220kv终端悬架母线短路时的动态特性

Transactions of the American Institute of Electrical Engineers. Part III: Power Apparatus and Systems Pub Date : 1962-04-01 DOI:10.1109/AIEEPAS.1962.4501289

A. T. Atwood, M. H. Mills, D. Downs, H. M. Stone

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引用次数: 8

摘要

对全尺寸220kv无端双束导体悬挂母线进行了不同大小和持续时间的短路试验。在这些测试中，可用的传感器和仪器允许测量和记录许多物理变量。最大短路幅度为30000毫安。短路电流会对母线导体、硬件和线塔产生动态作用力。主要的冲击力是由于双导体被短路磁力拉到一起的结果。双导线导线导线的数量和位置对动力峰值的大小有相当大的影响。短路对导体造成的电气和机械损伤可以忽略不计。这种悬架母线的设计被证明是足够的短路负载为1000万千伏安(千伏安)在220千伏，并通过微小的修改，它可能是足够的2000万千伏安在220千伏。

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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Dynamic Behavior of a 220-Kv Dead-End Suspension Bus during Short Circuit

A full-size 220-kv dead-end twin-bundled conductor suspension bus was subjected to short-circuit currents of various magnitudes and durations. Transducers and instruments available allowed the measurement and recording of many physical variables during these tests. Maximum short-circuit magnitude was 30,000 rms amperes. Short-circuit currents cause dynamic forces to be applied to the bus conductors, hardware, and towers. The major shock force is a result of the twin conductors being pulled together between spreaders by the short-circuit magnetic forces. The number and location of twin conductor spreaders have considerable influence on the peak magnitude of the dynamic forces. Electrical and mechanical damage to conductors as a result of a short circuit was negligible. This suspension bus design proved to be adequate for a shortcircuit duty of 10 million kva (kilovoltamperes) at 220 kv, and with minor modifications it may be adequate for 20 million kva at 220 kv.

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来源期刊

Transactions of the American Institute of Electrical Engineers. Part III: Power Apparatus and Systems

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