Application note VIPower: 30 W SMPS using VIPer50A-E Introduction In a growing consumer market, cost effective solutions with good performances and reliability able to meet energy saving international or local standards (Blue Angel) are needed. STMicroelectronics has, among its wide products portfolio, the VIPer product family offering excellent solutions with all features to design SMPS suitable for consumer applications. Thanks to the VIPower Technology, these devices combine on the same silicon chip a stateof-the-art PWM control circuit along with an optimized high voltage avalanche rugged Vertical Power MOSFET. The benefits obtained using these devices are: Fewer components compared to a discrete solution Less space on PCB Simpler design phase Automatic burst mode operation in standby for energy savings Cost effective solution for SMPS This document describes the results obtained from an off-line SMPS designed with VIPer50A-E. It has been designed for European mains, providing 30 W on two outputs. The main target of this application is total power consumption less than 1 W (Blue Angel Norm) in standby mode delivering an output power of 400 mw. September 2007 Rev 2 1/13 www.st.com
Contents AN1513 Contents 1 Schematic................................................. 5 2 Standby................................................... 6 3 Full load test............................................... 8 4 Load step.................................................. 9 5 Short circuit protection...................................... 10 6 Overvoltage protection...................................... 10 7 Thermal test............................................... 11 8 Conclusion................................................ 12 9 Revision history........................................... 12 2/13
List of tables List of tables Table 1. Electrical specifications..................................................... 5 Table 2. Standby measurements at 65 ma on output 1................................... 6 Table 3. Standby measurements at 65 ma on output 1................................... 7 Table 4. Full load measurements.................................................... 9 Table 5. Overvoltage measurements................................................ 10 Table 6. Thermal measurements................................................... 11 Table 7. Transformer specification and construction.................................... 11 Table 8. Document revision history................................................. 12 3/13
List of figures AN1513 List of figures Figure 1. Electrical schematic....................................................... 6 Figure 2. Adjustment for frequency reduction........................................... 8 Figure 3. Drain current at full load.................................................... 8 Figure 4. Voltage current at full load.................................................. 8 Figure 5. Load transient (V out1, V out2 )................................................. 9 Figure 6. Load transient (V comp, V DD )................................................. 9 Figure 7. Short circuit (V out1 )....................................................... 10 Figure 8. Short circuit (V out2 )....................................................... 10 Figure 9. Transformer cross section................................................. 11 4/13
Schematic 1 Schematic The power supply topology is a discontinuous current mode flyback converter, designed with secondary feedback, optocoupler and TL431C. The output voltage regulation is performed on the 6.5 V, so the output voltage 10 V can change according to the load applied on both outputs. To keep the drain voltage at a safe level and to meet the standby power specification, the clamper used is a Transil 1.5KE220A instead of a classic R-C-D circuit. While the R-C-D circuit dissipates energy in any load condition, the Transil dissipates energy only when the drain voltage spike reaches its breakdown voltage. This consideration is important in order to keep low consumption (<1 W) during standby operation mode. A Zener diode is also connected to pin Comp for short circuit protection. This diode clamps the voltage on pin Comp under the maximum value (4.5 V), reducing the maximum power delivered by the SMPS. During short circuit due to the short working time, the V DD voltage drops below the undervoltage lockout threshold and the VIPer starts working in hiccup mode. Even if the peak output current is higher than the nominal one, thanks to the on/off cycles, the average current flowing in the shorted output components is kept under control at a safe value avoiding diodes failure and any other damage to the circuit. The output rectifiers are Schottky diodes for better efficiency thanks to their lower forward voltage drop and negligible switching losses. The output capacitors are low ESR type to minimize the output ripple and to manage the RMS output ripple current. Table 1. Electrical specifications Parameter Value Input voltage European standard 230V ac ±15% Output voltage 1 6,5 V±3% at 2.5 A Output voltage 2 10 V±8% at 1.5 A Standby consumption <1 W Efficiency >80% Max working ambient temperature 60 C 5/13
Standby AN1513 2 Standby The first test performed is the measure of the power consumption during standby operation mode as the main target of this application is consumption lower than 1 W. For better accuracy, because the power level is very low, the power supply has been tested with a dc voltage source. Table 2. Standby measurements at 65 ma on output 1 V in I in V out1 at 65 ma V out2 at 0 ma P out P in Efficiency Switching frequency Vdc ma Vdc Vdc W W % KHz 276 3.33 6.51 16.6 0.42 0.92 46 BURST 325 3.02 6.51 17.5 0.42 0.98 43 BURST 374 2.67 6.51 18.2 0.42 1.0 42 BURST Figure 1. Electrical schematic D1 DF06M C6 2n2-Y2 MOUNTED ON HEAT SINK 1 D3 1000uF-25V YXF 1000uF-25V YXF 13-14 +10V STPS8H100CF C7 C8 C5 47uF-400V D2 9 230Vac±15% 1.5KE220A RTN D4 STTA106 L2 D5 D6 2200uF-16V YXF 2200uF-16V YXF 7 11-12 +6.5V 2,2uH 1N4148 STPS745F R2 C11 C12 18R C10 R1 100uF-50V YXF 10 15K 8 RTN C9 22nF IC1 VDD DRAIN R3 470R VIPer50A-E OSC C13 COMP SOURCE MOUNTED ON HEAT SINK 2.2nF 4 5 6 2 1 4 2 JP1 MOLEX F1 FUSE 2A - 5*20 C3 1nF 1 4 C1 C2 100nF 100nF L1 C4 B82732-27mH 1nF 2 T1 010150W-C MAGNETICA 3 MOUNTED ON HEAT SINK D7 C14 22nF IC2 TCDT1102G R6 R4 6K8 1% 1K0 C15 R5 22K 150nF BZX79-4V3 IC3 R7 TL431C 4K22 1% 1 2 1 2 3 3 1 5 4 2 3 6/13
Standby The VIPer50A-E is designed to work in burst mode automatically when the power delivered to the load becomes very low. The burst frequency and its duty-cycle depend on the transformer parameters and the power delivered. The burst mode takes place when the power transferred during the minimum on time is greater than the power required by the load. This should increase the output voltage, but instead the control loop reacts by missing some cycles. It is important to point out that during this working mode, the output voltage is always perfectly under control. The result is a working mode where the effective duty-cycle is much lower than the minimum under normal operation. To further decrease the consumption during standby operation an additional test has been done. Of course the burst mode has efficiency proportional to its working duty-cycle and to work or not in burst mode is also dependent on the primary inductance of the transformer. Sometimes it is difficult to optimize the primary inductance of the transformer and obtain an efficient burst. The result can be just a few cycles missed and most of the pulses are present at switching frequency. It can be an advantage to work at a lower fixed frequency, giving up the burst operation mode. The network Q1, R8 R10 decreases the frequency sinking current from R1 (timing resistor) when pin Comp (5) is lower than 1.6 V. In this way the charging current of C13 (timing capacitor) decreases and according to the law Equation 1 T = C -------------- V I the frequency starts to reduce until the minimum frequency is at standby load. In steady state condition at full load the switching frequency has been set to around 70 KHz, while in standby it is around 30 KHz. Table 3. Standby measurements at 65 ma on output 1 V in I in V out1 at 65 ma V out2 at 0 ma P out P in Efficiency Switching frequency Vdc ma Vdc Vdc W W % KHz 276 2.98 6.51 19.5 0.42 0.82 53 30 325 2.69 6.51 19.6 0.42 0.87 48 29 374 2.48 6.51 19.8 0.42 0.93 45 28 7/13
Full load test AN1513 3 Full load test The parameters checked at full load have been the efficiency and main working parameters of the VIPer for system reliability. The minimum voltage has been set at 240V dc considering the minimum voltage ripple on the bulk capacitor when the power supply is connected to the ac mains. The drain voltage spike reaches its maximum value at full load and maximum input voltage. This spike is caused at turn-off by the energy stored in the primary leakage inductance of the transformer during the T on. This is the reason why it is recommended to design the power transformer with a primary leakage inductance as low as possible. In addition a good coupling between primary and secondaries improves total regulation, especially in SMPS with more than one output. Figure 2. Adjustment for frequency reduction R8 68K R1 15K R2 18R C9 2 3 Q1 R10 18K 22nF C13 1 VDD OSC VIPer50A-E COMP IC1 DRAIN SOURCE 2.2nF BC546 5 4 R9 15K D7 C14 22nF BZX79-4V3 Figure 3. Drain current at full load Figure 4. Voltage current at full load The maximum peak voltage measured on the drain is 642 V, thanks to the clamp 1.5KE220A. This value guarantees a reliable operation of VIPer with a good margin with respect to the maximum B VDSS, which is 700 V. The VIPer is an avalanche rugged device able to withstand a momentary energy peak caused by voltage greater than 700 V. 8/13
Load step The SMPS meets the specification with efficiency better than 80% at any input voltage value, as shown in Table 4. Table 4. Full load measurements Full load V in I in V out1 at 2.5 A V out2 at 1.5 A P out P in Efficiency Vdc ma Vdc Vdc W W % 240 160 6.50 10.26 31.6 38.4 82.3 325 118 6.50 10.25 31.6 38.3 82.5 374 102 6.50 10.25 31.6 38.1 82.9 4 Load step This SMPS has been designed to operate under two conditions: standby and full load. In Figure 5 and Figure 6 show the outputs voltages during load steps from standby and full load and vice versa. CHA is the resampling of V out1 highlighting that no undershoot or overshoot is present during load transient. The same test has been done to show the behavior of the voltage on pins V DD and Comp. Figure 5. Load transient (V out1, V out2 ) Figure 6. Load transient (V comp, V DD ) 9/13
Short circuit protection AN1513 5 Short circuit protection The SMPS is protected against short circuit on both outputs. The short circuit test has been done with an active load for the complete input voltage range. As shown in Figure 7 and Figure 8, taken at worst case at 374 V dc, during short circuit on output1 or output 2, the SMPS works in hiccup mode keeping the mean output current at a safe value for the rectifiers, respectively at 3.3 A for output 1 and 2.2 A for output 2. Also the drain voltage remains at a safe level during short circuit. To achieve these results a Zener diode has been connected between pin Comp and Source of the VIPer. This Zener clamps the voltage on pin Comp, limiting the maximum primary peak current. During short circuit the auxiliary voltage is low because it is proportional to the output voltage. V DD drops under the low threshold (8 V) blocking the VIPer and beginning the start up cycle. When C12 is charged at 11 V, the VIPer turns on again. It works as long as C12 is discharged to 8 V because the auxiliary voltage, thanks to the reduced duty-cycle, is not capable of supplying the VIPer. Figure 7. Short circuit (V out1 ) Figure 8. Short circuit (V out2 ) 6 Overvoltage protection Thanks to the V DD regulation capability, this SMPS is protected against secondary feedback failure. If the secondary feedback loses control, the voltages increase. As the auxiliary voltage is proportional to the outputs, V DD increases up to 13 V, which is the typical regulation value for VIPer50A-E, so the VIPer takes control avoiding any damage to the output capacitors and rectifiers. Table 5 gives the measurements in standby and at full load with R6 removed from the board to simulate secondary feedback failure. Table 5. Overvoltage measurements Operation mode V out1 V out2 Standby 9.5V 22.5 V Full load 7.2V 11.2 V 10/13
Thermal test 7 Thermal test For system reliability it is important to keep device temperature at a safe level, considering the maximum ambient temperature especially when the board is inside a chassis. In Table 6 shows the temperatures measured on the SMPS after 4 hours of warm-up at full load at nominal input voltage 230V ac : the results are compatible with robust design rules. Table 6. Thermal measurements Measure point Temperature ( C) Ambient 25 VIPer50A-E 47 STPS8H100F 53 STPS745 58 1.5KE220A 84 STTA106 55 DFO6M 52 T1 Ferrite 53 Table 7. Transformer specification and construction Parameter Value Primary inductance 670 µh ±8% 58 TURNS Winding output1 4 TURNS Winding output2 6 TURNS Auxiliary winding 6 TURNS Primary leakage inductance 12 µh 1.8% of Lp Core EPCOS ETD29-N67 Code B66358-G500-X67 Figure 9. Transformer cross section 11/13
Conclusion AN1513 8 Conclusion The main specification requirements of this application have been reached and thanks to the VIPer features, it also has been demonstrated that a quite difficult task such as attaining very low power consumption in standby is easily achievable. 9 Revision history Table 8. Document revision history Date Revision Changes 04-Jan-2005 1 First issue 27-Sep-2007 2 The document has been reformatted VIPer50A becomes VIPer50A-E 12/13
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