针对高精度、小量程的电流相关测量方法有限这一难题,根据有源阻抗的矢量电压合成消除互感器测量误差的方法设计一种精密工频电流-电压比例变换器。该变换器采用3只感应式比例单元实现范围较大的电流比例变换;采用双级电流互感器解决励...针对高精度、小量程的电流相关测量方法有限这一难题,根据有源阻抗的矢量电压合成消除互感器测量误差的方法设计一种精密工频电流-电压比例变换器。该变换器采用3只感应式比例单元实现范围较大的电流比例变换;采用双级电流互感器解决励磁电流引起的误差,减小电流的测试误差;其校准方法采用基于双通道电压比较仪和有源阻抗变换技术的溯源提高测试精度。通过实验证明该变换器能够实现10-6量级的电流-电压比例变换,其校准方法误差优于2×10-6,可测量最小2 m A的电流。展开更多
The application areas of conventional push pull converters are limited because of high voltage stress of switches (twice of input voltage). This paper presents a novel zero voltage and zero current switching (ZCS)...The application areas of conventional push pull converters are limited because of high voltage stress of switches (twice of input voltage). This paper presents a novel zero voltage and zero current switching (ZCS) PWM push pull three level converter in which the voltage stress of switches is input voltage. With phase shifted modulation strategy, the leading switches can only realize zero voltage switching (ZVS), and the lagging switches can realize ZCS when block capacitor and block diodes are added. Using the strategy, the converter overcomes the drawbacks presented by the conventional push pull converter, such as magnetic aberration, large switch loss, and voltage spike on switches, so it can get higher efficiency, and a wider application area. The operating principle of the new converter is analyzed and verified on a 600 W, 50 kHz experimental prototype. Several zero voltage and zero current switching PWM push pull three level converters are proposed.展开更多
This paper proposes a zer o current and zero voltage switching (ZCZVS) PWM Boost full bridge (FB) conve rter. With series inductors, the leading switches can realize zero current swit ching (ZCS) in a wide load ra...This paper proposes a zer o current and zero voltage switching (ZCZVS) PWM Boost full bridge (FB) conve rter. With series inductors, the leading switches can realize zero current swit ching (ZCS) in a wide load range using the energy of the output capacitor. Ma king use of parasitic capacitors of the lagging switches and parallel auxiliary i nductance with the primary winding of the transformer, the lagging switches can realize zero voltage switching (ZVS) under any load. Compared with the ZCS PWM Boost FB converter, the new converter has no current duty cycle loss. Operat ional principle and parameter design are analyzed. Experimental results verify the effectiveness of the proposed converter.展开更多
文摘针对高精度、小量程的电流相关测量方法有限这一难题,根据有源阻抗的矢量电压合成消除互感器测量误差的方法设计一种精密工频电流-电压比例变换器。该变换器采用3只感应式比例单元实现范围较大的电流比例变换;采用双级电流互感器解决励磁电流引起的误差,减小电流的测试误差;其校准方法采用基于双通道电压比较仪和有源阻抗变换技术的溯源提高测试精度。通过实验证明该变换器能够实现10-6量级的电流-电压比例变换,其校准方法误差优于2×10-6,可测量最小2 m A的电流。
文摘The application areas of conventional push pull converters are limited because of high voltage stress of switches (twice of input voltage). This paper presents a novel zero voltage and zero current switching (ZCS) PWM push pull three level converter in which the voltage stress of switches is input voltage. With phase shifted modulation strategy, the leading switches can only realize zero voltage switching (ZVS), and the lagging switches can realize ZCS when block capacitor and block diodes are added. Using the strategy, the converter overcomes the drawbacks presented by the conventional push pull converter, such as magnetic aberration, large switch loss, and voltage spike on switches, so it can get higher efficiency, and a wider application area. The operating principle of the new converter is analyzed and verified on a 600 W, 50 kHz experimental prototype. Several zero voltage and zero current switching PWM push pull three level converters are proposed.
文摘This paper proposes a zer o current and zero voltage switching (ZCZVS) PWM Boost full bridge (FB) conve rter. With series inductors, the leading switches can realize zero current swit ching (ZCS) in a wide load range using the energy of the output capacitor. Ma king use of parasitic capacitors of the lagging switches and parallel auxiliary i nductance with the primary winding of the transformer, the lagging switches can realize zero voltage switching (ZVS) under any load. Compared with the ZCS PWM Boost FB converter, the new converter has no current duty cycle loss. Operat ional principle and parameter design are analyzed. Experimental results verify the effectiveness of the proposed converter.
