Design of an automated test bed for experimental Si and SiC SGTO devices

2012 IEEE International Power Modulator and High Voltage Conference (IPMHVC) Pub Date : 2012-06-03 DOI:10.1109/IPMHVC.2012.6518751

K. Lawson, S. Lacouture, S. Bayne, M. Giesselmann, T. Vollmer, H. O’Brien, C. Scozzie, A. Ogunniyi

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引用次数: 1

Abstract

In a collaborative effort between Army Research Lab (ARL) and Texas Tech University's center for Pulsed Power and Power Electronics (P3E) lab, a high power, high energy test bed meant to characterize experimental Si and SiC Super Gate Turn Off (SGTO) devices was designed and built. The system was engineered to run the devices through an arbitrary number of test cycles while recording all pertinent data automatically. Test parameters are set through a windows GUI which communicates with a microprocessor - based control system that orchestrates timing and settings of each subsystem as well as acquiring voltage and current waveforms with high speed ADCs operating simultaneously in parallel. The test waveform itself is generated by a Pulse Forming Network (PFN) which accurately controls rise time, fall time and pulse width. The PFN is charged by a Rapid Capacitor Charger (RCC) system designed at the P3E lab that is capable of 10 kW and allows precise charge voltage levels to be set. Waveforms are acquired through isolated probes specifically designed to capture desired signals even in the presence of a large bias voltages.

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实验用Si和SiC SGTO器件自动化试验台的设计

在陆军研究实验室(ARL)和德克萨斯理工大学脉冲功率和电力电子中心(P3E)实验室的共同努力下，设计和建造了一个高功率、高能量的试验台，旨在表征实验硅和SiC超级栅关断(SGTO)设备。该系统被设计为在自动记录所有相关数据的同时，通过任意数量的测试周期运行设备。测试参数通过windows GUI设置，该GUI与基于微处理器的控制系统通信，该控制系统协调每个子系统的时序和设置，并通过高速adc并行同时工作获取电压和电流波形。测试波形本身由脉冲形成网络(PFN)产生，该网络精确控制上升时间、下降时间和脉冲宽度。PFN由P3E实验室设计的快速电容器充电器(RCC)系统充电，该系统能够提供10 kW的充电电压，并允许设置精确的充电电压水平。波形通过专门设计的隔离探头获得，即使在存在大偏置电压的情况下也能捕获所需的信号。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2012 IEEE International Power Modulator and High Voltage Conference (IPMHVC)

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