30kv短空猝发电容充电电源的设计

M. Giesselmanns, E. Kristiansen
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引用次数: 1

摘要

本文介绍了一种用于在约40 ms内将6.66 /spl mu/F电容器充电至30 kV的电源。电源应该能够在几分钟的时间范围内给电容器充电几次。主电源将是一个500伏直流电源,最终可以由热电池提供。电源的主要部件是h桥结构的大功率逆变器和升压变压器。h桥的开关是高功率隔离栅双极晶体管(igbt)。电路的控制是通过脉冲宽度调制(PWM)控制igbt来实现的。一个微控制器被用来产生所需的PWM信号。微控制器的使用提供了广泛的控制灵活性,并将允许适应初级直流电源的特性。为了使变压器体积最小,同时限制igbt的开关损耗,选择10 kHz的开关频率。电路仿真表明,约38ms后可达到30kv。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Design of a 30 kV power supply for capacitor charging using short duty burst mode
This paper describes a power supply designed for charging a 6.66 /spl mu/F capacitor to 30 kV in approximately 40 ms. The power supply should be capable of recharging the capacitor several times within a time frame of a few minutes. The primary supply would be a 500 VDC source, which could ultimately be supplied by a thermal battery. The major components of the power supply are a high-power inverter in H-bridge configuration followed by a step-up transformer. The switches for the H-bridge are high power isolated gate bipolar transistors (IGBTs). Control of the circuit is achieved by controlling the IGBTs by pulse width modulation (PWM). A microcontroller is being used to generate the required PWM signals. Use of the microcontroller provides a wide range of control flexibility and will allow for adaptation to the characteristics of the primary DC source. In order to minimize the volume of the transformer and at the same time limit the switching losses in the IGBTs, a switching frequency of 10 kHz was chosen. Circuit simulations show that 30 kV is reached after about 38 ms.
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