Journal of Power Electronics

The Korean Institute of Power Electronics (전력전자학회)
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Actively Clamped Two-Switch Flyback Converter with High Efficiency

  • Yang, Min-Kwon (Division of Electronic Engineering, Chonbuk National University) ;
  • Choi, Woo-Young (Division of Electronic Engineering, Chonbuk National University)
  • Received : 2015.01.30
  • Accepted : 2015.04.24
  • Published : 2015.09.20
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Abstract

This paper proposes an actively clamped two-switch flyback converter. Compared to the conventional two-switch flyback converter, the proposed two-switch flyback converter operates with a wide duty cycle range. By using an active-clamp circuit, the proposed converter achieves zero-voltage switching for all of the power switches. Zero-current switching of an output diode is also achieved. Thus, compared with the conventional converter, the proposed converter realizes a higher efficiency with an extended duty cycle. The performance of the proposed converter is verified by the experimental results with use of a 1.0 kW prototype circuit.

Keywords

I. INTRODUCTION

High switching frequency pulse-width modulated DC-DC converters have been widely used for switch-mode power supplies [1]-[8]. Among these converters, the flyback converter is most popularly used because of its simple power circuit structure [9], [10]. However, the conventional flyback converter is limited by high switch voltage stress [11], [12]. The two-switch flyback converter shown in Fig. 1 uses an additional switch and two clamping diodes to overcome the drawback of the conventional flyback converter [13]. The two switches S1 and S2 are turned on and off simultaneously. The two clamping diodes DC1 and DC2 clamp the voltage across S1 and S2 by the input voltage Vin. The energy stored in the transformer T is recycled to the input side through the clamping diodes DC1 and DC2 [14]. However, the conventional two-switch flyback converter operates under a hard-switching condition [15], [16]. The energy stored in the leakage inductor Llk causes voltage spikes when S1 and S2 are turned off. The voltage spikes increase the switching losses and consequently decrease the power efficiency. Moreover, the duty cycle of the conventional two-switch flyback converter is limited to 0.5 because the demagnetization of the transformer should be guaranteed [17]. The narrow duty cycle range limits the practical use of the two-switch flyback converter.

Fig. 1.Circuit diagram of the conventional two-switch flyback converter.

To address these problems, this paper proposes an actively clamped two-switch flyback converter. Fig. 2 shows the circuit diagram of the proposed converter. The proposed converter has auxiliary switches S3 and S4 and one clamping capacitor Cc. By using an active-clamp circuit, the proposed converter extends the duty cycle of the converter. With the help of the clamping capacitor voltage Vc, the transformer can be demagnetized for the duty cycle from 0 to 1. Furthermore, zero-voltage switching (ZVS) of all of the power switches is achieved. Zero-current switching (ZCS) of an output diode is also achieved. Given that the proposed converter operates under soft-switching conditions, this converter can better improve the power efficiency compared with the conventional converter. The operation principle and converter features are described with simulation verifications. The performance of the proposed converter is verified by the experimental results with the use of a 1.0 kW prototype circuit. Compared with the conventional converter, the proposed converter improves the efficiency by 1.5 % at the rated output power.

Fig. 2.Circuit diagram of the active-clamped two-switch flyback converter.

 

II. PROPOSED CONVERTER

A. Operation Principle

Fig. 2 shows the circuit diagram of the proposed converter. The primary-side circuit consists of power switches (S1, S2, S3, S4), a clamping capacitor (Cc), and a transformer (T). Power switches have body diodes (D1, D2, D3, D4) and output capacitors (C1, C2, C3, C4). The transformer T has a magnetizing inductor (Lm) and leakage inductor (Llk) with the turns ratio of 1:N, where N = Ns/Np. The secondary-side circuit consists of an output diode (Do) and an output capacitor (Co). Vin is the input voltage. Vc is the clamping capacitor voltage. Vo is the output voltage.

Fig. 3 shows the operation modes of the proposed converter during one switching period Ts. The converter has five operation modes during Ts. Fig. 4 shows the switching waveforms of the proposed converter during Ts. Fig. 4(a) shows the switch voltages VS1 ,VS2, VS3, and VS4 and switch currents iS1, iS2, iS3, and iS4. Fig. 4(b) shows the output diode voltage VDo, diode current iDo, and primary current ip. When S1 and S4 are turned on, S2 and S3 are turned off. When S2 and S3 are turned on, S1 and S4 are turned off. Power switches operate complementarily with a short dead time Td. The duty cycle D is based on the on-time of S1 and S4. Then, the duty cycle of S2 and S3 is 1 – D. Before t = t0, S2 and S3 have been turned off. The voltages VS1 and VS4 have been zero when the primary current ip flows through D1 and D4.

Fig. 3.Operation modes of the proposed converter during Ts.

Fig. 4.Switching waveforms of the proposed converter during Ts: (a) switch voltages VS1 ,VS2, VS3, and VS4 and switch currents iS1, iS2, iS3, and iS4 and (b) output diode voltage VDo, diode current iDo, and primary current ip.

Mode 1 [t0, t1]: At t = t0, S1 and S4 are turned on at zero voltage. Lm and Llk stores energy from Vin. The magnetizing inductor current iLm increases linearly as follows:

Mode 2 [t1, t2]: At t = t1, S1 and S4 are turned off. The primary current ip charges C1 and C4 and discharges C2 and C3. VS1 increases from zero to Vin. VS4 increases from zero to Vin + Vc. VS3 decreases from Vin + Vc to zero. VS2 decreases from Vin to zero. Given that the switch output capacitorCs (= C1 = C2 = C3 = C4) is very small, the time interval during this mode is considered negligible compared with Ts. iLm is considered to be constant. The leakage inductor Llk starts discharging its energy by the primary current ip. D2 and D3 conduct the primary current ip.

Mode 3 [t2, t3]: At t = t2, S2 and S3 are turned on at zero voltage. iLm decreases linearly as follows:

When the output diode Do is turned on, the energy stored in Lm is transferred to the output. A series-resonance between Llk and Cc occurs. As the energy stored in Llk is fully discharged by the series-resonance, the output voltage Vo at the secondary side is reflected to the primary side. The primary current ip flows as follows:

Zr is the impedance of the series-resonant circuit. ωr is the angular resonant frequency as follows:

Mode 4 [t3, t4]: At t = t3, the series-resonance is finished when the output diode current iDo is zero. Do is turned off at zero current. ZCS of Do is achieved. The leakage inductor Llk has no energy in this mode.

Mode 5 [t4, t5]: At t = t4, S2 and S3 are turned off. The primary current ip charges C2 and C3 and discharges C1 and C4. VS1 decreases from Vin to zero. VS4 decreases from Vin + Vc to zero. VS3 increases from zero to Vin + Vc. VS2 increases from zero to Vin. The leakage inductor Llk starts charging its energy by the primary current ip. D1 and D4 conduct the primary current ip. The next switching cycle repeats when S1 and S4 are turned on at zero voltage.

B. Converter Features

By the volt-second balance law on Lm during Ts, the following relation between Vin and Vc is obtained as follows:

From (6), the clamping capacitor voltage Vc is obtained as follows:

By the volt-second balance law on the secondary winding of T during Ts, the following relation between Vin and Vo is obtained:

Fig. 5 shows the graph between the normalized voltage gain and the duty cycle D. The duty cycle ranges from 0 to 1. As shown in (7), the clamping capacitor voltage Vc is changed by the duty cycle D. This clamping capacitor voltage affects the transformer in the form of demagnetizing voltage when S2 and S3 are turned off. The proposed converter has a wider duty cycle compared with that of the conventional two-switch flyback converter.

Fig. 5.Graph between the normalized voltage gain and the duty cycle D.

At t = t0, to achieve ZVS of S1 and S4, the energy stored in Lm is larger than the energy stored in Cs. The following condition should be satisfied to achieve ZVS of S1 and S4:

At t = t2, to achieve ZVS of S2 and S3, the energy stored in Lm is larger than the energy stored in Cs. The following condition should be satisfied to achieve ZVS of S2 and S3:

At t = t3, to achieve ZCS of Do, the diode current iDo becomes zero before Do is turned off. The time interval from t3 to t4 should be ensured to achieve ZCS of Do. This time duration can be changed by the angular resonant frequency ωr. The critical condition is ip(Ts) = iLm(Ts). Then, the angular resonant frequency must satisfy the following condition: as

where the critical angular resonant frequency ωrc = 2πfrc is decided by

where Ro,min is the minimum output resistance.

 

III. SIMULATION VERIFICATIONS

Fig. 6 shows the simulation results of the proposed converter when Vin is 350 V, Vo is 200 V, and D is 0.4. Fig. 6(a) shows the switch voltages VS1 and VS2 and switch currents iS1 and iS2 for a 1.0 kW output power. Fig. 6(b) shows the switch voltages VS3 and VS4 and switch currents iS3 and iS4 for a 1.0 kW output power. Switch currents are negative before the power switches are turned on. Switch currents flow through the body diodes of the power switches before the power switches are turned on. Thus, ZVS of power switches is achieved. Fig. 7 shows the simulation results of the proposed converter when Vin is 350 V, Vo is 450 V, and D is 0.6. Fig. 7(a) shows the switch voltages VS1 and VS2 and switch currents iS1 and iS2 for a 1.0 kW output power. Fig. 7(b) shows the switch voltages VS3 and VS4 and switch currents iS3 and iS4 for a 1.0 kW output power. As shown in Fig. 7, ZVS of power switches is achieved. Moreover, the duty cycle of the converter can be extended to 0.6. The proposed converter operates with a wide duty cycle and reduced switching losses. Fig. 8 shows the simulated waveforms of the diode voltage VDo, diode current iDo, and primary current ip when Vin is 350 V, Vo is 200 V, and D is 0.4 for a 1.0 kW output power. For the series-resonance between Llk and Cc, Llk = 7.0 μH and Cc = 1.0 μF are selected. The resonant frequency fr (= ωr/2π) is decided as fr = 60.1 kHz. Before the output diode is turned off, the diode current becomes zero. ZCS of an output diode is achieved, which reduces the switching power losses of the converter.

Fig. 6.Simulation results for D = 0.4: (a) switch voltages VS1 and VS2 and switch currents iS1 and iS2 and (b) switch voltages VS3 and VS4 and switch currents iS3 and iS4.

Fig. 7.Simulation results for D = 0.6: (a) switch voltages VS1 and VS2 and switch currents iS1 and iS2 and (b) switch voltages VS3 and VS4 and switch currents iS3 and iS4.

Fig. 8.Simulated waveforms of the diode voltage VDo, diode current iDo, and primary current ip for D = 0.4.

 

IV. EXPERIMENTAL RESULTS

A 1.0 kW prototype circuit has been developed to verify the operation principles and performance of the proposed converter. Table I shows the electrical specification of the proposed converter. Table ІІ shows the parameters of the power circuit components.

TABLE IELECTRICAL SPECIFICATION OF THE PROPOSED CONVERTER

TABLE IIPARAMETERS OF THE POWER CIRCUIT COMPONENTS

Fig. 9 shows the experimental results of the proposed converter for an open-loop test. When D is 0.4, Vo is 200 V for Vin = 350 V. Fig. 9(a) shows the switch voltages VS1 and VS2 and switch currents iS1 and iS2 for a 1.0 kW output power. Fig. 9(b) shows the switch voltages VS3 and VS4 and switch currents iS3 and iS4 for a 1.0 kW output power. ZVS of power switches is achieved, which reduces the switching losses at the primary side. Fig. 10 shows the experimental results of the proposed converter for an open-loop test. When D is 0.6, Vo is 450 V for Vin = 350 V. Fig. 10(a) shows the switch voltages VS1 and VS2 and switch currents iS1 and iS2 for a 1.0 kW output power. Fig. 10(b) shows the switch voltages VS3 and VS4 and switch currents iS3 and iS4 for a 1.0 kW output power. The proposed converter can operate when the duty cycle is over 0.5. Fig. 11 shows the experimental waveforms of the diode voltage VDo, diode current iDo, and primary current ip when Vo is 200 V with D = 0.4 for a 1.0 kW output power. The resonant frequency fr is around fr = 60 kHz, which is above the switching frequency fr = 50 kHz. ZCS of output diode is also achieved, which reduces the switching power losses at the secondary side. Fig. 12 shows the experimental waveforms of the proposed converter for a closed-loop test. This figure also shows the output voltage Vo and output current io when the output power is changed abruptly. The output voltage Vo is regulated when the output power changes from 0.5 kW to 1.0 kW. Fig. 13 shows the measured power efficiency curves of the different power levels. The conventional two-switch flyback converter achieves the efficiency of 93.0 % for a 1.0 kW output power. On the contrary, the proposed converter realizes the efficiency of 94.5 % for a 1.0 kW output power. The proposed converter improves the converter efficiency by 1.5 %. The main factor for the efficiency improvement is the reduced switching losses. Given that the proposed converter is developed for high input voltage applications, the switching losses are more dominant than the conduction losses. The input voltage of the proposed converter is 350 V. For such a high input voltage, the switching losses are more significant than the conduction losses. This significance is because the average current of the switching devices is reduced as the input voltage of the converter is increased. The duty cycle range is also extended from 0 to 1 for the practical use of the proposed converter for a wide input voltage range.

Fig. 9.Experimental results for D = 0.4: (a) switch voltages VS1 and VS2 and switch currents iS1 and iS2 and (b) switch voltages VS3 and VS4 and switch currents iS3 and iS4.

Fig. 10.Experimental results for D = 0.6: (a) switch voltages VS1 and VS2 and switch currents iS1 and iS2 and (b) switch voltages VS3 and VS4 and switch currents iS3 and iS4.

Fig. 11.Experimental waveforms of the diode voltage VDo, diode current iDo, and primary current ip for D = 0.4.

Fig. 12.Experimental waveforms of the output voltage Vo and output current io when the output power is changed abruptly.

Fig. 13.Measured power efficiency curves of the different power levels.

 

V. CONCLUSION

This paper has proposed an actively clamped two-switch flyback converter. Operation principle and converter features of the proposed converter are described. The duty cycle range is extended by using an active-clamp circuit. ZVS of all power switches is achieved. ZCS of an output diode is also achieved. The proposed converter reduces switching power losses with an extended duty cycle range. Simulation verifications and experimental results are presented to verify the performance of the proposed converter. The proposed converter realizes the efficiency of 94.5 % for a 1.0 kW output power. This converter improves power efficiency by 1.5 % for a 1.0 kW output power compared with the conventional converter. The proposed converter is suitable for a high-efficiency isolated power supplies for a wide input voltage range.

References

  1. B. R. Lin, H. K. Chiang, and S. L. Wang, “Interleaved ZVS DC/DC converter with balanced input capacitor voltages for high-voltage applications,” Journal of Power Electronics, Vol. 14, No. 4, pp. 661-670, Jul. 2014. https://doi.org/10.6113/JPE.2014.14.4.661
  2. Z. Chen, Q. Zhou, J. Xu, and X. Zhou, “Asymmetrical pulse-width-modulated full-bridge secondary dual resonance DC-DC converter,” Journal of Power Electronics, Vol. 14, No. 6 pp. 1224-1232, Nov. 2014. https://doi.org/10.6113/JPE.2014.14.6.1224
  3. J. Zhang, S. Wang, Z. Wang, and L. Tian, “Design and realization of a digital PV simulator with a push-pull forward circuit,” Journal of Power Electronics, Vol. 14, No. 3. pp. 444-457, May 2014. https://doi.org/10.6113/JPE.2014.14.3.444
  4. B. R. Lin, and Y. B. Nian, “Analysis and implementation of a new three-level converter,” Journal of Power Electronics, Vol. 14, No. 3. pp. 478-487, May 2014. https://doi.org/10.6113/JPE.2014.14.3.478
  5. D. K. Jeong, M. H. Ryu, H. G. Kim, and H. J. Kim, “Optimized design of bi-directional dual active bridge converter for low-voltage battery charter,” Journal of Power Electronics, Vol. 14, No. 3. pp. 468-477, May 2014. https://doi.org/10.6113/JPE.2014.14.3.468
  6. M. Baei, M. Narimani, and G. Moschopoulos, “A new ZVS-PWM full-bridge boost converter,” Journal of Power Electronics, Vol. 14, No. 2. pp. 237-248, Mar. 2014. https://doi.org/10.6113/JPE.2014.14.2.237
  7. C. H. Park, S. H. Cho, J. H. Jang, S. K. Pidaparthy, and T. Y. Ahn, “Average current mode control for LLC series resonant DC-to-DC converters,” Journal of Power Electronics, Vol. 14, No. 1. pp. 40-47, Jan. 2014. https://doi.org/10.6113/JPE.2014.14.1.40
  8. B. R. Lin, “Analysis, design and implementation of a soft switching DC/DC converter,” Journal of Power Electronics, Vol. 13, No. 1. pp. 20-30, Jan. 2013. https://doi.org/10.6113/JPE.2013.13.1.20
  9. W. Hu, F. Zhang, Y. Xu, and X. Chen, “Output voltage ripple analysis and design considerations of intrinsic safety flyback converter based on energy transmission modes,” Journal of Power Electronics, Vol. 14, No. 5. pp. 908-917, Sep. 2014. https://doi.org/10.6113/JPE.2014.14.5.908
  10. D. H. Kim, and J. H. Park, “High efficiency step-down flyback converter using coaxial cable coupled-inductor,” Journal of Power Electronics, Vol. 13, No. 2. pp. 214-222, Mar. 2013. https://doi.org/10.6113/JPE.2013.13.2.214
  11. J. K. Kim and G. W. Moon, “Derivation, analysis, comparison of nonisolated single-switch high step-up converters with low voltage stress,” IEEE Trans. Power Electron., Vol. 30, No. 3, pp. 1336-1344, Mar. 2015. https://doi.org/10.1109/TPEL.2014.2316324
  12. Q. Vartak, A. Abramovitz, and K. M. Smedley, “Analysis and design of energy regenerative snubber for transformer isolated converters,” IEEE Trans. Power Electron., Vol. 29, No. 11, pp. 6030-6040, Nov. 2014. https://doi.org/10.1109/TPEL.2014.2301194
  13. M. G. Kim and Y. S. Jung, “A novel soft-switching two-switch flyback converter with a wide operating range and regenerative clamping,” Journal of Power Electronics, Vol. 9, No. 5, pp. 772-780, Sep. 2009.
  14. M. R. Yazdani and S. Rahmani, “A new zerocurrent- transition two-switch flyback converter,” in Proc. PEDSTC, pp. 390-395, 2014
  15. D. Murthy-Bellur and M. K. Kazimierczuk, “Zerocurrent- transition two-switch flyback pulse-width modulated DC-DC converter,” IET Power Electron., Vol. 4, No. 3, pp. 288-295, Mar. 2011. https://doi.org/10.1049/iet-pel.2009.0253
  16. C. Y. inaba, Y. Konishi, and M. Nakaoka, “Highfrequency flyback-type soft-switching PWM DC-DC power converter with energy recovery transformer and auxiliary passive lossless snubbers,” IET Electric Power Applications, Vol. 151, No. 1, pp. 32-37, Jan. 2004. https://doi.org/10.1049/ip-epa:20031060
  17. J. Zhao and F. Dai, “Soft-switching two-switch flyback converter with wide range,” in Proc. ICIEA, pp. 250-254, 2008.

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