Design of Robust Dual Boost Converter Power Factor Correction Circuits

Zai, Zong-ru

18 October 2010

The traditional AC/DC rectifier usually has the defects of low power factor and serious harmonic distortion and it results in serious pollution to the power system. This thesis proposes active power factor correction technique using a new AC/DC Dual Boost Converter. For power factor correction, inductor current is operated in the continuous conduction mode. First, the converter is analyzed by state space averaging method. Furthermore, we design applicable compensator by frequency analysis to implement a good power factor system. A classical PFC circuit with PI control law has low power factor under light load. In order to overcome problem, the thesis proposes a Dual Boost Converter circuit with robust performance. Comparing with circuits using PFC IC ¡§UC3854¡¨, the proposed system obtains higher power factor under the condition of the same light load.

Dual Boost

power factor correction

robust

Análise comparativa de conversores monofásicos aplicados a correção de fator de potência

Beltrame, Fernando

12 August 2009

This work presents a study and a comparative analysis of high power single-phase converter applied to power factor correctioii in according to the international standards IEC 61000-3-4 (harmonics limitation) and CISPR 22 (electromagnetic interference limitation) for high power applications. The converters studied were the conventional boost converter, the interleaved boost converter, with two cell operating with a delay angle of 180" between each other, and the dual boost converter. Such converters are used in front-end modules of information technology equipment. AI1 converters have the same input and output voltage and the same input current. The converters were projected to provide the same total input harmonic distortion (THD), with the idea of using the same input filter. Implementation of the control laws was performed through a digital control with the use of a 16 bits microcontroller. A11 converters were, first of all, studied and presented in this dissertation. The analyzed parameters for comparison were: power factor, total harmonic distortion (THD), semiconductor losses and magnetic losses, heat-sinks volume and magnetics volume, conducted electromagnetic interference, performance and costs. / Esse trabalho apresenta um estudo e uma análise comparativa de conversores monofásicos aplicados i correção de fator de potência que estejam de acordo com as normas internacionais IEC 61000-3-4 (limitação de harmônicos) e CISPR 22 (limitação dos níveis de interferência eletromagnética) para aplicações de alta potência. Os conversores estudados foram os conversores Boost, o conversor Boost Intercalado, com duas células operando com uma defasagem de 180" entre si, e o conversor Dual Boost. Tais conversores são utilizados como estágio de entrada em fontes de equipamentos da tecnologia da informação. Todos os conversores apresentam a mesma tensão de entrada e saída, e a mesma corrente de entrada. Os conversores foram projetados para apresentarem a mesma taxa de distorção harmônica da corrente de entrada (THD) para que, dessa forma, todos tenham o mesmo filtro de entrada. A implementação das leis de controle foi realizada através de um controlador digital com o uso de um microcontrolador de 16 bits. Todos os conversores foram primeiramente estudados e são apresentados nesta dissertação. Os parâmetros analisados para a comparação das topologias foram: fator de potência, taxa de distorção harmônica, perdas nos dispositivos semicondutores e magnéticos, volume dos dissipadores e materiais magnéticos, interferência eletromagnética conduzida, eficiência e custos.

Boost

Boost intercalado

Dual boost

Correção do fator de potência

Boost

Interleaved boost

Dual boost

Power factor correction

CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA

Investigation of High Performance AC/DC Front-End Converter with Digital Control for Server Applications

luo, zheng

03 March 2009

With the development of information technology, the market for power management of telecom and computing equipment keeps increasing. Distributed power systems are widely adopted in the telecom and computing applications for the reason of high performance and high reliability. Recently industry brought out aggressively high efficiency requirements for a wide load range for power management in telecom and computing equipment. High efficiency over a wide load range is now a requirement. On the other hand, power density is still a big challenge for front-end AC/DC converters. For DPS systems, front-end AC/DC converters are under the pressure of continuous increasing power density requirement. Although increasing switching frequency can dramatically reduce the passive component size, its effectiveness is limited by the converter efficiency and thermal management. Technologies to further increase the power density without compromising the efficiency need to be studied. The industry today is also at the beginning of transferring their design from analog control to full digital control strategy. Although issues are still exist, reducing components count, reducing the development cycle time, increasing the reliability, enhancing the circuit noise immunity and reducing the cost, all of these benefits indicate a great potential of the digital control. This thesis is focusing on how to improve the efficiency and power density by taking the advantages of the digital control. A novel Ï /2 phase shift two Channel interleaving PFC is developed to shrink the EMI filter size while maintain a good efficiency. A sophisticated power management strategy that associates with phase shedding and adaptive phase angle control is also discussed to increase the efficient for the entire load range without compromising the EMI filter size. The method of current sampling is proposed for Ï /2 phase shift two Channel interleaving PFC and multi-channel adaptive phase angle shift PFC is proposed to accurately extract the average total current information. A noise free current sampling strategy is also proposed that adjusting the sampling edge according to duty cycle information. An isolated ZVS dual boost converter is proposed to be the DC/DC stage of the front-end converter. This PWM converter has similar performance as the LLC resonant converter. It has hold up time extension capability without compromising the normal operation efficiency. It can achieve ZVS for all the switches. The current limit and SR implementation is much easier than LLC. State plane method, which potentially can be extent to other complex topologies, is used to fully study this circuit. All the operation modes are understood through the state plane method. The best operation mode is discovered for the front end applications. Light load efficiency is improved by the proposed pulse skipping method to guarantee the ZVS operation meanwhile reduce the switching frequency. Current limit operation is also proposed to restrict a best operation mode by fully taking the advantage of digital control that precisely control the circuit under the over current condition. High efficiency high power density is achieved by new topology, innovative interleaving, and the sophisticated digital control method. / Master of Science

DC/DC

AC/DC

High efficiency

High power density

Digital control

Front-end converter

Current limit

Light load

ZVS isolated dual boost

PFC

90 degree Interleaving