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| Title Engineering Prototype Report 70 W (19 V 3.66A) Universal Input Adapter (EP11) Laptop Adapters, LCD Monitors, Audio, High Power Adapters Power Integrations Applications Dept. EPR-00011 22-January-2001 1.4 Target Applications Author Doc Num Date Revision Features * * * * * * * * * * * * * * * Very compact design: (4.1" x 2.25" x 1.06") High power density - 7 W / inch Full output power (70 W) in sealed enclosure at 40C ambient High efficiency: 84% (85 VAC), 89% (230 VAC) Low no-load consumption: 350 mW (115 VAC), 500 mW (230 VAC) Low value input capacitor: 74% DCMAX and line feed forward allows 2 F/W Power limited during overload: overload output current less than 5 A at 19 V Primary side soft-start: minimizes component stresses during start-up Low EMI due to frequency jittering: meets CISPR22B with output cap. earthed Line under voltage sense: no output glitches on power up or power down Line over voltage shutdown: extended line surge protection Hysteretic thermal shutdown: supply automatically recovers when fault is removed Low component count: simple circuit and design Single sided PC board: no plated through holes No surface mount components required Power Integrations Inc 5245 Hellyer Avenue, San Jose, CA 95138 USA. Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com EPR-00011 - 70 W Adapter 22-Jan-01 Table of Contents Introduction..................................................................................................................4 Power Supply Specification .........................................................................................6 Schematic ....................................................................................................................7 3.1 Description ...............................................................................................................7 4 PCB Layout................................................................................................................10 5 Bill of Materials ..........................................................................................................11 6 Transformer Documentation ......................................................................................12 6.1 Transformer Sources .............................................................................................14 7 Transformer Spreadsheet..........................................................................................15 8 Performance Data......................................................................................................17 8.1 Efficiency................................................................................................................17 8.2 No-load input power...............................................................................................18 8.3 Regulation / Power Limiting ...................................................................................18 9 Thermal Performance ................................................................................................20 10 Waveform Scope Plots ..............................................................................................24 10.1 Drain Voltage and Current During Normal Operation.........................................24 10.2 Output Voltage During Power-up........................................................................25 10.3 Output Voltage During Power-down ...................................................................26 10.4 Drain Voltage and Current during Power-Up (265 VAC)......................................26 10.5 DRAIN Current During Power-Up and Power-Down...........................................27 10.6 Load Transient response (15 to 100% load change) .........................................28 10.6.1 15 to 100% load change, 85 VAC .....................................................................28 10.7 Load Transient response (0 to 50% load change) .............................................29 10.7.1 0 to 50% load change, 85 VAC .........................................................................29 10.7.2 0 to 50% load change, 130 VAC .......................................................................29 10.7.3 0 to 50% load change, 130 VAC .......................................................................30 10.8 Ripple Measurements.........................................................................................30 10.8.1 DC Ripple Measurement Technique...............................................................30 10.8.2 Ripple Measurement Results..........................................................................31 11 Control Loop Characteristics .....................................................................................32 11.1 Gain Phase Results............................................................................................33 12 Conducted EMI Scans ...............................................................................................36 1 2 3 Important Note: Although the EP11 is designed to satisfy safety isolation requirements, the engineering prototype has not been agency approved. Therefore all testing should be performed using an isolation transformer to provide the AC input to the prototype board Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 2 of 46 22-Jan-01 EPR-00011 - 70 W Adapter 13 Appendix A - Thermal considerations: ...................................................................... 37 13.1 Efficiency: .......................................................................................................... 38 13.2 Heat Sinking: ..................................................................................................... 38 13.3 Heat Spreading and Enclosure Surface Temperature: ...................................... 39 13.4 Component Temperature: .................................................................................. 39 13.5 Conclusion: ........................................................................................................ 40 14 Appendix B - Custom Component Documentation:................................................... 41 14.1 Toroid Filter Inductor (L2): ................................................................................. 41 14.2 Output Inductor (L1)........................................................................................... 42 14.3 Heat sink #1 (TOPSwitch-GX and Input Bridge)................................................ 43 14.4 Heat sink #2 (Output Diodes) ............................................................................ 43 15 Revision History ........................................................................................................ 44 Page 3 of 46 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com EPR-00011 - 70 W Adapter 22-Jan-01 1 Introduction This document is an engineering report that describes a universal input power supply that utilises a TOP249Y. This supply is an off-line flyback converter that operates in continuous mode. Below is a list of notable features: * * * * * * * * * * * * * * * Very compact design: (4.1"x2.25"x1.06" internal box dimensions) High power density - 7 W / inch Full output power in sealed enclosure at 40C ambient High efficiency: 84% (85 VAC), 89% (230 VAC) Low no-load consumption: 350mW (115 VAC), 500 mW (230 VAC) Low value input capacitor: extended maximum duty cycle allows 2F/W Power limited during overload: overload output current < 5 A at 19 V Primary side soft-start: minimizes component stresses during start-up Low EMI due to frequency jittering: meets CISPR22 B / EN55022 B with output earthed Line under voltage sense: no output glitches on power up or power down Line over voltage shutdown: extended line surge protection Hysteretic thermal shutdown: supply automatically recovers when fault is removed Low component count: simple circuit and design Single sided PC board: no plated through holes No surface mount components required This board demonstrates the basic performance features and the increased power capability of the new family. It was designed to allow testing within the enclosure of a commercial laptop power adapter. This enclosure was used for the thermal testing in section 9. This document contains the power supply specification, schematic, bill of materials and transformer documentation. Typical operating characteristics are presented at the rear of the report and consist of performance curves and scope waveforms Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com XG-hctiwSPOT Page 4 of 46 22-Jan-01 EPR-00011 - 70 W Adapter Figure 1 - EP11 Inside Commercial Laptop Enclosure (4.25 x 2.5 x 1.2" / 108 x 64 x 30mm - external diemonsions) Height=1.06" / 26.9 mm 2.25" / 57mm 4.1" / 104.1mm Figure 2 - EP11 Populated Circuit Board (dimensions include heat spreader not shown) Page 5 of 46 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com EPR-00011 - 70 W Adapter 22-Jan-01 2 Power Supply Specification Description Symbol Input Input Voltage VIN Input Frequency f No-load Input Power (115 VAC) No-load Input Power (230 VAC) Output Output Voltage VOUT Output Ripple Voltage VRIPPLE Output Current IOUT Continuous Output Power POUT Total Regulation Efficiency (85 VAC) Efficiency (230 VAC) Environmental Conducted EMI Safety External Ambient Temperature Min 85 47 Typ 115/230 50/60 370 520 19.2 Max 265 64 Units VAC Hz mW mW VDC mVp-p ADC W % % Comment See fig 7 See fig 7 At output terminals 20 MHz BW 18.7 0 0 -2 84 89 19.7 120 3.66 70 +2 0 - 100% load, 85 - 265 VAC At full load T AMB 0 25 40 o C Meets CISPR22 B Designed to meet IEC950 In enclosure with natural convection (see section 9) Output voltage tolerance may be improved through choice of feedback components. Nominal output voltage for purposes of determining regulation limits is measured at 115 VAC input and 3.66 A output current. Table 1 - Power supply specification Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 6 of 46 EPR-00011 - 70 W Adapter 22-Jan-01 3 Schematic Figure 3 - 70W TOP249Y Power Supply Schematic 3.1 Description The EP11 is a low-cost flyback switching power supply using the TOP249Y integrated circuit from the TOPSwitch-GX family. The circuit shown in Figure 3 details a 19 V, 70 W supply that operates from an input range of 85 to 265 VAC, suitable for applications requiring either an open frame supply or an enclosed adapter. AC power is rectified and filtered by BR1 and C7 to create the high voltage DC bus applied to the primary winding of transformer (T1). Only a 150F capacitor is required (2.1 F/W) due to the wider DCMAX of TOPSwitch-GX and the line feed forward function provided by the LINE SENSE Pin. The other side of the primary is driven by the integrated high-voltage MOSFET within the TOP249Y. Diodes, D4 and D2 clamp the DRAIN voltage spike caused by transformer leakage inductance to a safe value below the 700 V maximum. Capacitor C6 is added in parallel with D2 to reduce zener clamp dissipation. The TOPSwitch-GX family provides new operating features and extended specifications. The EP11 power supply is designed using several of these features. Resistors R14 and R15 connected to the LINE SENSE pin (L) of TOPSwitch-GX (U1) are used to implement Power Integrations Inc Tel: +1 408 523 9200 Fax: +1 408 523 9300 www: http://www.powerint.com Page 7 of 46 EPR-00011 - 70 W Adapter 22-Jan-01 an under-voltage detect (100V), over-voltage shutdown (450V) and line feed forward with DCMAX reduction features. Two resistors are used in series to allow low cost 1/4 W resistors which have a lower voltage rating. The under-voltage detect ensures that the output is glitch free at start-up and shutdown. With the combined value of R14 and R15 as shown, the power supply does not start operating until the DC rail voltage reaches 100 VDC. On removal of the AC input the UV sense prevents the output glitching as C7 discharges turning off the TOPSwitch-GX when output regulation is lost or when the input voltage falls to 40 V, whichever occurs first. The over-voltage feature shuts down the supply if the rectified input voltage exceeds approximately 450V. If exceeded this protects the TOPSwitch-GX from excessive drain voltages providing an extended AC surge withstand to 700 VDC (BVDSS rating), ideal for countries with poor power quality. Finally the line feed forward feature reduces output line frequency ripple by modulating the control loop with the line frequency ripple on the DC rail, ideal when using a relatively small input capacitor. Resistors R5, R6, and R12 connect to the EXTERNAL CURRENT LIMIT pin (X) and are used to externally program the current limit level of the device to just above the operating peak current at full load and low line. This allows use of a smaller transformer core and / or higher transformer primary inductance for a given output power. Reducing transformer size and TOPSwitch-GX power dissipation, while at the same time avoiding transformer core saturation during start-up or output load transient. This resistor network also reduces the current limit with increasing line voltage. This limits the maximum available power during overload conditions at high line (see Figure 10) removing the need for any protection circuitry on the secondary. The secondary windings are rectified and filtered by D1, D5, C1, and create the 19 V output voltage. Two windings are used, with separate dual rectifiers (for equal current sharing), to lower winding losses and maximise efficiency. Inductor L1 provided additional filtering in conjunction with C4 and C14. The 19 V output is directly sensed by the series combination of R4 and R13 that form a divider with R10. These resistors together with the reference node voltage of U3 set the output voltage. Other output voltages are also possible by adjusting the transformer turns ratios and value of R4 and R13. Resistor R2 sets the overall DC gain of the control loop and R7 provides bias for voltage reference U3. Capacitor C11 is the main compensation capacitor and together with R11, C9, R8 and C10 ensure stability of the control loop. The TOPSwitch-GX control circuit allows the switching frequency to reduce at light or zero load conditions, eliminating the need for a pre-load resistor to control the output Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 8 of 46 EPR-00011 - 70 W adapter 22-Jan-01 voltage at zero load. By lowering the switching frequency, no-load power consumption is also greatly reduced. The bias winding is rectified and filtered by D3, R3 and C8 to create a bias voltage to power the TOP249Y. A 1F capacitor is required for C8 to maintain sufficient voltage during zero to full load transients. Resistor R8 provides leakage inductance filtering to prevent peak charging. A ceramic capacitor is shown for C8 however for lower cost an electrolytic type can be used. Common mode choke L3 and capacitor C12 attenuate common-mode emission currents caused by high-voltage switching waveforms on the drain side of the primary winding and the primary to secondary capacitance. Inductor L2 in conjunction with C5, C15 and C16 attenuate differential-mode emission currents caused by the fundamental and harmonics of the primary current waveform. Capacitor C16 provides a high frequency bypass of C7 which shortens the loop formed by these high frequencies passing through the transformer primary and thus reduces both the differential and common mode conducted noise. Frequency jitter is employed by the TOPSwitch-GX family to reduce the conducted noise as measured for both the CISPR and EN standards (see section 12) Capacitor C17 filters internal MOSFET gate-drive charge current spikes on the CONTROL pin and together with R11 and C11 determines the auto-restart frequency. Power Integrations Inc Tel: +1 408 523 9200 Fax: +1 408 523 9300 www: http://www.powerint.com Page 9 of 46 EPR-00011 - 70 W Adapter 22-Jan-01 4 PCB Layout Figure 4 - PCB layout (not to scale) Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 10 of 46 EPR-00011 - 70 W adapter 22-Jan-01 5 Bill of Materials EP11 - 19.2V, 3.66A Universal Input Flyback Item 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 Qty. 1 3 1 1 1 1 1 3 1 1 1 1 2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 2 1 1 1 1 1 1 Reference BR1 C1, C2, C4 C5 C6 C7 C8 C9 C10, C14, C17 C11 C12 C15 C16 D5, D1 D2 D3 D4 F1 J1 J2 L1 L2 L3 RT1 R2 R3 R4 R5 R6 R7 R8 R10 R11 R12 R13 R14, R15 T1 U1 U2 U3 HS1 HS2 Part Comment RS805 820uF 25V 0.1uF X2 Safety 250VAC 0.01uF 400V 150uF 400V 1.0uF 50V 0.0047uF 50V 0.1uF 50V 47uF 16V .0022uF Y1 Safety 250VAC 0.33uF 400V 0.02uF 500V MBR20100 P6KE200A 1N4148 UF4006 3.15A, 250V Molex Header Molex Header 200uH (custom -see appendix) 75uH (custom -see appendix) CM Choke 820uH 2.0A 10 Ohm 1.7A In-rush limiter (Keystone CL 120) 270 1/8W 4.7 1/8W 31.6K 1/8W 1% 7.5M 1/4W 5.6M 1/4W 1.0K 1/8W 56K 1/8W 4.75K 1/8W 1% 6.8 1/8W 20.5K 1/8W 562 1/8W 1% 1M 1/4W PQ26/20 Core Transformer - revision F (custom - see appendix) TOP249Y PC817A TL431CLP Copper Heat Sink EP11-HS1D Copper Heat Sink EP11-HS2D Power Integrations Inc Tel: +1 408 523 9200 Fax: +1 408 523 9300 www: http://www.powerint.com Page 11 of 46 EPR-00011 - 70 W Adapter 22-Jan-01 6 Transformer Documentation Transformer, T1 (rev. F) CORE CONTACT SHIELD WDG #2 1 TURN OF FOIL 1 12 3T# 26AWG x 3 T.I. 9 WDG #3 WDG #1 9T # 26AWG x 2 2 11 3T# 26AWG x 3 T.I. 8 WDG #5 9T # 26AWG x 2 3 5 WDG #4 2 TURNS OF FOIL 6 ELECTRICAL SPECIFICATIONS: Electrical strength Primary Inductance Resonant Frequency Primary leakage inductance 60 Hz 1 minute, from Pins 2-6 to Pins 8-12 Pins 1-3; all windings open. Measure at 130kHz Pins 1-3; all windings open. Pins 1-3; Pins 8,9,11, 12 shorted. Measure at 130kHz. 3000 VAC 273H +/-10% 1.3 MHz (Min.) 3H (Max) MATERIALS: Item [1] [2] [3] [4] [5] [6] [7] [8] [9] [10] Description Core: FPQ26/20-A, TDK PC40 (or equivalent); gapped for ALG=843nH/T2 Lower loss ferrite can be substituted to obtain lower core temperatures. Bobbin: TDK BPQ26/20-1112CP (or equivalent) Magnet Wire: # 26 AWG Solderable Double Coated Triple Insulated Wire: # 26AWG Copper foil; 8mm wide Thickness=0.051mm (.002") Copper foil tape; 3M 1181 (or equivalent) 11mm wide Tape: 3M 74 Polyester Film (or equivalent) 12mm wide Tape: 3M 74 Polyester Film (or equivalent) 9.2mm wide Varnish Tape: 3M 1298 Polyester Film (or equivalent) 19.5mm wide Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 12 of 46 EPR-00011 - 70 W adapter TRANSFORMER DIAGRAM: Pin Side 2 3 5 6 8 11 9 12 1 11 22-Jan-01 Tape [6] 1/2 Primary [3] Tape [6] Bias [5] Secondary [4] Tape [3] Shield [5] 1 1/2 Primary [3] 2 SHIELD and BIAS Winding PREPARATION: #26 copper wire (only one required for shield) Copper Foil Tape A 20.0 12.0 B 8.0 4.0 2.0 65 for Shield and 120 for Bias Winding Figure 1-A (Top View before folding tape) Figure 1-B (Top View after folding tape) Copper Tape Figure 1-C (Cross Section) Power Integrations Inc Tel: +1 408 523 9200 Fax: +1 408 523 9300 www: http://www.powerint.com Page 13 of 46 EPR-00011 - 70 W Adapter 22-Jan-01 Due to proximity of secondary components (R4, R13), wrap one layer of tape [10] around core. TRANSFORMER CONSTRUCTION: 1/2 Primary Winding Shield Band (*see diagram) Start at pin 2. Wind 9 turns of 2 parallel strands of item [3] from left to right. Wind a single layer and finish at pin 1. Prepare cuffed foil [5]. Start at unterminated end of foil and wind one (1) complete turn of foil around bobbin. Terminate at pin 1 and cover with tape [8]. Attach Tri-filar item [4] to pin 12. Attach Tri-filar item [4] to pin 11. Interleaving windings, wind across the bobbin. From pin 12, wind 3 turns and finish at pin 9. From pin 11,wind 3 turns and finish at pin 8. Prepare cuffed foil [5]. Start at pin 6 and wind 2 complete turns of foil around bobbin and terminate at pin 5. 1 layer of tape [8] for insulation. Start at pin 3. Wind 9 turns of 2 parallel strands of item [3] from left to right. Wind a single layer and finish at pin 2. 1 layer of tape [8] for insulation. Affix center gapped core to bobbin. Wrap core with copper foil tape [6] Attach wire to pin 1 and to copper tape. Wrap one layer of tape [10] around core. (see figure above) Varnish Impregnate using [9] Secondary Winding Foil Band (*see diagram) Basic Insulation 1/2 Primary Winding Basic Insulation Core Final Assembly and Core Contact Apply Tape to outside of Core Impregnation 6.1 Transformer Sources For information on the vendors used to source the transformer, please visit our website at the address below and select Engineering Prototype Boards http://www.powerint.com/componentsuppliers.htm Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 14 of 46 EPR-00011 - 70 W adapter 22-Jan-01 7 Transformer Spreadsheet ACDC_TOPGX_Rev0.2_090100 Power Integrations Inc. 2000 ENTER APPLICATION VARIABLES VACMIN VACMAX fL VO PO n Z VB tC CIN ENTER TOPSWITCH-FX VARIABLES TOP-FX Chosen Device KI ILIMITMIN ILIMITMAX Frequency - (F)=130kHz, (H)=65kHz fS fSmin fSmax VOR VDS VD VDB KP INPUT INFO OUTPUT UNIT TOP_GX_090100.xls: TOPSwitch-GX Continuous/Discontinuous, Flyback Transformer Design Spreadsheet Customer 85 265 50 19.2 70 0.85 0.5 12 3 150 Volts Volts Hertz Volts Watts Minimum AC Input Voltage Maximum AC Input Voltage AC Mains Frequency Output Voltage Output Power Efficiency Estimate Loss Allocation Factor Bias Voltage Bridge Rectifier Conduction Time Estimate Input Filter Capacitor Volts mSeconds uFarads top249 TOP249 Pout 0.55 Universal 135W 2.67 Amps 3.18 Amps f 132000 132000 Hertz 124000 Hertz 140000 Hertz Volts Volts Volts Volts 115 Doubled/230V 300W External Ilimit reduction factor (KI=1.0 for default ILIMIT, KI <1.0 for lower ILIMIT) Use 1% resistor in setting external ILIMIT Use 1% resistor in setting external ILIMIT Full (F) frequency option - 130kHz TOPSwitch-FX Switching Frequency: Choose between 132 kHz and 66 kHz TOPSwitch-FX Minimum Switching Frequency TOPSwitch-FX Maximum Switching Frequency Reflected Output Voltage TOPSwitch on-state Drain to Source Voltage Output Winding Diode Forward Voltage Drop Bias Winding Diode Forward Voltage Drop Ripple to Peak Current Ratio (0.4 < KRP < 1.0 : 1.0< KDP<6.0) 120 8 0.7 0.7 0.60 ENTER TRANSFORMER CORE/CONSTRUCTION VARIABLES PQ26/2 Core Type 0 Core Bobbin AE LE AL BW M L NS 0 1.4 3 #N/A #N/A 1.19 0.463 6170 9.2 1.19 0.463 6170 9.2 P/N: P/N: cm^2 cm nH/T^2 mm mm #N/A #N/A Core Effective Cross Sectional Area Core Effective Path Length Ungapped Core Effective Inductance Bobbin Physical Winding Width Safety Margin Width (Half the Primary to Secondary Creepage Distance) Number of Primary Layers Number of Secondary Turns Power Integrations Inc Tel: +1 408 523 9200 Fax: +1 408 523 9300 www: http://www.powerint.com Page 15 of 46 EPR-00011 - 70 W Adapter 22-Jan-01 DC INPUT VOLTAGE PARAMETERS VMIN VMAX CURRENT WAVEFORM SHAPE PARAMETERS DMAX IAVG IP IR IRMS TRANSFORMER PRIMARY DESIGN PARAMETERS LP NP NB ALG BM BP BAC ur LG BWE OD INS DIA AWG CM CMA TRANSFORMER SECONDARY DESIGN PARAMETERS (SINGLE OUTPUT / SINGLE OUTPUT EQUIVALENT) Lumped parameters ISP ISRMS IO IRIPPLE CMS AWGS DIAS ODS INSS 82 Volts 375 Volts Minimum DC Input Voltage Maximum DC Input Voltage 0.62 1.00 2.32 1.39 1.31 Amps Amps Amps Amps Maximum Duty Cycle Average Primary Current Peak Primary Current Primary Ripple Current Primary RMS Current 273 18 2 834 2934 4140 880 191 0.16 12.88 0.71 0.07 0.64 23 512 uHenries nH/T^2 Gauss Gauss Gauss mm mm mm mm mm AWG Cmils Cmils/Am Primary Winding Current Capacity (200 < CMA < 500) 390 p Primary Inductance Primary Winding Number of Turns Bias Winding Number of Turns Gapped Core Effective Inductance Maximum Flux Density at PO, VMIN (BM<3000) Peak Flux Density (BP<4200) AC Flux Density for Core Loss Curves (0.5 X Peak to Peak) Relative Permeability of Ungapped Core Gap Length (Lg > 0.1 mm) Effective Bobbin Width Maximum Primary Wire Diameter including insulation Estimated Total Insulation Thickness (= 2 * film thickness) Bare conductor diameter Primary Wire Gauge (Rounded to next smaller standard AWG value) Bare conductor effective area in circular mils 13.96 6.22 3.65 5.05 Amps Amps Amps Amps Peak Secondary Current Secondary RMS Current Power Supply Output Current Output Capacitor RMS Ripple Current Secondary Bare Conductor minimum circular mils Secondary Wire Gauge (Rounded up to next larger standard AWG value) Secondary Minimum Bare Conductor Diameter Secondary Maximum Outside Diameter for Triple Insulated Wire Maximum Secondary Insulation Wall Thickness 1245 Cmils 19 AWG 0.91 mm 3.07 mm 1.08 mm VOLTAGE STRESS PARAMETERS VDRAIN PIVS PIVB 647 Volts 81 Volts 52 Volts Maximum Drain Voltage Estimate (Includes Effect of Leakage Inductance) Output Rectifier Maximum Peak Inverse Voltage Bias Rectifier Maximum Peak Inverse Voltage Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 16 of 46 EPR-00011 - 70 W adapter 22-Jan-01 8 Performance Data 8.1 Efficiency Efficiency vs Input Line Voltage 100 TAMB=25 C 95 90 60 W Output 70 W Output Output Efficiency (%) 85 80 75 70 65 60 55 50 50 100 150 200 250 300 Input Voltage (VAC 60Hz) Figure 5 - Efficiency vs. Line Voltage Efficiency vs Output Power 100 TAMB=25 C 90 80 Output Efficiency (%) 70 60 50 40 30 20 10 0 0 10 20 30 40 50 60 Vin = 265 VAC Vin = 85 VAC 70 80 Output Power (W) Figure 6 - Efficiency vs. Output Power (Min. and Max. Line Voltages 60 Hz) Power Integrations Inc Tel: +1 408 523 9200 Fax: +1 408 523 9300 www: http://www.powerint.com Page 17 of 46 EPR-00011 - 70 W Adapter 8.2 No-load input power No-load Input Power vs. Line Voltage 0.7 22-Jan-01 TAMB=25 C 0.6 Unit 1 Unit 2 Input Power (Watts) 0.5 0.4 0.3 0.2 0.1 0 50 100 150 200 250 300 Input Line Voltage (VAC 60Hz) Figure 7 - No-load Input Power vs. Line Voltage 8.3 Regulation / Power Limiting Line Regulation (70 Watts) 20 19.8 Io=3.66A 19.6 Output Voltage (V DC) 19.4 19.2 19 18.8 18.6 18.4 18.2 18 50 100 150 200 250 300 Input Line Voltage (VAC 60Hz) Figure 8 - Regulation vs. Input Voltage Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 18 of 46 EPR-00011 - 70 W adapter 22-Jan-01 Load Regulation 20 85 VAC 265 VAC 19.5 Output Voltage(VDC) 19 18.5 18 0 0.5 1 1.5 2 2.5 3 3.5 4 Output Current (ADC) Figure 9 - Load Regulation Overload Output Current vs Vin 7 TAMB=25 C 6.5 6 5.5 5 4.5 4 3.5 3 2.5 2 50 100 150 200 250 300 R12=24.3K R12=20.5K Max. Overload Output Current (ADC) Input Line Voltage (VAC 60 Hz) Figure 10 - Maximum Overload Current (auto-restart threshold) vs Line Voltage (2 values of R12) Note: User can program resistor R12 to give desired overload characteristic. Power Integrations Inc Tel: +1 408 523 9200 Fax: +1 408 523 9300 www: http://www.powerint.com Page 19 of 46 EPR-00011 - 70 W Adapter 22-Jan-01 9 Thermal Performance The EP11 printed circuit board was designed to allow testing within the enclosure of a commercial laptop computer adapter. This adapter has an enclosure made of plastic and incorporates copper heat spreaders with a plastic shroud to insulate them from the board components. See Figure 12. Thermal testing was done in still air. This was achieved by placing the board into a sealed cardboard box which is 11" long, 8.5" wide and 7" high. The adapter was placed on a 6" x 4" piece of single sided copper clad board (copper side down) which was taped to the bottom center of the box. The box had small openings for the thermal couple wires and the input and output cables. It was taped shut and placed in an environmental chamber. The measurements were made by attaching "T" type thermocouples to the following components using a thermally conductive glue (Loctite 384) with the wires dressed out of the enclosure in alignment with the output cable. 1 2 3 4 5 6 7 8 9 10 11 12 13 TOP249 tab: Bridge: CM Choke: Bulk / X cap: Opto: Enc. Top: Enc. Side: Snubber: Transformer: Output Diode 1: Output Diode 2: Ambient 1: Ambient 2: The metal tab of the TO-220 package of the TOP249Y. The junction of the plastic input rectifier bridge's package (BR1) and the copper heat sink HS1. The coil of the input choke L3. The narrow space between C5 and C7. The top of the package of U2. The outside of the enclosure centered on the top surface. The outside of the enclosure on its side (near the fuse F1). The package of the zener diode D2. The top of the windings nearest the center. The metal tab of the rectifier D5. The metal tab of the rectifier D1. This is suspended in the air approximately 3.5" above the center of the enclosure within the cardboard box. This is suspended in the air approximately 1" above and 0.5" to the side of the enclosure about 1" from the input cable end. Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 20 of 46 EPR-00011 - 70 W adapter 22-Jan-01 Figure 11 - Location of board mounted thermocouples The tests were run at an input line voltage of 90 Volts (60Hz). The load was adjusted to provide a nominal output power at the end of a cable of first 60 Watts, then 65 Watts, 70 Watts, and finally 72.5 Watts. Power at the power supply output connector (J2) was approximately; 61.2 Watts, 66.2 Watts, 70.6 Watts and 73.8 Watts respectively. The maximum case surface temperature was < 75C in a 40C ambient, 90 VAC, 70W (see figure 14 for thermal image) Power Integrations Inc Tel: +1 408 523 9200 Fax: +1 408 523 9300 www: http://www.powerint.com Page 21 of 46 9 01 11 9 5 8 1 4 3 2 EPR-00011 - 70 W Adapter 22-Jan-01 Figure 12 - Schematic cross-section of enclosure Note: The diagram above shows an exploded view. In actual construction, there are no air gaps between the board, copper heat spreader and case. The main path for heat dissipation is via conduction therefore air gaps, even small, greatly increase the thermal impedance from the heatsinks to ambient. Air gaps will reduce power capability and increase the temperature of components. Thermal Results in Enclosure 140 60 W 120 65 W 70 W 72.5 W Temperature (deg. C) 100 80 60 40 Top249 tab Enc. Top D1 tab Bridge Enc. Side Ambient 1 CM Choke Snubber Ambient 2 Bulk/Xcap T-former Opto D5 tab 20 0 0 2 4 6 8 10 12 14 16 18 Elapsed Time (Hours) Figure 13 - Thermal results in enclosure at elevated ambient with 60, 65,70, and 72.5 Watt loads - 90 VAC Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 22 of 46 EPR-00011 - 70 W adapter 22-Jan-01 Ambient thermocouple location (above case in free air) Cardboard box ambient Chamber ambient Case surface measurement locations Figure 14 - Thermal image of case at 45C ambient, 70 W output and 90 VAC input Measurement taken with unit inside a sealed cardboard box in environmental chamber, 8 second delay between opening door and box and taking thermal image looking into bottom of cardboard box. Power Integrations Inc Tel: +1 408 523 9200 Fax: +1 408 523 9300 www: http://www.powerint.com Page 23 of 46 EPR-00011 - 70 W Adapter 22-Jan-01 10 Waveform Scope Plots All scope plots were recorded with either a Yokogawa Model DL1540L or a Lecroy Model 9350AM, as noted. 10.1 Drain Voltage and Current During Normal Operation Both waveforms were captured using a Yokogawa Oscilloscope. Upper trace is DRAIN voltage and lower trace is DRAIN current, timebase is 2uS/div. VDRAIN IDRAIN Figure 15 - VDRAIN & IDRAIN (100 V & 1 A /div) at 70 Watt load, 85VAC input. (2 s/div) Figure 16 - VDRAIN & IDRAIN (100 V & 1 A /div) at 70 Watt load, 265VAC input. (2 s/div) Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 24 of 46 EPR-00011 - 70 W adapter 08-Dec-00 10.2 Output Voltage During Power-up Both waveforms were captured using a Yokogawa Oscilloscope. Upper trace is VOUT, the output voltage and the lower trace is VC7, the voltage across the input capacitor (C7). Timebase is 50 ms/div. In all cases the output voltage reaches regulation with no output overshoot. operation at 85 VAC the ripple present on the DC rail voltage can be clearly seen. During VOUT VC7 Figure 17 - Start-up, 5.25 load, 85 VAC VOUT & VC7 (10 & 100 V/div, 50ms/div) Figure 18 - Start-up, 5.25 load, 265 VAC VOUT & VC7 (10 & 200 V/div, 50ms/div) VOUT VC7 Figure 19 - Start-up, No load, 265 VAC VOUT & VC7 (10 & 100 V/div, 50ms/div) Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 25 of 46 EPR-00011 - 70 W Adapter 22-Jan-01 10.3 Output Voltage During Power-down Both waveforms were captured using a Yokogawa Oscilloscope. Upper trace is VOUT, the output voltage and the lower trace is VC7, the voltage across the input capacitor (C7). Timebase is 50 ms/div. During power down the output voltage falls to zero with no `glitching' due to line under voltage sensing. VOUT VC7 Figure 20 - Shut-down, 5.25 load, 85 VAC VOUT & VC7 (10 & 100V/div,50ms/div) Figure 21 - Shut-down, No-load, 85 VAC VOUT & VC7 (10 & 100V/div,50ms/div) 10.4 Drain Voltage and Current during Power-Up (265 VAC) The waveform was captured using a Yokogawa oscilloscope. VDRAIN IDRAIN Figure 22 - Start-up, 5.25 load, 265 VAC VDRAIN & IDRAIN (200 V & 1 A/div, 1s/div) Peak DRAIN voltage is acceptable at < 600 V, well below the recommended maximum of 650 Vpk. DRAIN current waveform shows no sign of core saturation. Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 26 of 46 EPR-00011 - 70 W adapter 08-Dec-00 10.5 DRAIN Current During Power-Up and Power-Down The waveforms were captured using a Lecroy oscilloscope. Upper trace is VC7, the voltage across the input bulk capacitor (C7) and the lower trace is IDRAIN, the current through the DRAIN pin. Timebase is 50 ms/div. VC7 IDRAIN Figure 23 - Start-up, 5.25 load, 265 VAC VC7 & IDRAIN (200 V & 1A/div, 50ms/div) Figure 24 - Shut-down, 5.25 load, 265 VAC VC7 & IDRAIN (200 V & 1A/div, 50ms/div) VC7 IDRAIN Figure 25 - Start-up, 5.25 load, 85 VAC VC7 & IDRAIN (50 V & 1A/div, 50ms/div) Figure 26 - Shut-down, 5.25 load, 85 VAC VC7 & IDRAIN (50 V & 1A/div, 50ms/div) Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 27 of 46 EPR-00011 - 70 W Adapter 08-Dec-00 10.6 Load Transient response (15 to 100% load change) 10.6.1 15 to 100% load change, 85 VAC The waveforms were captured using a Yokogawa oscilloscope. Upper trace is VOUT_AC, the output voltage AC coupled and the lower trace is IOUT, the output current. Timebase is 5 ms/div. 600 mVpk-pk VOUT_AC IOUT Figure 27 - Transient Response 85 VAC 50 Hz, IOUT: 3.66A to 0.5A VOUT & IOUT (200 mV & 2A/div, 5ms/div) Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 28 of 46 EPR-00011 - 70 W adapter 08-Dec-00 10.7 Load Transient response (0 to 50% load change) The 0 to 50% load variation shows no appreciable degradation in ripple response due to operation at a lower switching frequency at zero load (see bode response plots also). The waveforms were captured using a Lecroy oscilloscope. Upper trace is VOUT_AC, the output voltage AC coupled, 200 mV/div. Timebase is 5 ms/div. 10.7.1 0 to 50% load change, 85 VAC VOUT_AC 1.8 Vpk-pk Figure 28 - Transient Response 85 VAC 50 Hz, IOUT: 0 A to 1.83 A VOUT (200 mV, 5ms/div) 10.7.2 0 to 50% load change, 130 VAC 1.5 Vpk-pk Figure 29 - Transient Response 130 VAC 50 Hz, IOUT: 0 A to 1.83 A VOUT (200 mV, 5ms/div) Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 29 of 46 EPR-00011 - 70 W Adapter 10.7.3 0 to 50% load change, 130 VAC 08-Dec-00 1.4 Vpk-pk Figure 30 - Transient Response 265 VAC 50 Hz, IOUT: 0 A to 1.83 A VOUT (200 mV, 5ms/div) 10.8 Ripple Measurements 10.8.1 DC Ripple Measurement Technique Details of output ripple probe are provided below. Decoupling capacitors are included to minimize the effects of high frequency probe coupling and ensure a consistent measurement set-up. Probe RTN Probe Tip Figure 31 - Tektronix P6105A Oscilloscope Probe with Probe Master 5125BA BNC adapter, modified with wires for Probe Ground for ripple measurement. Two parallel decoupling capacitors have been added (1.0 F/50 V aluminium electrolytic and a 0.1 F/50 V ceramic) Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 30 of 46 22-Jan-01 EPR-00011 - 70 W Adapter 10.8.2 Ripple Measurement Results The results below show very good ripple results (<0.25%) even with a small input capacitor (2.1 uF/W). This is due to the line feed forward function implemented via the L pin, R14 and R15. The waveforms were captured using a Yokogawa oscilloscope. Trace is VOUT_AC, the output voltage AC coupled into the `scope input at 20 mV per division. Timebase is 5 ms/div. Figure 32 - Output ripple 85 VAC 50Hz, IOUT=3.6 A VRIPPLE (20 mV / div, 5 ms / div) Page 31 of 46 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com EPR-00011 - 70 W Adapter 22-Jan-01 11 Control Loop Characteristics The control loop characteristics were measured with a Venable measurement system, which breaks the control loop between the emitter of the opto-isolator (U2) and the control pin of the TOP249Y (U1) and its associated components; C11, R11, and C17. The results are tabulated below, followed by graphs of the last five table entries: Result # 1 2 3 4 5 6 7 8 9 10 11 VIN (VAC) 130 85 85 265 265 85 85 265 265 115 115 IOUT (ADC) 3.16 3.16 0.71 0.70 3.16 1.0 3.66 3.66 0 1.0 0 Crossover Freq. 1000 Hz 1220 Hz 435 Hz 556 Hz 1000 Hz 800 Hz 1600 Hz 1000 Hz 530 Hz 380 Hz 500 Hz Phase Margin 53 deg. 55 deg. 45 deg. 50 deg. 50 deg. 52 deg. 62 deg. 56 deg. 95 deg. 45 deg. 120 deg Note results for 9, 10 and 11 are shown without adding a 180 deg offset for the secondary error amplifier. Therefore phase margin is referenced to -180 deg. Measurements were made at zero load to confirm stability during the lower switching frequency operation at no-load. Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 32 of 46 22-Jan-01 EPR-00011 - 70 W Adapter Table 2 - Summary of Gain/Phase Measurements 11.1 Gain Phase Results Gain (dB) Phase (deg.) Phase Margin Figure 33 - Gain Phase Plot 6: VIN: 85 VAC, IOUT: 1 A, Crossover=800 Hz, Phase Margin=52 Page 33 of 46 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com EPR-00011 - 70 W Adapter 22-Jan-01 Gain (dB) Phase (deg.) Phase Margin Figure 34 - Gain Phase Plot 7: VIN: 85 VAC, IOUT: 3.66 A, Crossover=1.6 kHz, Phase Margin=62 Gain (dB) Phase Margin Phase (deg.) Phase Margin Figure 35 - Gain Phase Plot 8: VIN: 265 VAC, IOUT: 3.66 A, Crossover=1 kHz, Phase Margin=56 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 34 of 46 22-Jan-01 EPR-00011 - 70 W Adapter Gain (dB) Phase (deg.) Phase Margin Figure 36 - Gain Phase Plot 9: VIN: 265 VAC, IOUT: 0 A, Crossover=530 Hz, Phase Margin=95 Gain (dB) 1 A load Gain (dB) 0 A load Phase (deg.) 0 A load Phase (deg.) 1 A load Phase Margin 0 A load Phase Margin 1 A load Figure 37 - Gain Phase Plot 10/11: VIN: 115 VAC, IOUT: 1A & 0 A, Crossover=380 & 500 Hz, Phase Margin=45 & 120 Page 35 of 46 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com EPR-00011 - 70 W Adapter 22-Jan-01 12 Conducted EMI Scans The attached plots show EMI performance for the EP11 as compared to the CISPR22B conducted emissions limits. Both input AC lines were essentially identical. This worst case scan was taken with an input of 230VAC and a 70W resistive load. The output return was connected to the LISN's artificial hand connection to simulate a worst case condition. QP Limit AV Limit QP AV EN55022B CISPR22B Figure 38 - Highest Measured Conducted Emissions Scan (230 VAC, 70 W, with artificial hand) Note: EMI measurements without artificial hand grounding will be significantly lower than shown above. Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 36 of 46 22-Jan-01 EPR-00011 - 70 W Adapter 13 Appendix A - Thermal considerations: The TOPSwitch-GX family significantly extends the power capability over the TOPSwitch-II family of devices. The higher power capability is a result of a lower internal high voltage MOSFET RDS(ON) over that of any previous TOPSwitch-II. This lower RDS(ON) enables compact high power adapters such as the EP11. The output powers of higher power adapter supplies like EP11 are all thermally limited to some degree. One of the important design considerations is often compact size which together with efficiency limitations combine to limit the maximum continuous power of the design. This adapter is no exception. The maximum continuous power is rated at 70 Watts in an enclosure at a 40 C ambient temperature (see Figure 13). This rating is very "packaging" dependent. The power dissipated by the high voltage MOSFET within the TOP249Y is a significant source of heat. Together with the heat generated in the transformer, output diodes, input rectifier and filter, as well as the output filter must be managed to keep the maximum component temperatures within limits. Layout and heat sinking and the complete package must be designed to manage the heat generated by the board components. Adapters are generally completely enclosed external power sources that provide little or no ventilation for the internal converter components. They are also generally small in size which creates high power densities and necessitates very tight packaging of components. The first and most fundamental performance element to optimise for a successful high power adapter is its efficiency. Other key considerations include; heat sink design, "hot spots", and maximum component temperatures. Page 37 of 46 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com EPR-00011 - 70 W Adapter 22-Jan-01 13.1 Efficiency: Items to consider for maximising efficiency: * Transformer: - Minimise leakage inductance and conduction losses - Use highest possible duty factor and operate in continuous mode for reduced peak currents (the copper window of the transformer bobbin may limit this) * Output Diodes: - Use low forward drop, higher current rated diodes - Use Schottky-barrier diodes when possible - Parallel diodes to reduce forward drop. Take care to make sure that paralleled diodes share current equally (the EP11 uses dual secondary windings and a common heat sink to achieve this). - Allow diodes to run as hot as possible (consistent with maximum board temperature and component life constraints). This will minimize the forward drop. * Power Switch (TOPSwitch-GX): - Use a lower RDS(ON) part (the TOP249 used in the EP11 is capable of over 250 Watts in an open frame design) - Use the highest possible maximum operating duty cycle to reduce conduction losses (this must be balanced against increased leakage and transformer losses). * Line Filter: - Use as few turns as possible for inductor windings - Increase capacitor value (rather than inductor value) where practical, to minimize differential choke size down. 13.2 Heat Sinking: Heat sinking power devices such as the TOPSwitch-GX, input diodes, and output diodes will be more critical in an adapter application than in open frame designs. This is largely because all of the generated heat must be CONDUCTED through the enclosure walls. The heat sinks used in EP11 are made of copper. Copper has high thermal conductivity (~3.94 W/cm oC), but it is heavy. Aluminum may be used instead. It is lighter, but it has somewhat lower thermal conductivity (~2.18 W/cm oC). The net thermal conductivity from the heat generating components to the outside air of the adapter's enclosure together with the overall efficiency of the supply determines the maximum continuous power output for a given environment. Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 38 of 46 22-Jan-01 EPR-00011 - 70 W Adapter 13.3 Heat Spreading and Enclosure Surface Temperature: The enclosures of adapters are generally limited to an absolute maximum external surface temperature (defined by safety approval agencies such as U.L.). For higher power adapters, it is often necessary to use an internal heat spreader to evenly distribute the internally generated heat across the inside of the enclosure's outside walls. This will help eliminate "hot spots". The "heat spreader" is generally nothing more than an additional foil wrap (or sheets of copper or aluminum) between the converter and the outside enclosure walls. The caveat is that these heat spreaders must generally be electrically insulated from the heat sinks to provide safety isolation. This electrical insulation invariably contributes significant thermal impedance. Even with heat spreaders, care must be taken to avoid crowding the heat generating components together more than is necessary. 13.4 Component Temperature: The maximum operating temperature of the power devices within the converter may be limited by various considerations depending on the type of component. TOPSwitch-GX : The TOPSwitch-GX is thermally protected by its internal thermal shutdown feature. This feature prohibits the device from operation when the internal junction o temperature (TJ ) exceeds 140 C (typ.). This junction temperature will be higher than the package tab temperature (TC) depending on the amount of power being dissipated. It is good design practice to keep this junction temperature below o 120 C to guarantee continuous operation with adequate margin. For the EP11, thermal shutdown occurs at a TOP249 tab temperature (TC) of approximately o 120 C (depending somewhat on the output power level). At 65 Watts output, the EP11's TOP249 tab stabilises at TC=103.6 oC in an ambient of approximately 40oC (while in the enclosure with a 90VAC input). At 70Watts this tab temperature stabilises at TC=111.9 oC. Care must be taken with any package design to make sure that adequate margin remains at the maximum output power and ambient temperature. One way to test this is to stabilise the supply at maximum power in the desired environment and subsequently increase either the power or the ambient temperature in small increments (waiting for the internal temperatures to stabilise each time) until shutdown occurs. This allows the designer to determine how much margin there is for thermal shutdown. Page 39 of 46 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com EPR-00011 - 70 W Adapter 22-Jan-01 - Input and Output Diodes: For the power diodes the maximum junction temperature is generally 150oC. Depending on the required product life expectancy and the maximum lead temperature of the PC board material chosen, the actual allowed maximum junction temperature (TJ ) may be significantly less. Also the junction temperature (TJ ) will be significantly higher than the tab temperature (TC) and must be computed from the measured tab temperature and the estimated power dissipation in the device using the thermal impedance junction to case (JC) of the device given in its data sheet. Magnetic Components: If the transformer and the other magnetic components use 130 oC magnet wire in their construction, then the maximum hot spot temperature is limited to 105 oC. Higher operating temperatures are possible with higher temperature rated wire. o Generally, however, the ferrite core temperatures should be limited to near 100 C to maintain the saturation flux density. - 13.5 Conclusion: Careful design and rigorous testing are required to ensure that a design will perform adequately under high load and high temperature conditions. Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 40 of 46 22-Jan-01 EPR-00011 - 70 W Adapter 14 Appendix B - Custom Component Documentation: 14.1 Toroid Filter Inductor (L2): FL1 FL2 ELECTRICAL SPECIFICATIONS: Inductance MATERIALS: Item [1] [2] Description Core: Powder Iron Toroid, Micrometals T50-26 or equivalent Epoxy coated Magnet Wire: #25 AWG Solderable Double coated Measured at 100KHz 70.0 H min. COIL WINDING INSTRUCTION: Use item [2]. Wind 48 turns; spread evenly around circumference of the core as illustrated below. ILLUSTRATION: Wire Item # 2 Toroid Item # 1 0.05" Not Tinned 0.40" Tinned FL 1 FL2 Page 41 of 46 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com EPR-00011 - 70 W Adapter 22-Jan-01 14.2 Output Inductor (L1) 10T # 23AWG (RED) FL1 FL3 FL2 FL4 10T # 23AWG (GREEN) ELECTRICAL SPECIFICATIONS: Inductance(LCM) Inductance (LL) Pin1-3 or 2-4 Measure at 100KHz 1-2 with pin 3-4 shorted Measure at 100KHz 200 uH min. 1.6 uH (ref.) MATERIALS: Item [1] [2] [3] Description Core: Ferrite Torrid TDK T10 x2.5 x5 Material H5B2 Epoxy coated Magnet Wire: # 23 AWG Solderable Double coated (RED) Magnet Wire: # 23 AWG Solderable Double coated (GREEN) COIL WINDING INSTRUCTION: Start at pin FL1 wind 10 turns (Item #2) on one half of Toroid. End at pin FL3 , Start at pin FL2 wind 10 turns (Item #3) in the same direction on other half of Toroid. End at pin FL4. Spread the wire evenly around each half of the core circumference, as illustrated below. ILLUSTRATION: Red wire Item # 2 Green wire Item # 3 Core 0.05" Not Tinned 0.40" Tinned FL1 FL3 FL2 FL4 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 42 of 46 22-Jan-01 EPR-00011 - 70 W Adapter 14.3 Heat sink #1 (TOPSwitch-GX and Input Bridge) 14.4 Heat sink #2 (Output Diodes) Page 43 of 46 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com EPR-00011 - 70 W Adapter 22-Jan-01 15 Revision History Date 10/16/00 11/15/00 11/17/00 Author DJK PV PV Revision 0.1 1.0 1.1 Description & changes Original draft First Release Update - added photo of thermocouple location plus removed typographical errors Added power levels to temp chart, low load efficiency, bode plots at zero load, 0 to 50% load transient, power density, enclosure internal dimensions. Thermal image added Appendix B, Materials, Item [1] changed from T50-26C to T50-26 to reflect correct part number 12/06/00 PV 1.2 12/08/00 01/22/01 PV PV 1.3 1.4 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com Page 44 of 46 22-Jan-01 EPR-00011 - 70 W Adapter NOTES Page 45 of 46 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com EPR-00011 - 70 W Adapter 22-Jan-01 For the latest updates, visit our website: www.powerint.com Power Integrations reserves the right to make changes to its products at any time to improve reliability or manufacturability. Power Integrations does not assume any liability arising from the use of any device or circuit described herein, nor does it convey any license under its patent rights or the rights of others. are registered trademarks of Power Integrations, Inc. PI Logo and (c)Copyright 2000, Power Integrations, Inc. WORLD HEADQUARTERS NORTH AMERICA - WEST Power Integrations, Inc. 5245 Hellyer Avenue San Jose, CA 95138 USA. Main: +1*408*414*9200 Customer Service: Phone: +1*408*414*9665 Fax: +1*408*414*9765 CHINA Power Integrations, China Rm# 1705, Bao Hua Bldg. 1016 Hua Qiang Bei Lu Shenzhen Guangdong, 518031 Phone: +86*755*377*9485 Fax: +86*755*377*9610 APPLICATIONS HOTLINE World Wide +1*408*414*9660 Power Integrations Inc Tel: +1 408 414 9200 Fax: +1 408 414 9201 www: http://www.powerint.com hctiwSPOT NORTH AMERICA - EAST & SOUTH AMERICA Power Integrations, Inc. Eastern Area Sales Office 1343 Canton Road, Suite C1 Marietta, GA 30066 USA Phone: +1*770*424*5152 Fax: +1*770*424*6567 EUROPE & AFRICA Power Integrations (Europe) Ltd. Centennial Court Easthampstead Road Bracknell Berkshire RG12 1YQ, United Kingdom Phone: +44*1344*462*300 Fax: +44*1344*311*732 JAPAN Power Integrations, K.K. Keihin-Tatemono 1st Bldg. 12-20 Shin-Yokohama 2Chome, Kohoku-ku, Yokohama-shi, Kanagawa 222, Japan Phone: +81*45*471*1021 Fax: +81*45*471*371 TAIWAN Power Integrations International Holdings, Inc. 2F, #508, Chung Hsiao E. Rd., Sec. 5, Taipei 105, Taiwan Phone: +886*2*2727*1221 Fax: +886*2*2727*1223 KOREA Power Integrations International Holdings, Inc. Rm# 402, Handuk Building, 649-4 Yeoksam-Dong, Kangnam-Gu, Seoul, Korea Phone: +82*2*568*7520 Fax: +82*2*568*7474 INDIA (Technical Support) Innovatech #1, 8th Main Road Vasanthnagar Bangalore 560052, India Phone: +91*80*226*6023 Fax: +91*80*228*9727 APPLICATIONS FAX World Wide +1*408*414*9760 Page 46 of 46 |
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