Dielectric breakdown strength of GFRPs under mechanical stresses in cryogenic liquids

K. Fukushi, M. Nagai, Y. Kamata
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引用次数: 5

Abstract

The dielectric strength of GFRPs (glass-fiber-reinforced plastics) under combined application of electrical and mechanical stresses was investigated in liquid He, liquid N/sub 2/, and silicone oil at room temperature. With the combined application of tensile and electrical stresses in cryogenic liquids, the dielectric breakdown of GFRPs occurred prior to mechanical breakdown when the applied electrical stress was lower than the DBS (dielectric breakdown strength) of GFRPs without tensile stress. In the case of tensile stress application under constantly applied electrical stress, the DBS and GFRPs decreased markedly. The reason for the large DBS decrease of GFRPs was the occurrence of microcracks in matrix resins because of their brittleness at cryogenic temperatures. Combining GFRP with polyimide film in cryogenic liquids lessened the decrease in DBS. Compared with tensile stress application, the influence of compressive stress on the DBS of GFRPs was very small.<>
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低温液体中机械应力作用下gfrp的介电击穿强度
研究了gfrp(玻璃纤维增强塑料)在He液、N/sub /液和硅油中常温下的电、机械复合应力作用下的介电强度。在低温液体中,拉伸应力和电应力共同作用下,当施加的电应力低于无拉伸应力的gfrp的介电击穿强度时,gfrp的介电击穿发生在机械击穿之前。在持续施加电应力和拉伸应力的情况下,DBS和GFRPs显著下降。gfrp的DBS大幅度下降的原因是基体树脂在低温下脆性导致微裂纹的产生。GFRP与聚酰亚胺膜在低温液体中复合可减轻DBS的下降。与施加拉应力相比,压应力对gfrp DBS的影响很小
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