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UCI PEL UCI Power Electronics Lab Control of A Dual-Boost Power Factor Corrector for High Power Applications Yaoping Liu and Keyue Smedley University of California, Irvine, CA 92697 Shenzhen WATT Electronics Co., LTD. 10/11/03~15/11/03 UCI PEL UCI Power Electronics Lab outlines Dual boost converter for high power PFC application PFC control method review Proposed PFC control method for the converter (One cycle control method for PFC application) Stability analysis for the control method Experimental results Conclusions UCI PEL UCI Power Electronics Lab Popular configuration for practical power supply productions Vac uninsulated VRM PFC DC/DC PFC is necessary and very important for most of ac/dc power supply, and boost converter is used for single phase PFC: SIP LOAD insulated DC/DC Advantages: •Simpler circuit configuration; •adaptability to wide range input voltage; •higher efficiency; •relatively lower component stress. But for higher power level application, the boost converter has some limitations UCI PEL UCI Power Electronics Lab Dual boost converter for high level power PFC application When the converter operates under CCM, the conversion ratio is: M (d ) Vo 1 Vg 1 d Traditional control method: •voltage follower approach; large current stress, significant residual current harmonics •Multiplier approach circuit complex; additional current distortion due to the nonlinearity of the multiplier high cost inconvenience of sensing the input voltage and the input current UCI PEL UCI Power Electronics Lab The approach of PFC using PWM modulator Control goal: Vg = Re • ig Where Re is equivalent input resistor of DC/DC converter UCI PEL UCI Power Electronics Lab CONSTRACTION: • A constant frequency clock generator • A flip flop • An integrator with reset switch • A comparator occ core •The time coefficient of the integrator is selected to equal the switching period Ts; •V2 can be considered as constant during one cycle period; •For time t from the beginning of a cycle to the moment when v+ = v1, the duty ratio of Q is d. v2 t Ts v v1 When d represents duty ratio for Q high and take Q as driver signal then: t dTs v1 (1 d )v 2 v 0 t Ts v1 v2 d UCI PEL UCI Power Electronics Lab The approach of PFC for the dual boost converter using OCC core V1= V2d Vm – Rs * ig = Vm* d Vm = RsVo/Re So control goal Vg = Re * ig is realized So control goal V1 = V2 (1 – d) Rs* ig = Vm (1 – d) Vg = Re * ig is realized UCI PEL UCI Power Electronics Lab The stability analysis for the control method 1. The Stability Of The Trailing Edge Modulation. Vm Rs i Lin Vm d i.e. i Lin Vm V m dTs Rs Rs Ts Define: mc m1 Then, m2 Vm R s Ts m m2 m2 c d m1 m c m1 mc mc m 2 m1 mc if d* m2 m1 m2 d n d * (1 n ) n d 0 1 Vg Lin Vo V g Lin mc d nTs m2 (1 d n )Ts (m1 m c )d n 1Ts d n 1 f (d ) The duty ratio converges, so the stability condition is: d m m2 m2 c dn m1 m c m1 mc 2. The stability condition for leading edge modulation d 1 Lin f s 2 Re 1 Lin f s 2 Re UCI PEL UCI Power Electronics Lab Experimental verification UCI PEL UCI Power Electronics Lab Conclusion • A single-phase dual boost PFC rectifier using general constant frequency PWM control method is presented, And the converter can handle high power with a simple configuration; • The multiplier and the sensor for input voltage are not needed; • The control method is very simple and reliable which achieves low total harmonic distortion and high a power factor at low cost; • Analyses for the topology and control method are provided, and experiment verification is provided.