The stability of flow-improver additives in transformer oils under oxidation and electrical discharges

Conference on Electrical Insulation & Dielectric Phenomena - Annual Report 1982 Pub Date : 1982-10-01 DOI:10.1109/CEIDP.1982.7726564

M. Duval, S. Lamothe, D. Cauchon, Y. Giguere

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引用次数: 1

Abstract

Transformer oils used in the northern part of the United States and Canada must have low pour-point temperatures in order to maintain good flow characteristics under the sometimes arctic conditions encountered during the winter months. The naphthenic oils presently used meet this requirement, but they are not expected to be available any longer, as the corresponding crude oil bases are now depleted. The paraffinic oils proposed as alternatives by the oil industry have much higher pour points, which must be artificially lowered by incorporating relatively large amounts of pour depressants. The eventual use of paraffinic oils in cold climates therefore relies heavily on the quality of such additives and their stability under actual service conditions. Flow improver additives used in transformer oils are generally large molecules or polymers of the aromatic type, with long paraffinic side chains preventing the formation of crystals in oil on cooling [1]. Their resistance to oxidation, corona discharges and arcing have been examined in the present study.

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变压器油中流动改善剂添加剂在氧化和放电条件下的稳定性

在美国和加拿大北部地区使用的变压器油必须具有较低的凝点温度，以便在冬季遇到的北极条件下保持良好的流动特性。目前使用的环烷油符合这一要求，但由于相应的原油基现已耗尽，预计将不再可用。石蜡油作为石油工业提出的替代品具有更高的倾点，必须通过加入相对大量的倾点抑制剂来人为降低倾点。因此，石蜡油在寒冷气候下的最终使用在很大程度上取决于此类添加剂的质量及其在实际使用条件下的稳定性。变压器油中使用的流动改进剂添加剂一般为大分子或芳香族聚合物，其长石蜡侧链可防止油冷却时结晶体的形成[1]。本研究考察了它们的抗氧化性、电晕放电性和电弧性。

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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Conference on Electrical Insulation & Dielectric Phenomena - Annual Report 1982

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