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TCA 785
Phase Control IC
TCA 785
Bipolar IC
Features
q q q q q q q q
Reliable recognition of zero passage Large application scope May be used as zero point switch LSL compatible Three-phase operation possible (3 ICs) Output current 250 mA Large ramp current range Wide temperature range
P-DIP-16-1
Type TCA 785
Ordering Code Q67000-A2321
Package P-DIP-16-1
This phase control IC is intended to control thyristors, triacs, and transistors. The trigger pulses can be shifted within a phase angle between 0 and 180 . Typical applications include converter circuits, AC controllers and three-phase current controllers. This IC replaces the previous types TCA 780 and TCA 780 D. Pin Definitions and Functions Pin 1 2 3 4 5 6 7 8 9 10 11 12 13 Pin Configuration (top view) Semiconductor Group 14 15 16 1 Symbol GND Q2 QU Q2 VSYNC I QZ V REF R9 C10 V11 C12 L Q1 Q2 VS Function Ground Output 2 inverted Output U Output 1 inverted Synchronous voltage Inhibit Output Z Stabilized voltage Ramp resistance Ramp capacitance Control voltage Pulse extension Long pulse Output 1 Output 2 Supply voltage 09.94
TCA 785
Functional Description The synchronization signal is obtained via a high-ohmic resistance from the line voltage (voltage V5). A zero voltage detector evaluates the zero passages and transfers them to the synchronization register. This synchronization register controls a ramp generator, the capacitor C10 of which is charged by a constant current (determined by R9). If the ramp voltage V10 exceeds the control voltage V11 (triggering angle ), a signal is processed to the logic. Dependent on the magnitude of the control voltage V11, the triggering angle can be shifted within a phase angle of 0 to 180. For every half wave, a positive pulse of approx. 30 s duration appears at the outputs Q 1 and Q 2. The pulse duration can be prolonged up to 180 via a capacitor C12. If pin 12 is connected to ground, pulses with a duration between and 180 will result. Outputs Q 1 and Q 2 supply the inverse signals of Q 1 and Q 2. A signal of +180 which can be used for controlling an external logic,is available at pin 3. A signal which corresponds to the NOR link of Q 1 and Q 2 is available at output Q Z (pin 7). The inhibit input can be used to disable outputs Q1, Q2 and Q 1 , Q 2 . Pin 13 can be used to extend the outputs Q 1 and Q 2 to full pulse length (180 - ).
Block Diagram Semiconductor Group 2
TCA 785
Pulse Diagram
Semiconductor Group
3
TCA 785
Absolute Maximum Ratings Parameter Supply voltage Output current at pin 14, 15 Inhibit voltage Control voltage Voltage short-pulse circuit Synchronization input current Output voltage at pin 14, 15 Output current at pin 2, 3, 4, 7 Output voltage at pin 2, 3, 4, 7 Junction temperature Storage temperature Thermal resistance system - air Operating Range Supply voltage Operating frequency Ambient temperature VS f TA 8 10 - 25 18 500 85 V Hz C Symbol min. VS IQ V6 V11 V13 V5 VQ IQ VQ Tj Tstg Rth SA - 55 - 0.5 - 10 - 0.5 - 0.5 - 0.5 - 200 Limit Values max. 18 400 VS VS VS
Unit V mA V V V
A
200
VS 10 VS 150 125 80
V mA V C C K/W
Characteristics 8 VS 18 V; - 25 C TA 85 C; f = 50 Hz Parameter Supply current consumption S1 ... S6 open V11 = 0 V C 10 = 47 nF; R 9 = 100 k Synchronization pin 5 Input current R 2 varied Offset voltage Control input pin 11 Control voltage range Input resistance Semiconductor Group Symbol min. IS 4.5 Limit Values typ. 6.5 max. 10 Unit Test Circuit mA 1
I5 rms
V5
30 30 0.2 15 4
200 75 V10 peak
A
1
mV 4 V k 1 5
V11 R11
TCA 785
Characteristics (cont'd) 8 VS 18 V; - 25 C TA 85 C; f = 50 Hz Parameter Ramp generator Charge current Max. ramp voltage Saturation voltage at capacitor Ramp resistance Sawtooth return time Inhibit pin 6 switch-over of pin 7 Outputs disabled Outputs enabled Signal transition time Input current V6 = 8 V Input current V6 = 1.7 V Deviation of I10 R 9 = const. VS = 12 V; C10 = 47 nF Deviation of I10 R 9 = const. VS = 8 V to 18 V Deviation of the ramp voltage between 2 following half-waves, VS = const. Long pulse switch-over pin 13 switch-over of S8 Short pulse at output Long pulse at output Input current V13 = 8 V Input current V13 = 1.7 V Outputs pin 2, 3, 4, 7 Reverse current VQ = VS Saturation voltage IQ = 2 mA Symbol min. I10 V10 V10 R9 tf 10 100 3 225 80 Limit Values typ. max. 1000 V2 - 2 350 300 Unit Test Circuit
A
V 1 mV 1.6 k 1 s 1
V6 L V6 H tr I6 H - I6 L I10
4 1
3.3 3.3 500
2.5 5 800 200 5
V V
s A A
1 1 1 1 1 1
80 -5
150
% %
I10
- 20
20
1
V10 max
1
%
V13 H V13 L I13 H - I13 L
3.5
2.5 2.5
2 10 100
V V
A A
1 1 1 1
45
65
ICEO Vsat 0.1 0.4
10 2
A
2.6 2.6
V
Semiconductor Group
5
TCA 785
Characteristics (cont'd) 8 VS 18 V; - 25 C TA 85 C; f = 50 Hz Parameter Outputs pin 14, 15 H-output voltage - I Q = 250 mA L-output voltage IQ = 2 mA Pulse width (short pulse) S9 open Pulse width (short pulse) with C12 Internal voltage control Reference voltage Parallel connection of 10 ICs possible TC of reference voltage Symbol min. V14/15 H V14/15 L tp tp VS - 3 0.3 20 530 Limit Values typ. VS - 2.5 0.8 30 620 max. VS - 1.0 2 40 760 Unit Test Circuit V V
s s/
3.6 2.6 1 1
nF VREF
REF
2.8
3.1 2 x 10 - 4
3.4 5 x 10 - 4
V
1
1/K 1
Semiconductor Group
6
TCA 785
Application Hints for External Components min Ramp capacitance C10 500 pF V11 x R9 x C10 VREF x K VREF x K R9
2)
max 1 F1)
2)
The minimum and maximum values of I10 are to be observed
Triggering point
tTr =
Charge current
I10 =
Ramp voltage V10 max = VS - 2 V V10 =
VREF x K x t R9 x C10
2)
Pulse Extension versus Temperature
1) 2)
Attention to flyback times K = 1.10 20 %
Semiconductor Group
7
TCA 785
Output Voltage measured to + VS
Supply Current versus Supply Voltage
Semiconductor Group
8
TCA 785
It is necessary for all measurements to adjust the ramp with the aid of C10 and R 9 in the way that 3 V Vramp max V S - 2 V e.g. C10 = 47 nF; 18 V: R 9 = 47 k; 8 V: R 9 = 120 k
Test Circuit 1 Semiconductor Group 9
TCA 785
The remaining pins are connected as in test circuit 1
Test Circuit 2
The remaining pins are connected as in test circuit 1 Test Circuit 3
Semiconductor Group
10
TCA 785
Remaining pins are connected as in test circuit 1 The 10 F capacitor at pin 5 serves only for test purposes Test Circuit 4
Test Circuit 5 Semiconductor Group 11
Test Circuit 6
TCA 785
Inhibit 6
Long Pulse 13
Pulse Extension 12
Reference Voltage 8
Semiconductor Group
12
TCA 785
Application Examples Triac Control for up to 50 mA Gate Trigger Current
A phase control with a directly controlled triac is shown in the figure. The triggering angle of the triac can be adjusted continuously between 0 and 180 with the aid of an external potentiometer. During the positive half-wave of the line voltage, the triac receives a positive gate pulse from the IC output pin 15. During the negative half-wave, it also receives a positive trigger pulse from pin 14. The trigger pulse width is approx. 100 s. Semiconductor Group 13
TCA 785
Fully Controlled AC Power Controller Circuit for Two High-Power Thyristors Shown is the possibility to trigger two antiparalleled thyristors with one IC TCA 785. The trigger pulse can be shifted continuously within a phase angle between 0 and 180 by means of a potentiometer. During the negative line half-wave the trigger pulse of pin 14 is fed to the relevant thyristor via a trigger pulse transformer. During the positive line half-wave, the gate of the second thyristor is triggered by a trigger pulse transformer at pin 15. Semiconductor Group 14
TCA 785
Half-Controlled Single-Phase Bridge Circuit with Trigger Pulse Transformer and Direct Control for Low-Power Thyristors Semiconductor Group 15
TCA 785
Half-Controlled Single-Phase Bridge Circuit with Two Trigger Pulse Transformers for Low-Power Thyristors Semiconductor Group 16

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