Stator winding failures: contamination, surface discharge, tracking

Industry Applications Society 46th Annual Petroleum and Chemical Technical Conference (Cat.No. 99CH37000) Pub Date : 1999-09-13 DOI:10.1109/PCICON.1999.806452

J. Dymond, N. Stranges, K. Younsi

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引用次数: 48

Abstract

Stator winding failures are generally attributed to groundwall or turn insulation failures. The failure mechanism involves the gradual development of a weakness in the insulation. This weakness is usually caused by a trapped void that is continuously enlarging due to ever increasing corona or partial discharge activity. The failure mode is from the inside out. Studies of failures in actual machines, and of coils on voltage endurance testing, indicate that failures can occur from the outside inward. Surface contamination leads to intense surface discharge and tracking. This surface discharge can lead to rapid winding failure following the inward motion of the corona activity. This paper looks at tracking as one failure mechanism and describes a series of tests on standard insulation materials aimed at comparing the anti-tracking capability of the materials. The tests show that combinations of insulation materials can reduce the anti-tracking capacity of a rather robust insulation system and predispose it to failure.

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定子绕组故障:污染，表面放电，跟踪

定子绕组故障通常归因于接地墙或匝绝缘故障。破坏机制涉及绝缘的逐渐发展的弱点。这种弱点通常是由于日冕或局部放电活动不断增加而导致被困的空隙不断扩大造成的。故障模式是由内而外的。对实际机器故障的研究，以及对线圈电压耐久性测试的研究表明，故障可能是从外部向内发生的。表面污染导致强烈的表面排放和跟踪。这种表面放电会导致电晕活动向内运动后绕组迅速失效。本文将跟踪视为一种失效机制，并描述了一系列针对标准绝缘材料的测试，旨在比较材料的抗跟踪能力。试验表明，绝缘材料的组合会降低绝缘系统的抗跟踪能力，使其容易失效。

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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Industry Applications Society 46th Annual Petroleum and Chemical Technical Conference (Cat.No. 99CH37000)

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