Characterization of Insulation Aging with Power- Dense Environments

2018 IEEE Electrical Insulation Conference (EIC) Pub Date : 2018-06-01 DOI:10.1109/EIC.2018.8481092

A. Wilder

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引用次数: 2

Abstract

As machine environments become more power-dense, understanding the aging of insulation is critical for successful machine design and performance. It is well-known that electrical aging under stress can be monitored over time using partial discharge and breakdown strength. There are also tests that indicate comparative “condition”, such as polarization index and dielectric discharge. These characterizations give little information as to the nature of the aging, necessary for specifying new or improved materials. Such information would also be useful in machine design decisions. A survey of materials characterization tools was made to assess the nature of aging under mechanical, thermal, and electrical stresses. The use of three tools is recommended for characterization of the nature of aging in electrical insulation materials: Dielectric Thermal Analysis (DETA), Dynamic Mechanical Analysis for extension (DMA-Extension), and Dynamic Mechanical Analysis for shear (DMA-Shear). With these tools, significant differences are found between the aging behaviors of materials (e.g., between unfilled epoxy and silicone thermoset polymers).

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功率密集环境下绝缘老化特性研究

随着机器环境变得越来越功率密集，了解绝缘老化对于成功的机器设计和性能至关重要。众所周知，可以使用局部放电和击穿强度来监测应力下的电老化。还有指示比较“状况”的测试，如极化指数和介电放电。这些表征对老化的性质提供的信息很少，而这是指定新材料或改进材料所必需的。这些信息在机器设计决策中也很有用。对材料表征工具进行了调查，以评估机械，热和电应力下的老化性质。推荐使用三种工具来表征电绝缘材料的老化性质:介电热分析(DETA)、动态力学分析(DMA-Extension)和动态力学分析(DMA-Shear)。使用这些工具，可以发现材料老化行为之间的显著差异(例如，未填充的环氧树脂和硅树脂热固性聚合物之间)。

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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2018 IEEE Electrical Insulation Conference (EIC)

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