08-200A BTA08-200B BTA08-200C BTA08-200S BTA08-200SW BTA08-200TW BTA08-400A BTA08-400B BTA08-400BW BTA08-400C BTA08-400CW BTA08-400S BTA08-400SW BTA08-400TW BTA08-600A BTA08-600B BTA08-600BW BTA08-600C BTA08-600CW BTA08-600S BTA08-600SW BTA08-600TW BTA08-700B BTA08-700BW BTA08-700C BTA08-700CW BTA08-800B BTA08-800BW BTA08-800C BTA08-800CW BTA10-200AW BTA10-200B BTA10-200BW BTA10-200C BTA10-200CW BTA10-400AW BTA10-400B BTA10-400BW BTA10-400C BTA10-400CW BTA10-400GP BTA10-600AW BTA10-600B BTA10-600BW BTA10-600C BTA10-600CW
Teccor Device
L4006L6 L4006L6 L4006L8 L4006L5 L4006L6 L6006L8 Q6006L5 Q6006LH4 Q6006L5 Q6006LH4 L6006L6 L6006L6 L6006L6 L6006L8 L6006L5 L6006L6 Q8006L5 Q8006LH4 Q8006L5 Q7006LH4 Q8006L5 Q8006LH4 Q8006L5 Q8006LH4 L2008L8 Q2008L4 Q2008L4 L2008L6 L2008L8 L2008L6 L4008L8 Q4008L4 Q4008LH4 Q4008L4 Q4008LH4 L4008L6 L4008L8 L4008L6 L6008L8 Q6008L5 Q6008LH4 Q6008L5 Q6008LH4 L6008L6 L6008L8 L6008L6 Q8008L5 Q8008LH4 Q8008L5 Q8008LH4 Q8008L5 Q8008LH4 Q8008L5 Q8008LH4 Q2010L5 Q2010L5 Q2010LH5 Q2010L5 Q2010LH5 Q4010L5 Q4010L5 Q4010LH5 Q4010L5 Q4010LH5 Q4010L4 Q6010L5 Q6010L5 Q6010LH5 Q6010L5 Q6010LH5
Direct or Suggested Replacement
S D D S D D S S S S D S D D S D S S D D S S S D D S S D D D D S S S D D D D D S S S D D D D S S S D S S S D S S D S S S S D S S S S S D S S
Teccor Package
TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL)
http://www.teccor.com +1 972-580-7777
A-4
(c)2002 Teccor Electronics Thyristor Product Catalog
Appendix
Cross Reference Guide
Part Number
BTA10-600GP BTA10-700AW BTA10-700B BTA10-700BW BTA10-700C BTA10-700CW BTA10-800B BTA10-800BW BTA10-800C BTA10-800CW BTA12-200AW BTA12-200B BTA12-200BW BTA12-200C BTA12-400AW BTA12-400B BTA12-400BW BTA12-400C BTA12-400CW BTA12-600AW BTA12-600B BTA12-600BW BTA12-600C BTA12-600CW BTA12-700AW BTA12-700B BTA12-700BW BTA12-700C BTA12-700CW BTA12-800B BTA12-800BW BTA12-800C BTA12-800CW BTA13-200B BTA13-400B BTA13-600B BTA13-700B BTA13-800B BTA140-500 BTA140-600 BTA140-800 BTA16-200AW BTA16-200B BTA16-200BW BTA16-400AW BTA16-400B BTA16-400BW BTA16-400CW BTA16-600AW BTA16-600B BTA16-600BW BTA16-600CW BTA16-700AW BTA16-700B BTA16-700BW BTA16-700CW BTA16-800AW BTA16-800B BTA16-800BW BTA16-800CW BTA20-400BW BTA20-400CW BTA204S-600C BTA204S-600E BTA20-600BW BTA20-600CW BTA20-700BW BTA20-700CW BTA20-800BW BTA20-800CW
Teccor Device
Q6010L4 Q8010L5 Q8010L5 Q8010LH5 Q8010L5 Q8010LH5 Q8010L5 Q8010LH5 Q8010L5 Q8010LH5 Q2012LH5 Q2015L5 Q4012LH5 Q2015L5 Q4012LH5 Q4015L5 Q4012LH5 Q4015L5 Q4012LH5 Q6012LH5 Q6015L5 Q6012LH5 Q6015L5 Q6012LH5 Q8012LH5 Q8015L5 Q8012LH5 Q8015L5 Q8012LH5 Q8015L5 Q8012LH5 Q8015L5 Q8012LH5 Q2015L5 Q4015L5 Q6015L5 Q8015L5 Q8015L5 Q6025R5 Q6025R5 Q8025R5 Q2016LH6 Q2015L5 Q2016LH4 Q2016LH6 Q2015L5 Q2016LH4 Q4016LH4 Q6016LH6 Q6015L5 Q6016LH4 Q6016LH4 Q8016LH6 Q8015L5 Q8016LH4 Q8016LH4 Q8016LH6 Q8015L5 Q8016LH4 Q8016LH4 Q4025L6 Q4025L6 Q6006DH4 Q6006DH3 Q6025L6 Q6025L6 Q8025L6 Q8025L6 Q8025L6 Q8025L6
Direct or Suggested Replacement
S S S D S S S D S S D S D S D S D S S D S D S S D S D S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S D D S S S S S S
Teccor Package
TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-252 (SMT) TO-252 (SMT) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL)
Part Number
BTA208-600B BTA208-800B BTA208S-600E BTA208S-800C BTA208X-600B BTA208X-800B BTA20C BTA20D BTA20E BTA20M BTA20N BTA212-600B BTA212-800B BTA212B-600B BTA212B-800B BTA212X-600B BTA212X-800B BTA216-600B BTA216-800B BTA216B-600 BTA216X-600B BTA216X-800B BTA21C BTA21D BTA21E BTA21M BTA21N BTA225-600B BTA225-800B BTA225B-600B BTA225B-800B BTA22B BTA22C BTA22D BTA22E BTA22M BTA23B BTA23C BTA23D BTA23E BTA23M BTA24-600BW BTA24-600CW BTA24-700BW BTA24-700CW BTA24-800BW BTA24-800CW BTA25-200A BTA25-200B BTA25-400A BTA25-400B BTA25-600A BTA25-600B BTA25-600BW BTA25-600CW BTA25-700A BTA25-700B BTA25-800A BTA25-800B BTA25-800BW BTA25-800CW BTA26-200A BTA26-200B BTA26-400A BTA26-400B BTA26-400BW BTA26-400CW BTA26-600A BTA26-600B BTA26-600BW
Teccor Device
Q6008RH4 Q8008RH4 Q6008DH3 Q8008DH4 Q6008LH4 Q8008LH4 Q4006R4 Q4006R4 Q6006R4 Q6006R5 Q8006R5 Q6012RH5 Q8012RH5 Q6012NH5 Q8012NH5 Q6012LH5 Q8012LH5 Q6015R6 Q8015R6 Q6016NH4 Q6015L6 Q8015L6 Q4008R4 Q4008R4 Q6008R4 Q6008R5 Q8008R5 Q6025R6 Q8025R6 Q6025NH6 Q8025NH6 Q2010R5 Q4010R5 Q4010R5 Q5010R5 Q6010R5 Q2015R5 Q4015R5 Q4015R5 Q5015R5 Q6015R5 Q6025L6 Q6025L6 Q8025L6 Q8025L6 Q8025L6 Q8025L6 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q8025P5 Q8025P5 Q8025P5 Q8025P5 Q8025P5 Q8025P5 Q2025K6 Q2025K6 Q4025K6 Q4025K6 Q4025K6 Q4025K6 Q6025K6 Q6025K6 Q6025K6
Direct or Suggested Replacement
S S D D S S D D D D D S S D D S S S S S S S D D D S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-220 (N.ISOL TO-220 (N.ISOL TO-252 (SMT) TO-252 (SMT) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-263 (SMT) TO-263 (SMT) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-263 (SMT) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-263 (SMT) TO-263 (SMT) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL)
(c)2002 Teccor Electronics Thyristor Product Catalog
A-5
http://www.teccor.com +1 972-580-7777
Cross Reference Guide
Appendix
Part Number
BTA26-600CW BTA26-700A BTA26-700B BTA26-700BW BTA26-700CW BTA26-800A BTA26-800B BTA26-800BW BTA26-800CW BTA40-200A BTA40-200B BTA40-400A BTA40-400B BTA40-600A BTA40-600B BTA40-700A BTA40-700B BTA41-200A BTA41-200B BTA41-400A BTA41-400B BTA41-600A BTA41-600B BTA41-700A BTA41-700B BTA41-800A BTA41-800B BTB04-200A BTB04-200D BTB04-200S BTB04-200T BTB04-400A BTB04-400D BTB04-400S BTB04-400T BTB04-600A BTB04-600D BTB04-600S BTB04-600T BTB06-200A BTB06-200B BTB06-200C BTB06-200D BTB06-200S BTB06-200T BTB06-400A BTB06-400B BTB06-400BW BTB06-400C BTB06-400CW BTB06-400D BTB06-400S BTB06-400T BTB06-600A BTB06-600B BTB06-600BW BTB06-600C BTB06-600CW BTB06-600D BTB06-600S BTB06-600T BTB06-700B BTB06-700BW BTB06-700C BTB06-700CW BTB06-800B BTB06-800BW BTB06-800C BTB06-800CW BTB08-200A
Teccor Device
Q6025K6 Q8025K6 Q8025K6 Q8025K6 Q8025K6 Q8025K6 Q8025K6 Q8025K6 Q8025K6 Q6035P5 Q6035P5 Q6035P5 Q6035P5 Q6035P5 Q6035P5 Q8035P5 Q8035P5 Q2040K7 Q2040K7 Q4040K7 Q4040K7 Q6040K7 Q6040K7 Q8040K7 Q8040K7 Q8040K7 Q8040K7 L2004F81 L2004F61 L2004F61 L2004F51 L4004F81 L4004F61 L4004F61 L4004F51 L6004F61 L6004F61 L6004F81 L6004F51 L2006L8 Q2006R4 Q2006R4 L2006L6 L2006L6 L2006L5 L4006L8 Q4006R4 Q4006RH4 Q4006R4 Q4006RH4 L4006L6 L4006L6 L4006L5 L6006L8 Q6006R5 Q6006RH4 Q6006R5 Q6006RH4 L6006L6 L6006L6 L6006L5 Q8006R5 Q8006RH4 Q8006R5 Q8006RH4 Q8006R5 Q8006RH4 Q8006R5 Q8006RH4 L2008L8
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL)
Part Number
BTB08-200B BTB08-200C BTB08-200S BTB08-400A BTB08-400B BTB08-400BW BTB08-400C BTB08-400CW BTB08-400S BTB08-600A BTB08-600B BTB08-600BW BTB08-600C BTB08-600CW BTB08-600S BTB08-700B BTB08-700BW BTB08-700C BTB08-700CW BTB08-800B BTB08-800BW BTB08-800C BTB08-800CW BTB10-200B BTB10-200C BTB10-400B BTB10-400BW BTB10-400C BTB10-400CW BTB10-600B BTB10-600BW BTB10-600C BTB10-600CW BTB10-700B BTB10-700BW BTB10-700C BTB10-700CW BTB10-800B BTB10-800BW BTB10-800C BTB10-800CW BTB12-200B BTB12-200C BTB12-400B BTB12-400BW BTB12-400C BTB12-400CW BTB12-400SW BTB12-600B BTB12-600BW BTB12-600C BTB12-600CW BTB12-600SW BTB12-700B BTB12-700BW BTB12-700C BTB12-700CW BTB12-700SW BTB12-800B BTB12-800BW BTB12-800C BTB12-800CW BTB13-200B BTB13-400B BTB13-600B BTB13-700B BTB13-800B BTB15-200B BTB15-400B BTB15-600B
Teccor Device
Q2008R4 Q2008R4 L2008L6 L4008L8 Q4008R4 Q4008RH4 Q4008R4 Q4008RH4 L4008L6 L6008L8 Q6008R5 Q6008RH4 Q6008R5 Q6008RH4 L6008L6 Q8008R5 Q8008RH4 Q8008R5 Q8008RH4 Q8008R5 Q8008RH4 Q8008R5 Q8008RH4 Q2010R5 Q2010R5 Q4010R5 Q4010RH5 Q4010R5 Q4010RH5 Q6010R5 Q6010RH5 Q6010R5 Q6010RH5 Q8010R5 Q8010RH5 Q8010R5 Q8010RH5 Q8010R5 Q8010RH5 Q8010R5 Q8010RH5 Q2015R5 Q2015R5 Q4015R5 Q4012RH5 Q4015R5 Q4012RH5 Q4016RH3 Q6015R5 Q6012RH5 Q6015R5 Q6012RH5 Q6016RH3 Q8015R5 Q8012RH5 Q8015R5 Q8012RH5 Q8016RH3 Q8015R5 Q8012RH5 Q8015R5 Q8012RH5 Q2015R5 Q4015R5 Q6015R5 Q8015R5 Q8015R5 Q2015R5 Q4015R5 Q6015R5
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL)
http://www.teccor.com +1 972-580-7777
A-6
(c)2002 Teccor Electronics Thyristor Product Catalog
Appendix
Cross Reference Guide
Part Number
BTB15-700B BTB16-200B BTB16-400B BTB16-400CW BTB16-600B BTB16-600CW BTB16-700B BTB16-700CW BTB16-800B BTB16-800CW BTB19-200B BTB19-400B BTB19-600B BTB19-700B BTB20-400BW BTB20-400CW BTB20-600BW BTB20-600CW BTB20-700BW BTB20-700CW BTB20-800BW BTB20-800CW BTB24-200B BTB24-400B BTB24-600B BTB24-600BW BTB24-700B BTB24-800B BTB26-200A BTB26-200B BTB26-400A BTB26-400B BTB26-600A BTB26-600B BTB26-700A BTB26-700B BTB26-800B BTB41-200A BTB41-200B BTB41-400A BTB41-400B BTB41-600A BTB41-600B BTB41-700A BTB41-700B BTB41-800A BTB41-800B BTW41-500G BTW41-600G BTW66-200 BTW66-400 BTW66-600 BTW66-800 BTW67-200 BTW67-400 BTW67-600 BTW67-800 BTW68-200 BTW68-200N BTW68-400 BTW68-400N BTW68-600 BTW68-600N BTW68-800 BTW68-800N BTW69-200 BTW69-200N BTW69-400 BTW69-400N BTW69-600
Teccor Device
Q8015R5 Q2015R5 Q4015R5 Q4016RH4 Q6015R5 Q6016RH4 Q8015R5 Q8016RH4 Q8015R5 Q8016RH4 Q2025R5 Q4025R5 Q6025R5 Q8025R5 Q4025R6 Q4025R6 Q6025R6 Q6025R6 Q8025R6 Q8025R6 Q8025R6 Q8025R6 Q2025R5 Q4025R5 Q6025R5 Q6025R6 Q8025R5 Q8025R5 Q2025K6 Q2025K6 Q4025K6 Q4025K6 Q6025K6 Q6025K6 Q8025K6 Q8025K6 Q8025K6 Q2040K7 Q2040K7 Q4040K7 Q4040K7 Q6040K7 Q6040K7 Q8040K7 Q8040K7 Q8040K7 Q8040K7 Q6035P5 Q6035P5 S2035J S4035J S6035J S8035J S2065J S4065J S6065J S8065J S2035K S2035K S4035K S4035K S6035K S6035K S8035K S8035K S2065K S2055M S4065K S4055M S6065K
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S D S D S D S D S D D D D D
Teccor Package
TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (N.ISOL) TO-218 (ISOL) TO-218 (N.ISOL) TO-218 (ISOL)
Part Number
BTW69-600N BTW69-800 BTW69-800N BTW70-200N BTW70-400N BTW70-600N BYW80-100 BYW80-150 BYW80-200 BYW80-50 C103A C103B C103D C103E C103M C103Y C103YY C106A C106A1 C106A11 C106A12 C106A2 C106A21 C106A3 C106A32 C106A4 C106A41 C106B C106B1 C106B11 C106B12 C106B2 C106B21 C106B3 C106B32 C106B4 C106B41 C106C C106C1 C106C11 C106C12 C106C2 C106C21 C106C3 C106C32 C106C4 C106C41 C106D C106D1 C106D11 C106D12 C106D2 C106D21 C106D3 C106D32 C106D4 C106D41 C106E C106E1 C106E11 C106E12 C106E2 C106E21 C106E3 C106E32 C106E4 C106E41 C106F C106F1 C106F11
Teccor Device
S6055M S8065K S8055M S2070W S4070W S6070W D2020L D2020L D2020L D2020L EC103B EC103B EC103D EC103M EC103M EC103B EC103B T106B1 T106B1 T106B11 T106B12 T106B2 T106B21 T106B3 T106B32 T106B4 T106B41 T106B1 T106B1 T106B11 T106B12 T106B2 T106B21 T106B3 T106B32 T106B4 T106B41 T106D T106D1 T106D11 T106D12 T106D2 T106D1 T106D3 T106D32 T106D4 T106D41 T106D1 T106D1 T106D11 T106D12 T106D2 T106D21 T106D3 T106D32 T106D4 T106D41 T106M1 T106M1 T106M11 T106M12 T106M2 T106M21 T106M3 T106M32 T106M4 T106M41 T106B1 T106B1 T106B11
Direct or Suggested Replacement
D D D S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-218 (N.ISOL) TO-218 (ISOL) TO-218 (N.ISOL) TO-218 (N.ISOL) TO-218 (N.ISOL) TO-218 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
(c)2002 Teccor Electronics Thyristor Product Catalog
A-7
http://www.teccor.com +1 972-580-7777
Cross Reference Guide
Appendix
Part Number
C106F12 C106F2 C106F21 C106F3 C106F32 C106F4 C106F41 C106M C106M1 C106M11 C106M12 C106M2 C106M21 C106M3 C106M32 C106M4 C106M41 C106Q C106Q1 C106Q11 C106Q12 C106Q2 C106Q21 C106Q3 C106Q32 C106Q4 C106Q41 C106Y C106Y1 C106Y11 C106Y12 C106Y2 C106Y21 C106Y3 C106Y32 C106Y4 C106Y41 C107A C107A1 C107A11 C107A12 C107A2 C107A21 C107A3 C107A32 C107A4 C107A41 C107B C107B1 C107B11 C107B12 C107B2 C107B21 C107B3 C107B32 C107B4 C107B41 C107C C107C1 C107C11 C107C12 C107C2 C107C21 C107C3 C107C32 C107C4 C107C41 C107D C107D1 C107D11
Teccor Device
T106B12 T106B2 T106B21 T106B3 T106B32 T106B4 T106B41 T106M1 T106M1 T106M11 T106M12 T106M2 T106M21 T106M3 T106M32 T106M4 T106M41 T106B1 T106B1 T106B11 T106B12 T106B2 T106B21 T106B3 T106B32 T106B4 T106B41 T106B1 T106B1 T106B11 T106B12 T106B2 T106B21 T106B3 T106B32 T106B4 T106B41 T107B1 T107B1 T107B11 T107B12 T107B2 T107B21 T107B3 T107B32 T107B4 T107B41 T107B1 T107B1 T107B11 T107B12 T107B2 T107B21 T107B3 T107B32 T107B4 T107B41 T107D1 T107D1 T107D11 T107D12 T107D2 T107D21 T107D3 T107D32 T107D4 T107D41 T107D1 T107D1 T107D11
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
Part Number
C107D12 C107D2 C107D21 C107D3 C107D32 C107D4 C107D41 C107E C107E1 C107E11 C107E12 C107E2 C107E21 C107E3 C107E32 C107E4 C107E41 C107F C107F1 C107F11 C107F12 C107F2 C107F21 C107F3 C107F32 C107F4 C107F41 C107M C107M1 C107M11 C107M12 C107M2 C107M21 C107M3 C107M32 C107M41 C107Q C107Q1 C107Q11 C107Q12 C107Q2 C107Q21 C107Q3 C107Q32 C107Q4 C107Q41 C107Y C107Y1 C107Y11 C107Y12 C107Y2 C107Y21 C107Y3 C107Y32 C107Y4 C107Y41 C108A C108A1 C108A11 C108A12 C108A2 C108A21 C108A3 C108A32 C108A4 C108A41 C108B C108B1 C108B11 C108B12
Teccor Device
T107D12 T107D2 T107D21 T107D3 T107D32 T107D4 T107D41 T107M1 T107M1 T107M11 T107M12 T107M2 T107M21 T107M3 T107M32 T107M4 T107M41 T107B1 T107B1 T107B11 T107B12 T107B2 T107B21 T107B3 T107B32 T107B4 T107B41 T107M1 T107M1 T107M11 T107M12 T107M2 T107M21 T107M3 T107M32 T107M41 T107B1 T107B1 T107B11 T107B12 T107B2 T107B21 T107B3 T107B32 T107B4 T107B41 T107B1 T107B1 T107B11 T107B12 T107B2 T107B21 T107B3 T107B32 T107B4 T107B41 S2006FS21 S2006FS21 S2006FS211 S2006FS212 S2006FS22 S2006FS221 S2006FS23 S2006FS232 S2006FS24 S2006FS241 S2006FS21 S2006FS21 S2006FS211 S2006FS212
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
http://www.teccor.com +1 972-580-7777
A-8
(c)2002 Teccor Electronics Thyristor Product Catalog
Appendix
Cross Reference Guide
Part Number
C108B2 C108B21 C108B3 C108B32 C108B4 C108B41 C108C C108C1 C108C11 C108C12 C108C2 C108C21 C108C3 C108C32 C108C4 C108C41 C108D C108D1 C108D11 C108D12 C108D2 C108D21 C108D3 C108D32 C108D4 C108D41 C108E C108E1 C108E11 C108E12 C108E2 C108E21 C108E3 C108E32 C108E4 C108E41 C108F C108F1 C108F11 C108F12 C108F2 C108F21 C108F3 C108F32 C108F4 C108F41 C108M C108M1 C108M11 C108M12 C108M2 C108M21 C108M3 C108M32 C108M4 C108M41 C108Q C108Q1 C108Q11 C108Q12 C108Q2 C108Q21 C108Q3 C108Q32 C108Q4 C108Q41 C108Y C108Y1 C108Y11 C108Y12
Teccor Device
S2006FS22 S2006FS221 S2006FS23 S2006FS232 S2006FS24 S2006FS241 S4006FS21 S4006FS21 S4006FS211 S4006FS212 S4006FS22 S4006FS221 S4006FS23 S4006FS232 S4006FS24 S4006FS241 S4006FS21 S4006FS21 S4006FS211 S4006FS212 S4006FS22 S4006FS221 S4006FS23 S4006FS232 S4006FS24 S4006FS241 S6006FS21 S6006FS21 S6006FS211 S6006FS212 S6006FS22 S6006FS221 S6006FS23 S6006FS232 S6006FS24 S6006FS241 S2006FS21 S2006FS21 S2006FS211 S2006FS212 S2006FS22 S2006FS221 S2006FS23 S2006FS232 S2006FS24 S2006FS241 S6006FS21 S6006FS21 S6006FS211 S6006FS212 S6006FS22 S6006FS221 S6006FS23 S6006FS232 S6006FS24 S6006FS241 S2006FS21 S2006FS21 S2006FS211 S2006FS212 S2006FS22 S2006FS221 S2006FS23 S2006FS232 S2006FS24 S2006FS241 S2006FS21 S2006FS21 S2006FS211 S2006FS212
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
Part Number
C108Y2 C108Y21 C108Y3 C108Y32 C108Y4 C108Y41 C116A1 C116B1 C116C1 C116D1 C116E1 C116F1 C116M1 C122A C122B C122C C122D C122E C122F C122M C122N C122S C123A C123B C123C C123D C123E C123F C123M C126A C126B C126C C126D C126E C126F C126M C127A C127B C127D C127E C127F C127M C203A C203B C203C C203D C203Y C203YY C205A C205B C205C C205D C205Y C205YY D30 D40 DB3 DB4 DC34 DC38 DC42 DO201YR HI03SC HI03SD HI03SG HI03SH HI03SS HI13SC HI13SD HI13SG
Teccor Device
S2006FS22 S2006FS221 S2006FS23 S2006FS232 S2006FS24 S2006FS241 S2008F1 S2008F1 S4008F1 S4008F1 S6008F1 S2008F1 S6008F1 S2008R S2008R S4008R S4008R S6008R S2008R S6008R S8008R S8008R S2008L S2008L S4008L S4008L S6008L S2008L S6008L S2012R S2012R S4012R S4012R S6012R S2012R S6012R S2016R S2016R S4016R S6016R S2016R S6016R EC103B EC103B EC103D EC103D EC103B EC103B EC103B EC103B EC103D EC103D EC103B EC103B HT32 HT40 HT32 HT40 HT32 HT40 HT40 HT5761 L2004F31 L2004F51 L2004F61 L2004F81 L2004F31 L2004F31 L2004F51 L2004F61
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S D D D D D D S S S S S S D D D D D D D D S D S S S D S S S S S S S S
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) DO-35 (ISOL) DO-35 (ISOL) DO-35 (ISOL) DO-35 (ISOL) DO-35 (ISOL) DO-35 (ISOL) DO-35 (ISOL) DO-35 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
(c)2002 Teccor Electronics Thyristor Product Catalog
A-9
http://www.teccor.com +1 972-580-7777
Cross Reference Guide
Appendix
Part Number
HI13SH HI13SS HI23SC HI23SD HI23SG HI23SH HI23SS HI33SC HI33SD HI33SG HI33SH HI33SS HI43SC HI43SD HI43SG HI43SH HI43SS HI63SC HI63SD HI63SG HI63SH HI63SS HT06 HT16 HT26 HT36 HT46 HT66 ID100 ID101 ID102 ID103 ID104 ID105 ID106 IP100 IP101 IP102 IP103 IP104 IP105 IP106 IS010 IS010X IS020 IS020X IS08 IS08X IS110 IS110X IS120 IS120X IS18 IS18X IS210 IS210X IS220 IS220X IS28 IS28X IS310 IS310X IS320 IS320X IS38 IS38X IS410 IS410X IS420 IS420X
Teccor Device
L2004F81 L2004F31 L2004F31 L2004F51 L2004F61 L2004F81 L2004F31 L4004F31 L4004F51 L4004F61 L4004F81 L4004F31 L4004F31 L4004F51 L4004F61 L4004F81 L4004F31 L6004F31 L6004F51 L6004F61 L6004F81 L6004F31 Q2006F41 Q2006F41 Q2006F41 Q4006F41 Q4006F41 Q6006F41 EC103B EC103B EC103B EC103B EC103B EC103D EC103D 2N5064 2N5064 2N5064 2N5064 2N5064 EC103D EC103D S2010L S2010L S2020L S2020L S2008L S2008L S2010L S2010L S2020L S2020L S2008L S2008L S2010L S2010L S2020L S2020L S2008L S2008L S4010L S4010L S4020L S4020L S4008L S4008L S4010L S4010L S4020L S4020L
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S D D D D D D D D D S D D D D D S D D D D D S D D D D D S D D D D D S D
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL)
Part Number
IS48 IS48X IS510 IS510X IS520 IS520X IS58 IS58X IS610 IS610X IS620 IS620X IS68 IS68X IT010 IT010A IT010B IT010HA IT010HX IT015 IT015A IT015B IT015HA IT015HX IT06 IT08 IT08A IT08B IT08HA IT08HX IT110 IT110A IT110B IT110HA IT110HX IT115 IT115A IT115B IT115HA IT115HX IT16 IT18 IT18A IT18B IT18HA IT18HX IT210 IT210A IT210B IT210HA IT210HX IT215 IT215A IT215B IT215HA IT215HX IT26 IT28 IT28A IT28B IT28HA IT28HX IT310 IT310A IT310B IT310HA IT310HX IT315 IT315A IT315B
Teccor Device
S4008L S4008L S6010L S6010L S6020L S6020L S6008L S6008L S6010L S6010L S6020L S6020L S6008L S6008L Q2010L5 Q2010L5 Q2010L5 Q2010L5 Q2010L5 Q2015L5 Q2015L5 Q2015L5 Q2015L5 Q2015L5 Q2006L4 Q2008L4 Q2008L4 Q2008L4 Q2008L4 Q2008L4 Q2010L5 Q2010L5 Q2010L5 Q2010L5 Q2010L5 Q2015L5 Q2015L5 Q2015L5 Q2015L5 Q2015L5 Q2006L4 Q2008L4 Q2008L4 Q2008L4 Q2008L4 Q2008L4 Q2010L5 Q2010L5 Q2010L5 Q2010L5 Q2010L5 Q2015L5 Q2015L5 Q2015L5 Q2015L5 Q2015L5 Q2006L4 Q2008L4 Q2008L4 Q2008L4 Q2008L4 Q2008L4 Q4010L5 Q4010L5 Q4010L5 Q4010L5 Q4010L5 Q4015L5 Q4015L5 Q4015L5
Direct or Suggested Replacement
D D D D S D D D D D S D D D D D D S S D D D S S D D D D D S D D D S S D D D S S D D D D D S D D D S S D D D S S D D D D D S D D D S S D D D
Teccor Package
TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL)
http://www.teccor.com +1 972-580-7777
A-10
(c)2002 Teccor Electronics Thyristor Product Catalog
Appendix
Cross Reference Guide
Part Number
IT315HA IT315HX IT36 IT38 IT38A IT38B IT38HA IT38HX IT410 IT410A IT410B IT410HA IT410HX IT415 IT415A IT415B IT415HA IT415HX IT46 IT48 IT48A IT48B IT48HA IT48HX IT510 IT510A IT510B IT510HA IT510HX IT515 IT515A IT515B IT515HA IT515HX IT56 IT58 IT58A IT58B IT58HA IT58HX IT610 IT610A IT610B IT610HA IT610HX IT615 IT615A IT615B IT615HA IT615HX IT66 IT68 IT68A IT68B IT68HA IT68HX K1V10 K1V11 K1V12 K1V14 K1V16 K1V18 K1V22 K1V24 K1V26 K1VA10 K1VA11 K1VA12 K1VA14 K1VA16
Teccor Device
Q4015L5 Q4015L5 Q4006L4 Q4008L4 Q4008L4 Q4008L4 Q4008L4 Q4008L4 Q4010L5 Q4010L5 Q4010L5 Q4010L5 Q4010L5 Q4015L5 Q4015L5 Q4015L5 Q4015L5 Q4015L5 Q4006L4 Q4008L4 Q4008L4 Q4008L4 Q4008L4 Q4008L4 Q6010L5 Q6010L5 Q6010L5 Q6010L5 Q6010L5 Q6015L5 Q6015L5 Q6015L5 Q6015L5 Q6015L5 Q6006L4 Q6008L4 Q6008L4 Q6008L4 Q6008L4 Q6008L4 Q6010L5 Q6010L5 Q6010L5 Q6010L5 Q6010L5 Q6015L5 Q6015L5 Q6015L5 Q6015L5 Q6015L5 Q6006L5 Q6008L5 Q6008L5 Q6008L5 Q6008L5 Q6008L5 K1050G K1100G K1200G K1300G K1500G K1500G K2200G K2400G K2500G K1050E70 K1100E70 K1200E70 K1300E70 K1500E70
Direct or Suggested Replacement
S S D D D D D S D D D S S D D D S S D D D D D S D D D S S D D D S S D D D D D S D D D S S D D D S S D D D D S S S S S S S S S S S S S S S S
Teccor Package
TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) DO-15X DO-15X DO-15X DO-15X DO-15X DO-15X DO-15X DO-15X DO-15X TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL)
Part Number
L2004L7 L2004L9 L2006L7 L2006L9 L2008L7 L2008L9 L201E7 L201E9 L4004L7 L4004L9 L4006L7 L4006L9 L4008L7 L4008L9 L401E7 L401E9 L6004L7 L6004L9 L6006L7 L6006L9 L6008L7 L6008L9 L601E7 L601E9 MAC08BT1 MAC08DT1 MAC08MT1 MAC12D MAC12HCD MAC12HCM MAC12HCN MAC12M MAC12N MAC15-10 MAC15-10FP MAC15-4 MAC15-4FP MAC15-5 MAC15-6 MAC15-6FP MAC15-7 MAC15-8 MAC15-8FP MAC15-9 MAC15A10 MAC15A10FP MAC15A4 MAC15A4FP MAC15A5 MAC15A5FP MAC15A6 MAC15A6FP MAC15A7 MAC15A7FP MAC15A8 MAC15A8FP MAC15A9 MAC15A9FP MAC15M MAC15N MAC16-10 MAC16-4 MAC16-6 MAC16-8 MAC16CD MAC16CM MAC16CN MAC16D MAC16M MAC16N
Teccor Device
L2004L6 L2004L8 L2006L6 L2006L8 L2008L6 L2008L8 L201E6 L201E8 L4004L6 L4004L8 L4006L6 L4006L8 L4008L6 L4008L8 L401E6 L401E8 L6004L6 L6004L8 L6006L6 L6006L8 L6008L6 L6008L8 L601E6 L601E8 L2X5 L4X5 L6X5 Q4015R5 Q4012RH5 Q6012RH5 Q8012RH5 Q6015R5 Q8015R5 Q8015R5 Q8015L5 Q2015R5 Q2015L5 Q4015R5 Q4015R5 Q4015L5 Q6015R5 Q6015R5 Q6015L5 Q8015R5 Q8015R5 Q8015L5 Q2015R5 Q2015L5 Q4015R5 Q4015L5 Q4015R5 Q4015L5 Q6015R5 Q6015L5 Q6015R5 Q6015L5 Q8015R5 Q8015L5 Q6015R5 Q8015R5 Q8015R6 Q2015R6 Q4015R6 Q6015R6 Q4015R6 Q6015R6 Q8015R6 Q4015R6 Q6015R6 Q8015R6
Direct or Suggested Replacement
D D D D D D D D D D D D D D D D D D D D D D D D S S S S S S S S S D D D D D D D D D D D S S S S S S S S S S S S S S D D D D D D S S S S S S
Teccor Package
TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-92 (ISOL) TO-92 (ISOL) SOT-223/COMPAK SOT-223/COMPAK SOT-223/COMPAK TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL)
(c)2002 Teccor Electronics Thyristor Product Catalog
A-11
http://www.teccor.com +1 972-580-7777
Cross Reference Guide
Appendix
Part Number
MAC20-10 MAC20-4 MAC20-5 MAC20-6 MAC20-7 MAC20-8 MAC20-9 MAC20A10 MAC20A4 MAC20A5 MAC20A6 MAC20A7 MAC20A8 MAC20A9 MAC210-10 MAC210-10FP MAC210-4 MAC210-4FP MAC210-5 MAC210-6 MAC210-6FP MAC210-7 MAC210-8 MAC210-8FP MAC210A10 MAC210A10F MAC210A4 MAC210A4FP MAC210A5 MAC210A5FP MAC210A6 MAC210A6FP MAC210A7 MAC210A7FP MAC210A8 MAC210A8FP MAC210A9 MAC210A9FP MAC212-10 MAC212-10FP MAC212-4 MAC212-4FP MAC212-6 MAC212-6FP MAC212-8 MAC212-8FP MAC212A10 MAC212A10FP MAC212A4 MAC212A4FP MAC212A6 MAC212A6FP MAC212A8 MAC212A8FP MAC213-10 MAC213-4 MAC213-6 MAC213-8 MAC218-10 MAC218-10FP MAC218-2 MAC218-3 MAC218-4 MAC218-4FP MAC218-5 MAC218-6 MAC218-6FP MAC218-7 MAC218-8 MAC218-8FP
Teccor Device
Q8025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q8025P5 Q8025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q8025P5 Q8010R5 Q8010L5 Q2010R5 Q2010L5 Q4010R5 Q4010R5 Q4010L5 Q6010R5 Q6010R5 Q6010L5 Q8010R5 Q8010L5 Q2010R5 Q2010L5 Q4010R5 Q4010L5 Q4010R5 Q4010L5 Q6010R5 Q6010L5 Q6010R5 Q6010L5 Q8010R5 Q8010L5 Q8012RH5 Q8012LH5 Q2012RH5 Q2012LH5 Q4012RH5 Q4012LH5 Q6012RH5 Q6012LH5 Q8012RH5 Q8012LH5 Q2015RH5 Q2012LH5 Q4012RH5 Q4012LH5 Q6012RH5 Q6012LH5 Q8012RH5 Q2012RH5 Q4012RH5 Q6012RH5 Q8008R5 Q8008L5 Q2008R5 Q2008R5 Q2008R5 Q2008L5 Q4008R4 Q4008R4 Q4008L5 Q4008R4 Q6008R5 Q6008L5
Direct or Suggested Replacement
S S S S S S S S S S S S S S D D D D D D D D D D S S S S S S S S S S S S S S D D D D D D D D S S S S S S S S D D D D D D D D D D D D D D D S
Teccor Package
FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL)
Part Number
MAC218-A10 MAC218-A10FP MAC218-A2 MAC218-A3 MAC218-A4 MAC218-A4FP MAC218-A5 MAC218-A6 MAC218-A6FP MAC218-A7 MAC218-A8 MAC218-A8FP MAC219-10 MAC219-4 MAC219-6 MAC219-8 MAC220-2 MAC220-3 MAC220-5 MAC220-7 MAC220-9 MAC221-2 MAC221-3 MAC221-5 MAC221-7 MAC221-9 MAC222-1 MAC222-10 MAC222-2 MAC222-3 MAC222-4 MAC222-5 MAC222-6 MAC222-7 MAC222-8 MAC222-9 MAC222A1 MAC222A10 MAC222A2 MAC222A3 MAC222A4 MAC222A5 MAC222A6 MAC222A7 MAC222A8 MAC222A9 MAC223-10 MAC223-10FP MAC223-3 MAC223-4 MAC223-4FP MAC223-5 MAC223-6 MAC223-6FP MAC223-7 MAC223-8 MAC223-8FP MAC223-9 MAC223A10 MAC223A10FP MAC223A3 MAC223A4 MAC223A4FP MAC223A5 MAC223A5FP MAC223A6 MAC223A6FP MAC223A7 MAC223A7FP MAC223A8
Teccor Device
Q8008R5 Q8008L5 Q2008R4 Q2008R4 Q2008R4 Q2008L4 Q4008R4 Q4008R4 Q4008L4 Q5008R4 Q6008R5 Q6008L5 Q8008R5 Q2008R4 Q4008R4 Q6008R5 Q2008R4 Q2008R4 Q4008R4 Q6008R4 Q8008R5 Q2008R4 Q2008R4 Q4008R4 Q6008R4 Q8008R5 Q2008R4 Q8008R5 Q2008R4 Q2008R4 Q2008R4 Q4008R4 Q4008R4 Q6008R4 Q6008R5 Q8008R5 Q2008R4 Q8008R5 Q2008R4 Q2008R4 Q2008R4 Q4008R4 Q4008R4 Q6008R4 Q6008R5 Q8008R5 Q8025R5 Q8025L6 Q2025R5 Q2025R5 Q2025L6 Q4025R5 Q4025R5 Q4025L6 Q6025R5 Q6025R5 Q6025L6 Q8025R5 Q8025R5 Q8025L6 Q4025R5 Q2025R5 Q2025L6 Q4025R5 Q4025L6 Q4025R5 Q4025L6 Q6025R5 Q6025L6 Q6025R5
Direct or Suggested Replacement
S S S S S S S S S S S S D D D D D D D D D D D D D D D D D D D D D D D D S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL)
http://www.teccor.com +1 972-580-7777
A-12
(c)2002 Teccor Electronics Thyristor Product Catalog
Appendix
Cross Reference Guide
Part Number
MAC223A8FP MAC223A9 MAC223A9FP MAC224-10 MAC224-4 MAC224-5 MAC224-6 MAC224-7 MAC224-8 MAC224A10 MAC224A4 MAC224A5 MAC224A6 MAC224A7 MAC224A8 MAC224A9 MAC228-2 MAC228-3 MAC228-4 MAC228-4FP MAC228-5 MAC228-6 MAC228-6FP MAC228-7 MAC228-8 MAC228-8FP MAC228A2 MAC228A3 MAC228A4 MAC228A4FP MAC228A5 MAC228A6 MAC228A6FP MAC228A7 MAC228A8 MAC228A8FP MAC229-4 MAC229-4FP MAC229-6 MAC229-6FP MAC229-8 MAC229-8FP MAC229A4 MAC229A4FP MAC229A6 MAC229A6FP MAC229A8 MAC229A8FP MAC229A8FP MAC25-10 MAC25-4 MAC25-5 MAC25-6 MAC25-7 MAC25-8 MAC25-9 MAC25A10 MAC25A4 MAC25A5 MAC25A6 MAC25A7 MAC25A8 MAC25A9 MAC3010-15 MAC3010-25 MAC3010-4 MAC3010-8 MAC3020-15 MAC3020-25 MAC3020-4
Teccor Device
Q6025L6 Q8025R5 Q8025L6 Q8040K7 Q2040K7 Q4040K7 Q4040K7 Q6040K7 Q6040K7 Q8040K7 Q2040K7 Q4040K7 Q4040K7 Q6040K7 Q6040K7 Q8040K7 L2008L6 L2008L6 L2008L6 L2008L6 L4008L6 L4008L6 L4008L6 L6008L6 L6008L6 L6008L6 L2008L6 L2008L6 L2008L6 L2008L6 L4008L6 L4008L6 L4008L6 L6008L6 L6008L6 L6008L6 L2008L6 L2008L6 L4008L6 L4008L6 L6008L6 L6008L6 L2008L6 L2008L6 L4008L6 L4008L6 L6008L6 L6008L6 L6008L6 Q8025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q8025P5 Q8025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q8025P5 Q2015R5 Q2025R5 L2004F31 Q2008R4 Q4015R5 Q4025R5 L4004F31
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S D S S D S S D S S S S S S S S S S S D S D S D S S S S S S S S S S S S S S S S S S S S S S S S D S S S
Teccor Package
TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-202 (N.ISOL)
Part Number
MAC3020-8 MAC3030-15 MAC3030-25 MAC3030-4 MAC3030-8 MAC3040-15 MAC3040-25 MAC3040-4 MAC3040-8 MAC320-10 MAC320-10FP MAC320-4 MAC320-4FP MAC320-6 MAC320-6FP MAC320-8 MAC320-8FP MAC320A10 MAC320A4 MAC320A6 MAC320A8 MAC321-10 MAC321-4 MAC321-6 MAC321-8 MAC4DCM MAC4DCM1 MAC4DCN MAC4DCN1 MAC4DHM MAC4DHM1 MAC4DLM MAC4DLM1 MAC4DSM MAC4DSM1 MAC4DSN MAC4DSN1 MAC50-4 MAC50-5 MAC50-6 MAC50-7 MAC50-8 MAC50-9 MAC50A4 MAC50A5 MAC50A6 MAC50A7 MAC50A8 MAC50A9 MAC515-10 MAC515-4 MAC515-5 MAC515-6 MAC515-7 MAC515-8 MAC515-9 MAC515A10 MAC515A4 MAC515A5 MAC515A6 MAC515A7 MAC515A8 MAC515A9 MAC525-10 MAC525-4 MAC525-5 MAC525-6 MAC525-7 MAC525-8 MAC525-9
Teccor Device
Q4008R4 Q2015R5 Q2025R5 L4004F41 Q2008R4 Q4015R5 Q4025R5 L4004F41 Q4008R4 Q8025R5 Q8025L6 Q2025R5 Q2025L6 Q4025R5 Q4025L6 Q6025R5 Q6025L6 Q8025R5 Q2025R5 Q4025R5 Q6025R5 Q8025R5 Q2025R5 Q4025R5 Q6025R5 Q6006DH4 Q6006VH4 Q8006DH4 Q8006VH4 L6004D6 L6004V6 L6004D5 L6004V5 Q6006DH3 Q6006VH3 Q8006DH3 Q8006VH3 Q6035P5 Q6035P5 Q6035P5 Q6035P5 Q6035P5 Q8035P5 Q6035P5 Q6035P5 Q6035P5 Q6035P5 Q6035P5 Q8035P5 Q8025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q8025P5 Q8025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q8025P5 Q8025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q8025P5
Direct or Suggested Replacement
D S S S D S S S D S S S S S S S S S S S S D D D D S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL)
(c)2002 Teccor Electronics Thyristor Product Catalog
A-13
http://www.teccor.com +1 972-580-7777
Cross Reference Guide
Appendix
Part Number
MAC525A10 MAC525A4 MAC525A5 MAC525A6 MAC525A7 MAC525A8 MAC525A9 MAC625-4 MAC625-6 MAC625-8 MAC635-4 MAC635-6 MAC635-8 MAC8D MAC8M MAC8N MAC91-1 MAC91-2 MAC91-3 MAC91-4 MAC91-5 MAC91-6 MAC91-7 MAC91-8 MAC91A1 MAC91A2 MAC91A3 MAC91A4 MAC91A5 MAC91A6 MAC91A7 MAC91A8 MAC92-1 MAC92-2 MAC92-3 MAC92-4 MAC92-5 MAC92-6 MAC92-7 MAC92-8 MAC92A1 MAC92A2 MAC92A3 MAC92A4 MAC92A5 MAC92A6 MAC92A7 MAC92A8 MAC93-1 MAC93-2 MAC93-3 MAC93-4 MAC93-5 MAC93-6 MAC93-7 MAC93-8 MAC93A1 MAC93A2 MAC93A3 MAC93A4 MAC93A5 MAC93A6 MAC93A7 MAC93A8 MAC94-1 MAC94-2 MAC94-3 MAC94-4 MAC94-5 MAC94-6
Teccor Device
Q8025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q8025P5 Q6025P5 Q6025P5 Q6025P5 Q6035P5 Q6035P5 Q6035P5 Q4008RH4 Q6008RH4 Q8008RH4 Q2X8E3 Q2X8E3 Q2X8E3 Q2X8E3 Q4X8E3 Q4X8E3 Q5X8E3 Q6X8E3 L2X8E6 L2X8E6 L2X8E6 L2X8E6 L4X8E6 L4X8E6 L6X8E6 L6X8E6 L2X8E5 L2X8E5 L2X8E5 L2X8E5 L4X8E5 L4X8E5 L6X8E5 L6X8E5 L2X8E5 L2X8E5 L2X8E5 L2X8E5 L4X8E5 L4X8E5 L6X8E5 L6X8E5 L2X8E3 L2X8E3 L2X8E3 L2X8E3 L4X8E3 L4X8E3 L6X8E3 L6X8E3 Q2X8E3 Q2X8E3 Q2X8E3 Q2X8E3 L4X8E3 L4X8E3 L6X8E3 L6X8E3 Q2X8E3 Q2X8E3 Q2X8E3 Q2X8E3 Q4X8E3 Q4X8E3
Direct or Suggested Replacement
S S S S S S S S S S S S S D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D
Teccor Package
FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL)
Part Number
MAC94-7 MAC94-8 MAC94A1 MAC94A2 MAC94A3 MAC94A4 MAC94A5 MAC94A6 MAC94A7 MAC94A8 MAC95-1 MAC95-2 MAC95-3 MAC95-4 MAC95-5 MAC95-6 MAC95-7 MAC95-8 MAC95A1 MAC95A2 MAC95A3 MAC95A4 MAC95A5 MAC95A6 MAC95A7 MAC95A8 MAC96-1 MAC96-2 MAC96-3 MAC96-4 MAC96-5 MAC96-6 MAC96-7 MAC96-8 MAC96A1 MAC96A2 MAC96A3 MAC96A4 MAC96A5 MAC96A6 MAC96A7 MAC96A8 MAC97-2 MAC97-3 MAC97-4 MAC97-5 MAC97-6 MAC97-7 MAC97-8 MAC97A2 MAC97A3 MAC97A4 MAC97A5 MAC97A6 MAC97A7 MAC97A8 MAC97B2 MAC97B3 MAC97B4 MAC97B5 MAC97B6 MAC97B7 MAC97B8 MAC9D MAC9M MAC9N MCR08BT1 MCR08DT1 MCR08MT1 MCR100-3
Teccor Device
Q6X8E3 Q6X8E3 L2X8E6 L2X8E6 L2X8E6 L2X8E6 L4X8E6 L4X8E6 L6X8E6 L6X8E6 L2X8E5 L2X8E5 L2X8E5 L2X8E5 L4X8E5 L4X8E5 L6X8E5 L6X8E5 L2X8E5 L2X8E5 L2X8E5 L2X8E5 L4X8E5 L4X8E5 L6X8E5 L6X8E5 L2X8E3 L2X8E3 L2X8E3 L2X8E3 L4X8E3 L4X8E3 L6X8E3 L6X8E3 L2X8E3 L2X8E3 L2X8E3 L2X8E3 L4X8E3 L4X8E3 L6X8E3 L6X8E3 L2X8E6 L2X8E6 L2X8E6 L4X8E6 L4X8E6 L6X8E6 L6X8E6 L2X8E5 L2X8E5 L2X8E5 L4X8E5 L4X8E5 L6X8E5 L6X8E5 L2X8E3 L2X8E3 L2X8E3 L4X8E3 L4X8E3 L6X8E3 L6X8E3 Q4008RH4 Q6008RH4 Q8008RH4 S2S S4S S6S EC103B
Direct or Suggested Replacement
D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D S S S S S S D
Teccor Package
TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) SOT-223 / COMPAK SOT-223 / COMPAK SOT-223 / COMPAK TO-92 (ISOL)
http://www.teccor.com +1 972-580-7777
A-14
(c)2002 Teccor Electronics Thyristor Product Catalog
Appendix
Cross Reference Guide
Part Number
MCR100-4 MCR100-5 MCR100-6 MCR100-7 MCR100-8 MCR101 MCR102 MCR103 MCR106-1 MCR106-2 MCR106-3 MCR106-4 MCR106-5 MCR106-6 MCR106-7 MCR106-8 MCR120 MCR12DSM MCR12DSM1 MCR12M MCR12N MCR16D MCR16M MCR16N MCR202 MCR203 MCR204 MCR206 MCR218-10FP MCR218-2 MCR218-2FP MCR218-3 MCR218-3FP MCR218-4 MCR218-4FP MCR218-5 MCR218-6 MCR218-6FP MCR218-7 MCR218-8 MCR218-8FP MCR220-5 MCR220-7 MCR220-9 MCR22-1 MCR221-5 MCR221-7 MCR221-9 MCR22-2 MCR22-3 MCR22-4 MCR225-10FP MCR225-2FP MCR225-4FP MCR225-5 MCR225-6FP MCR225-7 MCR225-8FP MCR225-9 MCR22-6 MCR22-7 MCR22-8 MCR25D MCR25M MCR25N MCR264-10 MCR264-2 MCR264-3 MCR264-4 MCR264-6
Teccor Device
EC103B EC103D EC103D EC103M EC103M EC103B EC103B EC103B T106B1 T106B1 T106B1 T106B1 T106D1 T106D1 T106M1 T106M1 EC103B S6010DS2 S6010VS2 Q6015R Q8015R Q4015R Q6015R Q8015R EC103B EC103B EC103B EC103B S8008L S2008R S2008L S2008R S2008L S2008R S2008L S4008R S4008R S4008L S6008R S6008R S6008L S4012R S6012R S8012R TCR22-4 S4016R S6016R S8016R TCR22-4 TCR22-4 TCR22-4 S8025L S2025L S2025L S4025R S4025L S6025R S6025L S8025R TCR22-6 TCR22-8 TCR22-8 S4025R S6025R S8025R S8040R S2040R S2040R S2040R S4040R
Direct or Suggested Replacement
D D D D D D D D D D D D D D D D D S S S S S S S S S S S D D D D D D D D D D D D D D D D S D D D D D D S S S S S S S S D D D D D D D D D D D
Teccor Package
TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-92 (ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-92 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL)
Part Number
MCR264-8 MCR265-10 MCR265-2 MCR265-3 MCR265-4 MCR265-6 MCR265-8 MCR3000-1 MCR3000-10 MCR3000-2 MCR3000-3 MCR3000-4 MCR3000-5 MCR3000-6 MCR3000-7 MCR3000-8 MCR3000-9 MCR310-1 MCR310-2 MCR310-3 MCR310-4 MCR310-5 MCR310-6 MCR310-7 MCR310-8 MCR506-1 MCR506-2 MCR506-3 MCR506-4 MCR506-6 MCR506-8 MCR525-1 MCR525-2 MCR525-3 MCR525-6 MCR68-1 MCR68-2 MCR68-3 MCR68-6 MCR69-1 MCR69-2 MCR69-3 MCR69-6 MCR704A MCR704A1 MCR706A MCR706A1 MCR708A MCR708A1 MCR716 MCR718 MCR72-1 MCR72-2 MCR72-3 MCR72-4 MCR72-5 MCR72-6 MCR72-7 MCR72-8 MCR8DCM MCR8DCM1 MCR8DCN MCR8DCN1 MCR8DSM MCR8DSM1 MCR8SD MCR8SM MK1V115 MK1V125 MK1V135
Teccor Device
S6040R S8055R S2055R S2055R S2055R S4055R S6055R S2008R S8008R S2008R S2008R S2008R S4008R S4008R S6008R S6008R S8008R S2010LS2 S2010LS2 S2010LS2 S2010LS2 S4010LS2 S4010LS2 S6010LS2 S6010LS2 S2006FS21 S2006FS21 S2006FS21 S2006FS21 S4006FS21 S6006FS21 S2035J S2035J S2035J S4035J S2012R S2012R S2012R S4012R S2025R S2025R S2025R S4025R S2004DS2 S2004VS2 S4004DS2 S4004VS2 S6004DS2 S6004VS2 S4004DS2 S6004DS2 S2008LS2 S2008LS2 S2008LS2 S2008LS2 S4008LS2 S4008LS2 S6008LS2 S6008LS2 S6008D S6008V S8008D S8008V S6008DS2 S6008VS2 S4008FS21 S6008FS21 K1100G K1200G K1300G
Direct or Suggested Replacement
D D D D D D D S S S S S S S S S S S S S S S S S S S S S S S S S S S S D D D D D D D D S S S S S S D D S S S S S S S S D D D D D D S S S S S
Teccor Package
TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-252 (SMT) TO-252 (SMT) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) DO-15X DO-15X DO-15X
(c)2002 Teccor Electronics Thyristor Product Catalog
A-15
http://www.teccor.com +1 972-580-7777
Cross Reference Guide
Appendix
Part Number
MK1V240 MK1V260 MK1V270 MK1V280 MKP1V120 MKP1V130 MKP1V240 MKP3V110 MKP3V120 MKP3V130 MKP9V120 MKP9V130 MKP9V240 MKP9V260 MKP9V270 MN611A P0100AA P0100AB P0100BA P0100BB P0100CA P0100CB P0100DA P0100DB P0101AA P0101AB P0101BA P0101BB P0101CA P0101CB P0101DA P0101DB P0102AA P0102AB P0102AD P0102AN P0102BA P0102BB P0102BD P0102BN P0102CA P0102CB P0102CD P0102CN P0102DA P0102DB P0102DD P0102DN P0103AA P0103AB P0103BA P0103BB P0103CA P0103CB P0103DA P0103DB P0104AA P0104AB P0104BA P0104BB P0104CA P0104CB P0104DA P0104DB P0105AA P0105AB P0105BA P0105BB P0105CA P0105CB
Teccor Device
K2400G K2500G K2500G K2500G K1200E70 K1300E70 K2400E70 K1100G K1200G K1300G K1200E70 K1300E70 K2400E70 K2500E70 K2500E70 K1050E70 EC103B1 EC103B1 EC103B1 EC103B1 EC103D1 EC103D1 EC103D1 EC103D1 EC103B1 EC103B1 EC103B1 EC103B1 EC103D1 EC103D1 EC103D1 EC103D1 EC103B EC103B EC103B78 S2S EC103B EC103B EC103B78 S2S EC103D EC103D EC103D78 S4S EC103D EC103D EC103D78 S4S EC103B EC103B EC103B EC103B EC103D EC103D EC103D EC103D EC103B2 EC103B2 EC103B2 EC103B2 EC103D2 EC103D2 EC103D2 EC103D2 EC103B2 EC103B2 EC103B2 EC103B2 EC103D2 EC103D2
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S D S D S D S D S D S D S D S D S D S S S D S S S D S S S D S S S D S D S D S D S D S D S D S D S S S S D S S
Teccor Package
DO-15X DO-15X DO-15X DO-15X TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) DO-15X DO-15X DO-15X TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) SOT223/COMPAK TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) SOT223/COMPAK TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) SOT223/COMPAK TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) SOT223/COMPAK TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL)
Part Number
P0105DA P0105DB P0110AA P0110AB P0110BA P0110BB P0110CA P0110CB P0110DA P0110DB P0111AN P0111BN P0111CN P0111DN PT20 PT40 PT60 Q2015L9 Q2015R9 Q2025L9 Q2025R9 Q2040J9 Q2040K9 Q4015L9 Q4015R9 Q4025L9 Q4025R9 Q4040J9 Q4040K9 Q5015L9 Q5015R9 Q5025L9 Q5025R9 Q5040J9 Q5040K9 Q6015L9 Q6015R9 Q6025L9 Q6025R9 Q6040J9 Q6040K9 Q7015L9 Q7015R9 Q7025L9 Q7025R9 Q7040J9 Q7040K9 Q8015L9 Q8015R9 Q8025L9 Q8025R9 Q8040J9 Q8040K9 S0402BH S0402DH S0402MH S0405BH S0405DH S0405MH S0406BH S0406DH S0406MH S0406NH S0407BH S0407DH S0407MH S0410BH S0410DH S0410MH S0410NH
Teccor Device
EC103D2 EC103D2 EC103B1 EC103B1 EC103B1 EC103B2 EC103D2 EC103D1 EC103D1 EC103D1 S2S1 S2S1 S4S1 S4S1 D2015L D4015L D6015L Q2016LH6 Q2016RH6 Q2025L6 Q2025R6 Q2040J7 Q2040K7 Q4016LH6 Q4016RH6 Q4025L6 Q4025R6 Q4040J7 Q4040K7 Q6016LH6 Q6016RH6 Q6025L6 Q6025R6 Q6040J7 Q6040K7 Q6016LH6 Q6016RH6 Q6025L6 Q6025R6 Q6040J7 Q6040K7 Q8016LH6 Q8016RH6 Q8025L6 Q8025R6 Q8040J7 Q8040K7 Q8016LH6 Q8016RH6 Q8025L6 Q8025R6 Q8040J7 Q8040K7 T106B1 T106D1 T106M1 S2006L S4006L S6006L S2006L S4006L S6006L S8006L S2006L S4006L S6006L S2006L S4006L S6006L S8006L
Direct or Suggested Replacement
S S S S S S S S S S S S S S D D D D D S S D D D D S S D D D D S S D D D D S S D D D D S S D D D D S S D D S S S D D S S S S S S S S S S S S
Teccor Package
TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) SOT223/COMPAK SOT223/COMPAK SOT223/COMPAK SOT223/COMPAK TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-218X (ISOL) TO-218AC (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-218X (ISOL) TO-218AC (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-218X (ISOL) TO-218AC (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-218X (ISOL) TO-218AC (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-218X (ISOL) TO-218AC (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-218X (ISOL) TO-218AC (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL)
http://www.teccor.com +1 972-580-7777
A-16
(c)2002 Teccor Electronics Thyristor Product Catalog
Appendix
Cross Reference Guide
Part Number
S0417BH S0417DH S0417MH S0417NH S0602BH S0602DH S0602MH S0605BH S0605DH S0605MH S0606BH S0606DH S0606MH S0606NH S0607BH S0607DH S0607MH S0610BH S0610DH S0610MH S0610NH S0617BH S0617DH S0617MH S0617NH S0802BH S0802DH S0802MH S0805BH S0805DH S0805MH S0806BH S0806DH S0806MH S0806NH S0807BH S0807DH S0807MH S0807NH S0810BH S0810DH S0810MH S0810NH S0817BH S0817DH S0817MH S0817NH S1005BH S1005DH S1005MH S1006BH S1006DH S1006MH S1006NH S1007BH S1007DH S1007MH S1010BH S1010DH S1010MH S1010NH S1017BH S1017DH S1017MH S1017NH S106A1 S106B1 S106C1 S106D1 S106E1
Teccor Device
S2006L S4006L S6006L S8006L S2006LS2 S4006LS2 S6006LS2 S2006L S4006L S6006L S2006L S4006L S6006L S8006L S2006L S4006L S6006L S2006L S4006L S6006L S8006L S2006L S4006L S6006L S8006L S2008LS2 S4008LS2 S6008LS2 S2006R S4006R S6008R S2008R S4008R S6008R S8008R S2008R S4008R S6008R S8008R S2008R S4008R S6008R S8008R S2008R S4008R S6008R S8008R S2010R S4010R S6010R S2010R S4010R S6010R S8010R S2010R S4010R S6010R S2010R S4010R S6010R S8010R S2010R S4010R S6010R S8010R T106B1 T106B1 T106D1 T106D1 T106M1
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S D D D D D
Teccor Package
TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
Part Number
S106F1 S106M1 S106Y1 S107A1 S107B1 S107C1 S107D1 S107E1 S107F1 S107M1 S107Q1 S107Y1 S1205BH S1205DH S1205MH S1206BH S1206DH S1206MH S1206NH S1207BH S1207DH S1207MH S1210BH S1210DH S1210MH S1210NH S1217BH S1217DH S1217MH S1217NH S1610BH S1610DH S1610MH S1610NH S1612BH S1612DH S1612MH S1612NH S1616BH S1616DH S1616MH S1616NH S1A S1B S1D S1M S1Y S1YY S2060A S2060B S2060C S2060D S2060E S2060F S2060M S2060Y S2061A S2061B S2061C S2061D S2061E S2061F S2061Q S2061Y S2062A S2062B S2062C S2062D S2062E S2062F
Teccor Device
T106B1 T106M1 T106B1 T107B1 T107B1 T107D1 T107D1 T107M1 T107B1 T107M1 T107B1 T107B1 S2012R S4012R S6012R S2012R S4012R S6012R S8012R S2012R S4012R S6012R S2012R S4012R S6012R S8012R S2012R S4012R S6012R S8012R S2016R S4016R S6016R S8016R S2016R S4016R S6016R S8016R S2016R S4016R S6016R S8016R EC103B EC103B EC103D EC103M EC103B EC103B S2006LS2 S2006LS2 S4006LS2 S4006LS2 S6006LS2 S2006LS2 S6006LS2 S2006LS2 S2006LS3 S2006LS3 S4006LS3 S4006LS3 S6006LS3 S2006LS3 S2006LS3 S2006LS3 S2006LS3 S2006LS3 S4006LS3 S4006LS3 S6006LS3 S2006LS3
Direct or Suggested Replacement
D D D D D D D D D D D D S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S D D D D S D S S S S S S S S S S S S S S S S S S S S S S
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL)
(c)2002 Teccor Electronics Thyristor Product Catalog
A-17
http://www.teccor.com +1 972-580-7777
Cross Reference Guide
Appendix
Part Number
S2062M S2062Q S2062Y S2512BH S2512BK S2512DH S2512DK S2512MH S2512MK S2512NH S2512NK S2514BH S2514BK S2514DH S2514DK S2514MH S2514MK S2514NH S2514NK S2516BH S2516DH S2516MH S2516NH S2600B S2600D S2600M S2800A S2800B S2800C S2800D S2800E S2800F S2800M S2800N S3014NH S3016NH S4012BH S4012BK S4012DH S4012DK S4012MH S4012MK S4012NH S4012NK S4014BH S4014BK S4014DH S4014DK S4014MH S4014MK S4014NH S4014NK S4016BH S4016DH S4016MH S4016NH S4060A S4060B S4060C S4060D S4060F S4060U S5800B S5800C S5800D S5800E S5800M SC129B SC129D SC129E
Teccor Device
S6006LS3 S2006LS3 S2006LS3 S2025R S2035J S4025R S4035J S6025R S6035J S8025R S8035J S2025R S2035J S4025R S4035J S6025R S6035J S8025R S8035J S2025R S4025R S6025R S8025R S2006L S4006L S6006L S2010R S2010R S4010R S4010R S6010R S2010R S6010R S8010R S8040R S8040R S2040R S2035J S4040R S4035J S6040R S6035J S8040R S8035J S2040R S2035J S4040R S4035J S6040R S6035J S8040R S8065J S2040R S4040R S6040R S8040R S2010LS2 S2010LS2 S4010LS2 S4010LS2 S2010LS2 S2010LS2 S2008R S4008R S4008R S6008R S6008R Q2025R5 Q4025R5 Q6025R5
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S D D S D S D D D S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S D D D
Teccor Package
TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-218 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL)
Part Number
SC129M SC136A SC136B SC136C SC136D SC136E SC136M SC140B SC140D SC140E SC140M SC141A SC141B SC141C SC141D SC141E SC141M SC141N SC142B SC142D SC142E SC142M SC143B SC143D SC143E SC143M SC146B SC146D SC146E SC146M SC146N SC147B SC147D SC147E SC147M SC148B SC148D SC148E SC148M SC149B SC149D SC149E SC149M SC150B SC150D SC150E SC150M SC151B SC151D SC151E SC151M SC160B SC160D SC160E SC160M SC92A SC92B SC92D SC92F SF0R1A42 SF0R1B42 SF0R1D42 SF0R1G42 SF0R3B42 SF0R3D42 SF0R3G42 SF0R3J42 SF0R5B43 SF0R5D43 SF0R5G43
Teccor Device
Q6025R5 Q2004F41 Q2004F41 Q4004F41 Q4004F41 Q5004F41 Q6004F41 Q2006L4 Q4006L4 Q6006L4 Q6006L5 Q2006R4 Q2006R4 Q4006R4 Q4006R4 Q6006R4 Q6006R5 Q8006R5 Q2008L4 Q4008L4 Q6008L4 Q6008L5 Q2008R4 Q4008R4 Q6008R4 Q6008R5 Q2010R5 Q4010R5 Q6010R5 Q6010R5 Q8010R5 Q2010L5 Q4010L5 Q6010L5 Q6010L5 Q2010L5 Q4010L5 Q6010L5 Q6010L5 Q2015R5 Q4015R5 Q6015R5 Q6015R5 Q2015L5 Q4015L5 Q6015L5 Q6015L5 Q2015R5 Q4015R5 Q6015R5 Q6015R5 Q6025P5 Q6025P5 Q6025P5 Q6025P5 Q201E3 Q201E3 Q401E3 Q201E3 EC103B EC103B EC103B EC103D EC103B EC103B EC103D EC103M EC103B EC103B EC103D
Direct or Suggested Replacement
D S S S S S S D D D D S D S D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D S S S S D D D D S S S S S S S S S S S
Teccor Package
TO-220 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL)
http://www.teccor.com +1 972-580-7777
A-18
(c)2002 Teccor Electronics Thyristor Product Catalog
Appendix
Cross Reference Guide
Part Number
SF0R5H43 SF0R5J43 SF10D41A SF10G41A SF10J41A SF1B12 SF1D12 SF1G12 SF3B41 SF3B42 SF3D41 SF3D42 SF3D42C SF3G41 SF3G42 SF3G42C SF3H42LC2 SF3J41 SF3J42 SF5B41 SF5B42 SF5D41 SF5D41A SF5D42 SF5G41 SF5G41A SF5G42 SF5J41 SF5J41A SF5J42 SF8B41 SF8D41 SF8D41A SF8G41 SF8G41A SF8J41 SF8J41A SM0R5B42 SM0R5D42 SM0R5G42 SM12D41 SM12G41 SM12J41 SM16DZ41 SM16G45 SM16G45A SM16GZ41 SM16GZ47 SM16GZ47A SM16J45 SM16J45A SM16JZ41 SM16JZ47 SM16JZ47A SM1D43 SM1G43 SM25DZ41 SM25GZ41 SM25JZ41 SM2B41 SM2D41 SM2G41 SM3B41 SM3D41 SM3G41 SM3G45 SM3GZ46 SM3J41 SM3J45 SM3JZ46
Teccor Device
EC103M EC103M S2016R S4016R S6016R TR22-4 TR22-4 TR22-6 S2006F1 T106B1 S2006F1 T106B1 T106B1 S4006F1 T106D1 T106D1 T106M2 S6006F1 T106M1 S2008R S2008FS21 S2008R S2012R S2008FS21 S4008R S6012R S4008FS21 S6008R S6012R S6008FS21 S2012R S2012R S2012R S4012R S4012R S6012R S6012R Q2X8E3 Q2X8E3 Q4X8E3 Q2012RH5 Q4012RH5 Q6012RH5 Q2025P5 Q4016RH4 Q4016RH3 Q4025P5 Q4016LH4 Q4016LH3 Q6016RH4 Q6016RH3 Q6025P5 Q6016LH4 Q6016LH3 L201E6 L401E6 Q2025P5 Q4025P5 Q6025P5 Q2004F31 Q2004F31 Q4004F31 Q2004F41 Q2004F41 Q4004F41 Q4004L3 Q4004L3 Q6004F41 Q6004L3 Q6004L3
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S D S S D S
Teccor Package
TO-92 (ISOL) TO-92 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-39/TO-92 (ISOL) TO-39/TO-92 (ISOL) TO-39/TO-92 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) FASTPAK (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) FASTPAK (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) FASTPAK (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-92 (ISOL) TO-92 (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-202 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL)
Part Number
SM6D45 SM6D45A SM6DZ46 SM6DZ46A SM6G45 SM6G45A SM6GZ46 SM6GZ46A SM6GZ47 SM6GZ47A SM6J45 SM6J45A SM6JZ46 SM6JZ46A SM6JZ47 SM6JZ47A SM8D41 SM8D45 SM8D45A SM8DZ46 SM8DZ46A SM8G41 SM8G45 SM8G45A SM8GZ46 SM8GZ46A SM8GZ47 SM8GZ47A SM8J41 SM8J45 SM8J45A SM8JZ46 SM8JZ46A SM8JZ47 SM8JZ47A ST2 T0505MH T0509MH T0510DH T0510MH T0605DH T0605MH T0609DH T0609MH T0612BH T0612DH T0612MH T0805DH T0805MH T0809DH T0809MH T0810DH T0810MH T0810NH T0810SH T0812DH T0812MH T0812NH T0812SH T1010BH T1010BJ T1010DH T1010DJ T1010MH T1010MJ T1010NH T1010NJ T1012BH T1012BJ T1012DH
Teccor Device
Q2006R4 Q2006R4 Q2006L4 Q2006L4 Q4006R4 Q4006R4 Q4006L4 Q4006L4 Q4006L4 Q4006L4 Q6006R4 Q6006R4 Q6006L4 Q6006L4 Q6006L4 Q6006L4 Q2008R4 Q2010R4 L2008L8 Q2010L4 L2008L8 Q4008R4 Q4010R4 L4008L8 Q4010L4 L4008L8 Q4008LH4 Q4008LH4 Q6008R5 Q6010R4 L6008L8 Q6010L4 L6008L8 Q6008LH4 Q6008LH4 HT32 L6006L5 L6006L6 L4006L8 L6006L8 L4006L5 L6006L5 L4006L6 L6006L6 Q2004R4 Q4006R4 Q6006R5 L4008L6 L6008L6 L4008L8 L6008L8 Q4008R4 Q6008R5 Q8008R5 Q8008R5 Q4008R4 Q6008R5 Q8008R5 Q8008R5 Q2010R5 Q2010L5 Q4010R5 Q4010L5 Q6010R5 Q6010L5 Q8010R5 Q8010L5 Q2010R5 Q2010L5 Q4010R5
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S D S S S S D S S S S S S D S S S S S S D S S S S S S S S D D D S S S S S S S S S S S S S D S D S D S D D D D
Teccor Package
TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) DO-35 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL)
(c)2002 Teccor Electronics Thyristor Product Catalog
A-19
http://www.teccor.com +1 972-580-7777
Cross Reference Guide
Appendix
Part Number
T1012DJ T1012MH T1012MJ T1012NH T1012NJ T1013BH T1013BJ T1013DH T1013DJ T1013MH T1013MJ T1013NH T1013NJ T106A1SC T106A1SD T106A1SG T106A1SH T106A1SHA T106A1SS T106A2SS T106B1SC T106B1SD T106B1SG T106B1SGA T106B1SH T106B1SHA T106B1SS T106B2SD T106B2SG T106B2SGA T106B2SH T106B2SHA T106B2SS T106C1SC T106C1SD T106C1SG T106C1SGA T106C1SH T106C1SHA T106C1SS T106C2SD T106C2SG T106C2SGA T106C2SH T106C2SHA T106C2SS T106D1SC T106D1SD T106D1SG T106D1SGA T106D1SH T106D1SHA T106D1SS T106D2SD T106D2SG T106D2SGA T106D2SH T106D2SHA T106D2SS T106E1SC T106E1SD T106E1SG T106E1SGA T106E1SH T106E1SHA T106E1SS T106E2SD T106E2SG T106E2SGA T106E2SH
Teccor Device
Q4010L5 Q6010R5 Q6010L5 Q8010R5 Q8010L5 Q2010R5 Q2010L5 Q4010R5 Q4010L5 Q6010R5 Q6010L5 Q8010R5 Q8010L5 L2004F31 L2004F51 L2004F61 L2004F81 Q2004F41 L2004F31 L2004F32 L2004F31 L2004F51 L2004F61 Q2004F31 L2004F81 Q2004F41 L2004F31 L2004F52 L2004F62 Q2004F32 L2004F82 Q2004F42 L2004F32 L4004F31 L4004F51 L4004F61 Q4004F31 L4004F81 Q4004F41 L4004F31 L4004F52 L4004F62 Q4004F32 L4004F82 Q4004F42 L4004F32 L4004F31 L4004F51 L4004F61 Q4004F31 L4004F81 Q4004F41 L4004F31 L4004F52 L4004F62 Q4004F32 L4004F82 Q4004F42 L4004F32 L6004F31 L6004F51 L6004F61 Q6004F31 L6004F81 Q6004F41 L6004F31 L6004F52 L6004F62 Q6004F32 L6004F82
Direct or Suggested Replacement
D D D S S D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D
Teccor Package
TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
Part Number
T106E2SHA T106E2SS T106F1SC T106F1SD T106F1SG T106F1SGA T106F1SH T106F1SHA T106F1SS T106F2SC T106F2SD T106F2SG T106F2SGA T106F2SH T106F2SHA T106F2SS T106M1SD T106M1SG T106M1SGA T106M1SH T106M1SHA T106M1SS T106M2SD T106M2SG T106M2SGA T106M2SH T106M2SHA T106M2SS T1210BH T1210DH T1210MH T1210NH T1212BH T1212BJ T1212DH T1212DJ T1212MH T1212MJ T1212NH T1212NJ T1213BH T1213BJ T1213DH T1213DJ T1213MH T1213MJ T1213NH T1213NJ T1235-600G T1235-800G T1512BJ T1512DJ T1512MJ T1512NJ T1513BJ T1513DJ T1513MJ T1513NJ T1612BH T1612DH T1612MH T1612NH T1612NJ T1613BH T1613DH T1613MH T1613NH T1635-600G T1635-800G T2300A
Teccor Device
Q6004F42 L4004F32 L2004F31 L2004F51 L2004F61 Q2004F31 L2004F81 Q2004F41 L2004F31 L2004F32 L2004F52 L2004F62 Q2004F32 L2004F82 Q2004F42 L2004F32 L6004F51 L6004F61 Q6004F31 L6004F81 Q6004F41 L6004F31 L6004F52 L6004F62 Q6004F32 L6004F82 Q6004F42 L6004F32 Q2015R5 Q4015R5 Q6015R5 Q8015R5 Q2015R5 Q4015L5 Q4015R5 Q4015L5 Q6015R5 Q6015L5 Q8015R5 Q8015L5 Q2015R5 Q4015L5 Q4015R5 Q4015L5 Q6015R5 Q6015L5 Q8015R5 Q8015L5 Q6012NH5 Q8012NH5 Q2015L5 Q4015L5 Q6015L5 Q8015L5 Q2015L5 Q4015L5 Q6015L5 Q8015L5 Q2015R5 Q4015R5 Q6015R5 Q8015R5 Q8015L5 Q2015R5 Q4015R5 Q6015R5 Q8015R Q6016NH4 Q8016NH4 L2004F321
Direct or Suggested Replacement
D D D D D D D D D D D D D D D D D D D D D D D D D D D D S S S S D D D D D D D D D D D D D D D D S S D D D D D D D D D D D D D D D D S D D S
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-263 (SMT) TO-263 (SMT) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-263 (SMT) TO-263 (SMT) TO-202 (N.ISOL)
http://www.teccor.com +1 972-580-7777
A-20
(c)2002 Teccor Electronics Thyristor Product Catalog
Appendix
Cross Reference Guide
Part Number
T2300B T2300D T2300F T2300PA T2300PB T2300PC T2300PD T2300PE T2300PF T2300PM T2301A T2301B T2301D T2301F T2301PA T2301PB T2301PC T2301PD T2301PE T2301PF T2301PM T2302A T2302B T2302D T2302F T2302PA T2302PB T2302PC T2302PD T2302PE T2302PF T2302PM T2303F T2306A T2306B T2306D T2310A T2310B T2310D T2310F T2311A T2311B T2311D T2311F T2312A T2312B T2312D T2312F T2313A T2313B T2313D T2313F T2316A T2316B T2316D T2320A T2320B T2320C T2320D T2320E T2320F T2320M T2322A T2322B T2322C T2322D T2322E T2322F T2322M T2323A
Teccor Device
L2004F321 L4004F321 L2004F321 L2004F31 L2004F31 L4004F31 L4004F31 L6004F31 L2004F31 L6004F31 L2004F321 L2004F321 L4004F321 L2004F321 L2004F31 L2004F31 L4004F31 L4004F31 L6004F31 L2004F31 L6004F31 L2004F621 L2004F621 L4004F621 L2004F621 L2004F61 L2004F61 L4004F61 L4004F61 L6004F61 L2004F61 L6004F61 Q2004F421 Q2004F421 Q2004F421 Q4004F421 L2004F321 L2004F321 L4004F321 L2004F321 L2004F321 L2004F321 L4004F321 L2004F321 L2004F621 L2004F621 L4004F621 L2004F621 Q2004F421 Q2004F421 Q4004F421 Q2004F421 Q2004F421 Q2004F421 Q4004F421 L2004F31 L2004F31 L4004F31 L4004F31 L6004F31 L2004F31 L6004F31 L2004F61 L2004F61 L4004F61 L4004F61 L6004F61 L2004F61 L6004F61 L2004F81
Direct or Suggested Replacement
S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S D D D D D D D D D D D D D D D
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
Part Number
T2323B T2323C T2323D T2323E T2323F T2323M T2327A T2327B T2327C T2327D T2327E T2327F T2327M T2500A T2500AFP T2500B T2500BFP T2500C T2500CFP T2500D T2500DFP T2500E T2500EFP T2500M T2500MFP T2500N T2500NFP T2500S T2500SFP T2506B T2506D T2512BH T2512BK T2512DH T2512DK T2512MH T2512MK T2512NH T2512NK T2513BH T2513BK T2513DH T2513DK T2513MH T2513MK T2513NH T2513NK T2535-600G T2535-800G T2700B T2700D T2800A T2800B T2800C T2800D T2800E T2800M T2801A T2801B T2801C T2801D T2801E T2801M T2801N T2801S T2802A T2802B T2802C T2802D T2802E
Teccor Device
L2004F81 L4004F81 L4004F81 L6004F81 L2004F81 L6004F81 L2004F51 L2004F51 L4004F51 L4004F51 L6004F51 L2004F51 L6004F51 Q2006R4 Q2006L4 Q2006R4 Q2006L4 Q4006R4 Q4006L4 Q4006R4 Q4006L4 Q6006R4 Q6006L4 Q6006R5 Q6006L5 Q8006R5 Q8006L5 Q8006R5 Q8006L5 Q2006R4 Q4006R4 Q2025R5 Q6025P5 Q4025R5 Q6025P5 Q6025R5 Q6025P5 Q8025R5 Q8025P5 Q2025R5 Q6025P5 Q4025R5 Q6025P5 Q6025R5 Q6025P5 Q8025R5 Q8025P5 Q6025NH6 Q8025NH6 Q2006R4 Q4006R4 Q2008R4 Q2008R4 Q4008R4 Q4008R4 Q6008R4 Q6008R5 Q2006R4 Q2006R4 Q4006R4 Q4006R4 Q6006R4 Q6006R5 Q8006R5 Q8006R5 Q2008R4 Q2008R4 Q4008R4 Q4008R4 Q6008R4
Direct or Suggested Replacement
D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D S S S S S S S S S S S S S S S S S S S S S S S S S S D D D D D D D D S S S S S
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) FASTPAK (ISOL) TO-220 (N.ISOL) FASTPAK (ISOL) TO-220 (N.ISOL) FASTPAK (ISOL) TO-220 (N.ISOL) FASTPAK (ISOL) TO-220 (N.ISOL) FASTPAK (ISOL) TO-220 (N.ISOL) FASTPAK (ISOL) TO-220 (N.ISOL) FASTPAK (ISOL) TO-220 (N.ISOL) FASTPAK (ISOL) TO-263 (SMT) TO-263 (SMT) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL)
(c)2002 Teccor Electronics Thyristor Product Catalog
A-21
http://www.teccor.com +1 972-580-7777
Cross Reference Guide
Appendix
Part Number
T2802M T2806B T2806D T2806M T2850A T2850B T2850D T2850E T2850F T2856B T2856D T4012DKS T4012MKS T4012NKS T4012SKS T4013DKS T4013MKS T4013NKS T4013SKS T405-400T T405-400W T405-600B T405-600H T405-600T T405-600W T410-400T T410-400W T410-600B T410-600H T410-600T T410-600W T435-400T T435-400W T435-600B T435-600H T435-600T T435-600W T435-700T T435-700W T435-800T T435-800W T6000B T6000D T6000M T6001B T6001D T6001M T6006B T6006D T6006M T620-400W T620-600W T620-700W T630-400W T630-600W T630-700W T810-400B T810-600B T820-400W T820-600W T820-700W T830-400W T830-600W T830-700W T835-600B T835-600G T850-600G TIC106D TIC106M TIC108D
Teccor Device
Q6008R5 Q2008R4 Q4008R4 Q6008R5 Q2008L4 Q2008L4 Q4008L4 Q6008L4 Q2008L4 Q2008L4 Q4008L4 Q6035P5 Q6035P5 Q8035P5 Q8035P5 Q6035P5 Q6035P5 Q8035P5 Q8035P5 L4004L6 L4004L6 L6004D6 L6004V6 L6004L6 L6004L6 L4004L8 L4004L8 L6006DH3 L6006VH3 L6004L8 L6004L8 Q4006RH4 Q4006LH4 Q6006DH4 Q6006VH4 Q6006RH4 Q6006LH4 Q8006RH4 Q8006LH4 Q8006RH4 Q8006LH4 Q2015R5 Q4015R5 Q6015R5 Q2015R5 Q4015R5 Q6015R5 Q2015R5 Q4015R5 Q6015R5 Q4006LH4 Q6006LH4 Q8006LH4 Q4006LH4 Q6006LH4 Q8006LH4 Q4008DH3 Q6008DH3 Q4008LH4 Q6008LH4 Q8008LH4 Q4008LH4 Q6008LH4 Q8008LH4 Q6008DH4 Q6008NH4 Q6010NH5 T106D1 T106M1 T107D1
Direct or Suggested Replacement
S D D S D D D D D D D S S S S S S S S S D S S S D S D S S S D D D S S D D D D D D D D D D D D S S S S S S S S S D D S S S S S S D D D S S S
Teccor Package
TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) FASTPAK (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-252 (SMT) TO-252 (SMT) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-252 (SMT) TO-263 (SMT) TO-263 (SMT) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL)
Part Number
TIC108M TIC116D TIC116M TIC116N TIC116S TIC126D TIC126M TIC126N TIC126S TIC201D TIC201M TIC206D TIC206M TIC216D TIC216M TIC225D TIC225M TIC226D TIC226M TIC226N TIC226S TIC236D TIC236M TIC236N TIC236S TIC246D TIC246M TIC246N TIC246S TIC256D TIC256D TIC256M TIC256N TIC256S TICP106D TICP106M TL1003 TL1006 TL106-05 TL106-1 TL106-2 TL106-4 TL106-6 TL107-05 TL107-1 TL107-2 TL107-4 TL107-6 TL2003 TL2006 TL4003 TL4006 TL6003 TL6006 TLC111A TLC111B TLC111D TLC111S TLC111T TLC113B TLC1165 TLC116A TLC116B TLC116D TLC116T TLC221A TLC221B TLC221D TLC221S TLC221T
Teccor Device
T107M1 S4008R S6008R S8008R S8008R S4012R S6012R S8012R S8012R L4004F61 L6004F61 L4004F61 L6004F61 L4006F61 L6006F61 L4008F61 L6008F61 Q4008R4 Q6008R5 Q8008R5 Q8008R5 Q4015R5 Q6015R5 Q8015R5 Q8015R5 Q4015R5 Q6015R5 Q8015R5 Q8015R5 Q4025R5 Q4025R5 Q6025R5 Q8025R5 Q7025R5 TCR22-4 TCR22-8 S2006F2 S2006F2 T106B2 T106B2 T106B2 T106D2 T106M2 T107B2 T107B2 T107B2 T107D2 T107M2 S2006F2 S2006F2 S4006F2 S4006F2 S6006F2 S6006F2 L2004F62 Q2004F42 L2004F52 L2004F62 L2004F52 Q2004F42 L2004F62 L2004F62 Q2004F42 L2004F52 L2004F52 L4004F62 Q4004F42 L4004F52 L4004F62 L4004F52
Direct or Suggested Replacement
S D D D D D D D D S S S S S S S S D D D D D D D D S S S S S S S S S S S S S D D D D D D D D D D S S S S S S D D D D D D D D D D D D D D D D
Teccor Package
TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-92 TO-92 TO-202 (N.ISOL) ? TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
http://www.teccor.com +1 972-580-7777
A-22
(c)2002 Teccor Electronics Thyristor Product Catalog
Appendix
Cross Reference Guide
Part Number
TLC223A TLC223B TLC223D TLC226A TLC226B TLC226D TLC226S TLC226T TLC331A TLC331B TLC331D TLC331S TLC331T TLC333A TLC333B TLC333D TLC336A TLC336B TLC336D TLC336S TLC336T TLC386B TLS106-05 TLS106-1 TLS106-2 TLS106-4 TLS106-6 TLS107-05 TLS107-1 TLS107-2 TLS107-4 TLS107-6 TN1215-600B TN1215-600H TN1215-800B TN1215-800H TN1625-1000G TN1625-600G TN1625-800G TN815-600B TN815-600H TN815-800B TN815-800H TO1013BJ TO1013DJ TO1013MJ TO1013NJ TO409BJ TO409DJ TO409MJ TO410BJ TO410DJ TO410MJ TO505BH TO505DH TO509BH TO509DH TO510BH TO512BH TO512DH TO512MH TO605BH TO605DH TO605MH TO609BH TO609BJ TO609DH TO609DJ TO609MH TO609MJ
Teccor Device
L4004F62 Q4004F42 L4004F52 L4004F62 Q4004F42 L4004F52 L4004F62 L4004F52 L6004F62 Q6004F42 L6004F52 L6004F62 L6004F52 L6004F62 Q6004F42 L6004F52 L6004F62 Q6004F42 L6004F52 L6004F62 L6004F52 Q7004F42 T106B2 T106B2 T106B2 T106D2 T106M2 T107B2 T107B2 T107B2 T107D2 T107M2 S6012D S6012V S8012D S8012V SK016N S6016N S8016N S6008D S6008V S8008D S8008V Q2010L5 Q4010L5 Q6010L5 Q8010L5 L2004L6 L4004L6 L6004L6 L2004L8 L4004L8 L6004L8 L2006L5 L4006L5 L2006L6 L2006L6 L2006L8 Q2006R4 Q4006R4 Q6006R5 L2006L5 L4006L5 L6006L5 L2006L6 L2006L6 L4006L6 L4006L6 L6006L6 L6006L6
Direct or Suggested Replacement
D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D D S S S S S S S D D D D D D D D D D D D D D S S S S S D D S S S S S D S D S D
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-263 (SMT) TO-263 (SMT) TO-263 (SMT) TO-252 (SMT) TO-251 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL)
Part Number
TO610BH TO610BJ TO610DH TO610DJ TO610MH TO610MJ TO612BJ TO612DJ TO612MJ TO805BH TO805DH TO805MH TO809BH TO809DH TO809MH TO810BH TO810BJ TO810DH TO810DJ TO810MH TO810MJ TO812BH TO812BJ TO812DH TO812DJ TO812MH TO812MJ TO812NH TO813BJ TO813DJ TO813MJ TO813NJ TPDV125 TPDV140 TPDV225 TPDV240 TPDV425 TPDV-440 TPDV625 TPDV-640 TPDV825 TPDV-840 TS420-400T TS420-600B TS420-600H TS420-600T TS820-400T TS820-600B TS820-600H TS820-600T TXDV-212 TXDV-412 TXDV612 TXDV812 TXN0510 TXN0512 TXN056 TXN058 TXN058G TXN106 TXN108 TXN108G TXN110 TXN112 TXN204 TXN206 TXN208 TXN208G TXN210 TXN212
Teccor Device
L2006L8 L2006L8 L4006L8 L4006L8 L6006L8 L6006L8 Q2006L4 Q4006L4 Q6006L5 L2008L6 L4008L6 L6008L6 L2008L6 L4008L6 L6008L6 L2008L8 L2008L8 L4008L8 L4008L8 L6008L8 L6008L8 Q2008R4 Q2008L4 Q4008R4 Q4008L4 Q6008R5 Q6008L5 Q8008L5 Q2008L4 Q4008L4 Q6008L5 Q8008L5 Q2025L6 Q2040K7 Q2025L6 Q2040K7 Q4025L6 Q4040J7 Q6025L6 Q6040K7 Q8025L6 Q8040K7 T106D1 S6004DS2 S6004VS2 T106M1 S4008FS21 S6008DS2 S6008VS2 S6008FS21 Q2015L6 Q4015L6 Q6015L6 Q8015L6 S2010L S2015L S2006L S2008L S2008L S2006L S2008L S2008L S2010L S2015L S2006L S2006L S2008L S2008L S2010L S2015L
Direct or Suggested Replacement
S D S D S D S S S S S S S S S S D S D S D S S S S S S S S S S S S D S D S D S D S D S S S S S S S S D D D D D S D D D D S D D S S D D D D S
Teccor Package
TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-218 (ISOL) TO-220 (ISOL) TO-218 (ISOL) TO-220 (ISOL) TO-218 (ISOL) TO-220 (ISOL) TO-218 (ISOL) TO-220 (ISOL) TO-218 (ISOL) TO-202 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-252 (SMT) TO-251 (N.ISOL) TO-202 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL)
(c)2002 Teccor Electronics Thyristor Product Catalog
A-23
http://www.teccor.com +1 972-580-7777
Cross Reference Guide
Appendix
Part Number
TXN404 TXN406 TXN408 TXN408G TXN410 TXN412 TXN604 TXN606 TXN608 TXN608G TXN610 TXN612 TXN812 TYN0510 TYN0512 TYN0516 TYN054 TYN056 TYN058 TYN058G TYN058K TYN104 TYN106 TYN108 TYN108G TYN110 TYN112 TYN116 TYN204 TYN206 TYN208 TYN208G TYN208K TYN210 TYN212 TYN216 TYN404 TYN406 TYN408 TYN408G TYN408K TYN410 TYN412 TYN416 TYN604 TYN606 TYN608 TYN608G TYN608K TYN610 TYN612 TYN616 TYN682 TYN683 TYN685 TYN688 TYN690 TYN808 TYN808G TYN808K TYN810 TYN812 TYN816 TYS1006-05 TYS1006-1 TYS1006-2 TYS1006-4 TYS1007-05 TYS1007-1 TYS1007-2
Teccor Device
S4006L S4006L S4008L S4008L S4010L S4015L S6006L S6006L S6008L S6008L S6010L S6015L S8015L S2010R S2012R S2016R S2006F1 S2006F1 S2008R S2008R S2008R S2006F1 S2006F1 S2008R S2008R S2010R S2012R S2016R S2006F1 S2006F1 S2008R S2008R S2008R S2010R S2012R S2016R S4006F1 S4006F1 S4008R S4008R S4008R S4010R S4012R S4016R S6006F1 S6006F1 S6008R S6008R S6008R S6010R S6012R S6016R S2025R S2025R S2025R S4025R S6025R S8008R S8008R S8008R S8010R S8012R S8016R S2010LS2 S2010LS2 S2010LS2 S4010LS2 S2010LS3 S2010LS2 S2010LS2
Direct or Suggested Replacement
S D D D D S S D D D D S S D D D S S D S S S S D S D D D S S D S S D D D S S D S S D S D S S D S S D D D D D D D D D S S S D D S S S S S S S
Teccor Package
TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL)
Part Number
TYS1007-4 TYS406-05 TYS406-1 TYS406-2 TYS406-4 TYS406-6 TYS407-05 TYS407-1 TYS407-2 TYS407-4 TYS407-6 TYS606-05 TYS606-1 TYS606-2 TYS606-4 TYS606-6 TYS607-05 TYS607-1 TYS607-2 TYS607-4 TYS607-6 TYS806-05 TYS806-1 TYS806-2 TYS806-4 TYS806-6 TYS807-05 TYS807-1 TYS807-2 TYS807-4 TYS807-6 X0101BA X0101DA X0101MA X0102BA X0102DA X0102MA X0103BA X0103DA X0103MA X0104BA X0104DA X0104MA X0105BA X0105DA X0105MA X0106BA X0106DA X0106MA X0110BA X0110DA X0110MA X0202BA X0202DA X0202MA X0203BA X0203DA X0203MA X0204BA X0204DA X0204MA X0205BA X0205DA X0205MA X0206BA X0206DA X0402BE X0402BF X0402DE X0402DF
Teccor Device
S4010LS2 T106B1 T106B1 T106B1 T106D1 T106M1 T107B1 T107B1 T107B1 T107D1 T107M1 S2006LS2 S2006LS2 S2006LS2 S4006LS2 S6006LS2 S2006LS3 S2006LS3 S2006LS3 S4006LS3 S6006LS3 S2008LS2 S2008LS2 S2008LS2 S4008LS2 S6008LS2 S2008LS3 S2008LS3 S2008LS3 S4008LS3 S6008LS3 EC103B1 EC103D1 EC103M1 EC103B EC103D EC103M EC103B EC103D EC103M EC103B2 EC103D2 EC103M2 EC103B2 EC103D2 EC103M2 EC103B EC103D EC103M EC103B1 EC103D1 EC103M1 TCR22-4 TCR22-6 TCR22-8 TCR22-4 TCR22-6 TCR22-8 TCR22-4 TCR22-6 TCR22-8 EC103B2 EC103D2 EC103M2 TCR22-4 TCR22-6 T106B1 T106B2 T106D1 T106D2
Direct or Suggested Replacement
S S S S S S S S S S S D D D D S D D D D S D D D D S D D D D S S S S S S S S S S D D D S S S S S S S S S D D D S S S S S S S S S S S D D D D
Teccor Package
TO-220 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-220 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
http://www.teccor.com +1 972-580-7777
A-24
(c)2002 Teccor Electronics Thyristor Product Catalog
Appendix
Cross Reference Guide
Part Number
X0402DG X0402ME X0402MF X0403BE X0403BF X0403DE X0403DF X0403ME X0403MF X0405BE X0405BF X0405DE X0405DF X0405ME X0405MF Z00607DA Z00607MA Z0102BA Z0102DA Z0102MA Z0103DN Z0103MN Z0105BA Z0105DA Z0105MA Z0107DN Z0107MN Z0109BA Z0109DA Z0109MA Z0110DA Z0110MA Z0302BG Z0302DG Z0302MG Z0305BG Z0305DG Z0309BG Z0309DG Z0310BG Z0310DG Z0310MG Z0405BE Z0405BF Z0405DE Z0405DF Z0405ME Z0405MF Z0409BE Z0409BF Z0409DE Z0409DF Z0409ME Z0409MF Z0410BE Z0410BE Z0410BF Z0410BF Z0410DE Z0410DE Z0410DF Z0410ME Z0410MF
Teccor Device
T106D1 T106M1 T106M2 T106B1 T106B2 T106D1 T106D2 T106M1 T106M2 T106B1 T106B2 T106D1 T106D2 T106M1 T106M2 L4X8E5 L6X8E5 L201E3 L401E3 L601E3 L4N3 L6N3 L201E5 L401E5 L601E5 L4N5 L6N5 L201E6 L401E6 L601E6 L401E8 L601E8 L2004F321 L4004F321 L6004L3 L2004F521 L4004F521 L2004F621 L4004F621 L2004F821 L4004F821 L6004L8 L2004F51 L2004F52 L4004F51 L4004F52 L6004F51 L6004F52 L2004F61 L2004F62 L4004F61 L4004F62 L6004F61 L6004F62 L2004F81 L2004F81 L2004F82 L2004F82 L4004F81 L4004F81 L4004F82 L6004F81 L6004F82
Direct or Suggested Replacement
S D D S S S S S S S S S S S S S S D D D S S D D D S S D D D D D S S S S S S S S S S D D D D D D D D D D D D D D D D D D D D D
Teccor Package
TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) SOT223/COMPAK SOT223/COMPAK TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) SOT223/COMPAK SOT223/COMPAK TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-92 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-220 (ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL) TO-202 (N.ISOL)
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Notes
Part Number Index
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Part Number Index
TECCOR PART NO. 2N5064 2N6565 D2015L D2020L D2025L D4015L D4020L D4025L D6015L D6020L D6025L D8015L D8020L D8025L DK015L DK020L DK025L EC103B EC103B1 EC103B2 EC103B3 EC103D EC103D1 EC103D2 EC103D3 EC103M EC103M1 EC103M2 EC103M3 HT-32 HT-32A HT-32B HT-34B HT-35 HT-36A HT-36B HT-40 HT-5761 HT-5761A HT-5762 K0900E70 K0900G K0900S K1050E70 K1050G K1050S PAGE NO. E5-2 E5-2 E7-2 E7-2 E7-2 E7-2 E7-2 E7-2 E7-2 E7-2 E7-2 E7-2 E7-2 E7-2 E7-2 E7-2 E7-2 E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 E8-2 E8-2 E8-2 E8-2 E8-2 E8-2 E8-2 E8-2 E8-2 E8-2 E8-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 TECCOR PART NO. K1100E70 K1100G K1100S K1200E70 K1200G K1200S K1300E70 K1300G K1300S K1400E70 K1400G K1400S K1500E70 K1500G K1500S K2000E70 K2000F1 K2000G K2000S K2200E70 K2200F1 K2200G K2200S K2400E70 K2400F1 K2400G K2400S K2500E70 K2500F1 K2500G K2500S K3000F1 L2004D3 L2004D5 L2004D6 L2004D8 L2004F31 L2004F51 L2004F61 L2004F81 L2004L3 L2004L5 L2004L6 L2004L8 L2004V3 L2004V5 PAGE NO. E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E9-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 TECCOR PART NO. L2004V6 L2004V8 L2006D5 L2006D6 L2006D8 L2006L5 L2006L6 L2006L8 L2006V5 L2006V6 L2006V8 L2008D6 L2008D8 L2008L6 L2008L8 L2008V6 L2008V8 L201E3 L201E5 L201E6 L201E8 L2N3 L2N5 L2X3 L2X5 L2X8E3 L2X8E5 L2X8E6 L2X8E8 L4004D3 L4004D5 L4004D6 L4004D8 L4004F31 L4004F51 L4004F61 L4004F81 L4004L3 L4004L5 L4004L6 L4004L8 L4004V3 L4004V5 L4004V6 L4004V8 L4006D5 PAGE NO. E1-2 E1-2 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-4 TECCOR PART NO. L4006D6 L4006D8 L4006L5 L4006L6 L4006L8 L4006V5 L4006V6 L4006V8 L4008D6 L4008D8 L4008L6 L4008L8 L4008V6 L4008V8 L401E3 L401E5 L401E6 L401E8 L4N3 L4N5 L4X3 L4X5 L4X8E3 L4X8E5 L4X8E6 L4X8E8 L6004D3 L6004D5 L6004D6 L6004D8 L6004F31 L6004F51 L6004F61 L6004F81 L6004L3 L6004L5 L6004L6 L6004L8 L6004V3 L6004V5 L6004V6 L6004V8 L6006D5 L6006D6 L6006D8 L6006L5 PAGE NO. E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-4 E1-4 E1-4 E1-4 TECCOR PART NO. L6006L6 L6006L8 L6006V5 L6006V6 L6006V8 L6008D6 L6008D8 L6008L6 L6008L8 L6008V6 L6008V8 L601E3 L601E5 L601E6 L601E8 L6N3 L6N5 L6X3 L6X5 L6X8E3 L6X8E5 L6X8E6 L6X8E8 Q2004D3 Q2004D4 Q2004F31 Q2004F41 Q2004L3 Q2004L4 Q2004LT Q2004V3 Q2004V4 Q2006DH3 Q2006DH4 Q2006F41 Q2006L4 Q2006LH4 Q2006LT Q2006N4 Q2006NH4 Q2006R4 Q2006RH4 Q2006VH3 Q2006VH4 Q2008DH3 Q2008DH4 PAGE NO. E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-4 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E1-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E3-2 E2-2 E2-2 E4-2 E4-2 E2-2 E2-2 E4-2 E3-2 E2-2 E4-2 E2-2 E4-2 E4-2 E4-2 E4-2 E4-2
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Part Number Index
TECCOR PART NO. Q2008F41 Q2008L4 Q2008LH4 Q2008LT Q2008N4 Q2008NH4 Q2008R4 Q2008RH4 Q2008VH3 Q2008VH4 Q2010F51 Q2010L4 Q2010L5 Q2010LH5 Q2010LT Q2010N4 Q2010N5 Q2010NH5 Q2010R4 Q2010R5 Q2010RH5 Q2012LH5 Q2012NH5 Q2012RH5 Q2015L5 Q2015LT Q2015N5 Q2015R5 Q2016LH3 Q2016LH4 Q2016LH6 Q2016RH3 Q2016RH4 Q2016RH6 Q201E3 Q201E4 Q2025J6 Q2025K6 Q2025L6 Q2025N5 Q2025R5 Q2025R6 Q2030LH5 Q2035NH5 Q2035RH5 Q2040J7 PAGE NO. E2-2 E2-2 E4-2 E3-2 E2-2 E4-2 E2-2 E4-2 E4-2 E4-2 E2-4 E2-4 E2-4 E4-2 E3-2 E2-4 E2-4 E4-2 E2-4 E2-4 E4-2 E4-2 E4-2 E4-2 E2-4 E3-2 E2-4 E2-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E2-2 E2-2 E4-4 E4-4 E4-4 E2-4 E2-4 E4-4 E4-4 E4-4 E4-4 E4-4 TECCOR PART NO. Q2040K7 Q2N3 Q2N4 Q2X3 Q2X4 Q2X8E3 Q2X8E4 Q4004D3 Q4004D4 Q4004F31 Q4004F41 Q4004L3 Q4004L4 Q4004LT Q4004V3 Q4004V4 Q4006DH3 Q4006DH4 Q4006F41 Q4006L4 Q4006LH4 Q4006LT Q4006LTH Q4006N4 Q4006NH4 Q4006R4 Q4006RH4 Q4006VH3 Q4006VH4 Q4008DH3 Q4008DH4 Q4008F41 Q4008L4 Q4008LH4 Q4008LT Q4008LTH Q4008N4 Q4008NH4 Q4008R4 Q4008RH4 Q4008VH3 Q4008VH4 Q4010F51 Q4010L4 Q4010L5 Q4010LH5 PAGE NO. E4-4 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E3-2 E2-2 E2-2 E4-2 E4-2 E2-2 E2-2 E4-2 E3-2 E3-2 E2-2 E4-2 E2-2 E4-2 E4-2 E4-2 E4-2 E4-2 E2-2 E2-2 E4-2 E3-2 E3-2 E2-2 E4-2 E2-2 E4-2 E4-2 E4-2 E2-4 E2-4 E2-4 E4-2 TECCOR PART NO. Q4010LT Q4010LTH Q4010N4 Q4010N5 Q4010NH5 Q4010R4 Q4010R5 Q4010RH5 Q4012LH5 Q4012NH5 Q4012RH5 Q4015L5 Q4015LT Q4015LTH Q4015N5 Q4015R5 Q4016LH3 Q4016LH4 Q4016LH6 Q4016RH3 Q4016RH4 Q4016RH6 Q401E3 Q401E4 Q4025J6 Q4025K6 Q4025L6 Q4025N5 Q4025R5 Q4025R6 Q4030LH5 Q4035NH5 Q4035RH5 Q4040J7 Q4040K7 Q4N3 Q4N4 Q4X3 Q4X4 Q4X8E3 Q4X8E4 Q6004D3 Q6004D4 Q6004F31 Q6004F41 Q6004L3 PAGE NO. E3-2 E3-2 E2-4 E2-4 E4-2 E2-4 E2-4 E4-2 E4-2 E4-2 E4-2 E2-4 E3-2 E3-2 E2-4 E2-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E2-2 E2-2 E4-4 E4-4 E4-4 E2-4 E2-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 TECCOR PART NO. Q6004L4 Q6004LT Q6004V3 Q6004V4 Q6006DH3 Q6006DH4 Q6006F51 Q6006L5 Q6006LH4 Q6006LT Q6006LTH Q6006N5 Q6006NH4 Q6006R5 Q6006RH4 Q6006VH3 Q6006VH4 Q6008DH3 Q6008DH4 Q6008F51 Q6008L5 Q6008LH4 Q6008LT Q6008LTH Q6008N5 Q6008NH4 Q6008R5 Q6008RH4 Q6008VH3 Q6008VH4 Q6010F51 Q6010L4 Q6010L5 Q6010LH5 Q6010LT Q6010LTH Q6010N4 Q6010N5 Q6010NH5 Q6010R4 Q6010R5 Q6010RH5 Q6012LH5 Q6012NH5 Q6012RH5 Q6015L5 PAGE NO. E2-2 E3-2 E2-2 E2-2 E4-2 E4-2 E2-2 E2-2 E4-2 E3-2 E3-2 E2-2 E4-2 E2-2 E4-2 E4-2 E4-2 E4-2 E4-2 E2-2 E2-2 E4-2 E3-2 E3-2 E2-2 E4-2 E2-2 E4-2 E4-2 E4-2 E2-4 E2-4 E2-4 E4-2 E3-2 E3-2 E2-4 E2-4 E4-2 E2-4 E2-4 E4-2 E4-2 E4-2 E4-2 E2-4 TECCOR PART NO. Q6015LT Q6015LTH Q6015N5 Q6015R5 Q6016LH3 Q6016LH4 Q6016LH6 Q6016RH3 Q6016RH4 Q6016RH6 Q601E3 Q601E4 Q6025J6 Q6025K6 Q6025L6 Q6025N5 Q6025P5 Q6025R5 Q6025R6 Q6030LH5 Q6035NH5 Q6035P5 Q6035RH5 Q6040J7 Q6040K7 Q6N3 Q6N4 Q6X3 Q6X4 Q6X8E3 Q6X8E4 Q8004D4 Q8004L4 Q8004V4 Q8006DH3 Q8006DH4 Q8006L5 Q8006LH4 Q8006N5 Q8006NH4 Q8006R5 Q8006RH4 Q8006VH3 Q8006VH4 Q8008DH3 Q8008DH4 PAGE NO. E3-2 E3-2 E2-4 E2-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E2-2 E2-2 E4-4 E4-4 E4-4 E2-4 E2-4 E2-4 E4-4 E4-4 E4-4 E2-4 E4-4 E4-4 E4-4 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E2-2 E4-2 E4-2 E2-2 E4-2 E2-2 E4-2 E2-2 E4-2 E4-2 E4-2 E4-2 E4-2
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Part Number Index
TECCOR PART NO. Q8008L5 Q8008LH4 Q8008N5 Q8008NH4 Q8008R5 Q8008RH4 Q8008VH3 Q8008VH4 Q8010L4 Q8010L5 Q8010LH5 Q8010N4 Q8010N5 Q8010NH5 Q8010R4 Q8010R5 Q8010RH5 Q8012LH5 Q8012NH5 Q8012RH5 Q8015L5 Q8015N5 Q8015R5 Q8016LH3 Q8016LH4 Q8016LH6 Q8016RH3 Q8016RH4 Q8016RH6 Q8025J6 Q8025K6 Q8025L6 Q8025N5 Q8025P5 Q8025R5 Q8025R6 Q8035P5 Q8040J7 Q8040K7 QK004D4 QK004L4 QK004V4 QK006DH3 QK006DH4 QK006L5 QK006LH4 PAGE NO. E2-2 E4-2 E2-2 E4-2 E2-2 E4-2 E4-2 E4-2 E2-4 E2-4 E4-2 E2-4 E2-4 E4-2 E2-4 E2-4 E4-2 E4-2 E4-2 E4-2 E2-4 E2-4 E2-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E2-4 E2-4 E2-4 E4-4 E2-4 E4-4 E4-4 E2-2 E2-2 E2-2 E4-2 E4-2 E2-2 E4-2 TECCOR PART NO. QK006N5 QK006NH4 QK006R5 QK006RH4 QK006VH3 QK006VH4 QK008DH3 QK008DH4 QK008L5 QK008LH4 QK008N5 QK008NH4 QK008R5 QK008RH4 QK008VH3 QK008VH4 QK010L4 QK010L5 QK010LH5 QK010N4 QK010N5 QK010NH5 QK010R4 QK010R5 QK010RH5 QK012LH5 QK012NH5 QK012RH5 QK015L5 QK015N5 QK015R5 QK016LH3 QK016LH4 QK016LH6 QK016NH3 QK016NH4 QK016NH6 QK016RH3 QK016RH4 QK016RH6 QK025K6 QK025L6 QK025N5 QK025N6 QK025R5 QK025R6 PAGE NO. E2-2 E4-2 E2-2 E4-2 E4-2 E4-2 E4-2 E4-2 E2-2 E4-2 E2-2 E4-2 E2-2 E4-2 E4-2 E4-2 E2-4 E2-4 E4-2 E2-4 E2-4 E4-2 E2-4 E2-4 E4-2 E4-2 E4-2 E4-2 E2-4 E2-4 E2-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E4-4 E2-4 E4-4 E2-4 E4-4 TECCOR PART NO. QK040K7 S2004DS1 S2004DS2 S2004VS1 S2004VS2 S2006D S2006DS2 S2006DS3 S2006F1 S2006FS21 S2006FS31 S2006L S2006LS2 S2006LS3 S2006V S2006VS2 S2006VS3 S2008D S2008DS2 S2008DS3 S2008F1 S2008FS21 S2008FS31 S2008L S2008LS2 S2008LS3 S2008R S2008V S2008VS2 S2008VS3 S2010D S2010DS2 S2010DS3 S2010F1 S2010FS21 S2010FS31 S2010L S2010LS2 S2010LS3 S2010R S2010V S2010VS2 S2010VS3 S2012D S2012R S2012V PAGE NO. E4-4 E5-2 E5-2 E5-2 E5-2 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E6-2 E5-4 E5-4 E6-2 E6-2 E6-2 TECCOR PART NO. S2015L S2016N S2016R S201E S2020L S2025L S2025N S2025R S2035J S2035K S2040N S2040R S2055M S2055N S2055R S2055W S2065J S2065K S2070W S2N1 S2S S2S1 S2S2 S2S3 S4004DS1 S4004DS2 S4004VS1 S4004VS2 S4006D S4006DS2 S4006DS3 S4006F1 S4006FS21 S4006FS31 S4006L S4006LS2 S4006LS3 S4006V S4006VS2 S4006VS3 S4008D S4008DS2 S4008DS3 S4008F1 S4008FS21 S4008FS31 PAGE NO. E6-4 E6-4 E6-4 E6-2 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-2 E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 TECCOR PART NO. S4008L S4008LS2 S4008LS3 S4008R S4008V S4008VS2 S4008VS3 S4010D S4010DS2 S4010DS3 S4010F1 S4010FS21 S4010FS31 S4010L S4010LS2 S4010LS3 S4010R S4010V S4010VS2 S4010VS3 S4012D S4012R S4012V S4015L S4016N S4016R S401E S4020L S4025L S4025N S4025R S4035J S4035K S4040N S4040R S4055M S4055N S4055R S4055W S4065J S4065K S4070W S4N1 S4S S4S1 S4S2 PAGE NO. E6-2 E5-4 E5-4 E6-2 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E6-2 E5-4 E5-4 E6-2 E6-2 E6-2 E6-4 E6-4 E6-4 E6-2 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-2 E5-2 E5-2 E5-2
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Part Number Index
TECCOR PART NO. S4S3 S6004DS1 S6004DS2 S6004VS1 S6004VS2 S6006D S6006DS2 S6006DS3 S6006F1 S6006FS21 S6006FS31 S6006L S6006LS2 S6006LS3 S6006V S6006VS2 S6006VS3 S6008D S6008DS2 S6008DS3 S6008F1 S6008FS21 S6008FS31 S6008L S6008LS2 S6008LS3 S6008R S6008V S6008VS2 S6008VS3 S6010D S6010DS2 S6010DS3 S6010F1 S6010FS21 S6010FS31 S6010L S6010LS2 S6010LS3 S6010R S6010V S6010VS2 S6010VS3 S6012D S6012R S6012V PAGE NO. E5-2 E5-2 E5-2 E5-2 E5-2 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E5-4 E5-4 E6-2 E6-2 E5-4 E5-4 E6-2 E6-2 E6-2 TECCOR PART NO. S6015L S6016N S6016R S601E S6020L S6025L S6025N S6025R S6035J S6035K S6040N S6040R S6055M S6055N S6055R S6055W S6065J S6065K S6070W S6N1 S6S S6S1 S6S2 S6S3 S8006D S8006L S8006V S8008D S8008L S8008R S8008V S8010D S8010L S8010R S8010V S8012D S8012R S8012V S8015L S8016N S8016R S8020L S8025L S8025N S8025R S8035J PAGE NO. E6-4 E6-4 E6-4 E6-2 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-2 E5-2 E5-2 E5-2 E5-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 TECCOR PART NO. S8035K S8040N S8040R S8055M S8055N S8055R S8055W S8065J S8065K S8070W SK006D SK006L SK006V SK008D SK008L SK008R SK008V SK010D SK010L SK010R SK010V SK012D SK012R SK012V SK015L SK016N SK016R SK020L SK025L SK025N SK025R SK035K SK040N SK040R SK055M SK055N SK055R SK065K ST-32 ST-32B ST-34B ST-35 ST-36A ST-36B ST-40 T106B1 PAGE NO. E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-2 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E6-4 E8-2 E8-2 E8-2 E8-2 E8-2 E8-2 E8-2 E5-2 TECCOR PART NO. T106D1 T106M1 T107B1 T107D1 T107M1 TCR22-4 TCR22-6 TCR22-8 PAGE NO. E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 E5-2 TECCOR PART NO. PAGE NO.
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