Abstract
To understand the propagation characteristics of water trees at a wide temperature range, this paper presents the effect of mechanical behaviors on the sizes of water trees. An accelerated water tree aging experiment was performed at −15 °C, 0 °C, 20 °C, 40 °C, 60 °C, and 80 °C for crosslinked polyethylene (XLPE) specimens, respectively. Depending on the micro observations of water tree slices, water tree length is not always increasing with the increase in temperature. From 0 °C to 60 °C, water tree length shows a trend from decline to rise. Above 60 °C, water tree length continues to reduce. Dynamic mechanical analysis (DMA) shows that the glass transition temperature of the new XLPE specimen is about −5 °C, and the α-relaxation is significant at about 60 °C. With the increase in temperature, the XLPE material presents different deformation. Meanwhile, according to the result of the yield strength of XLPE at different temperatures, with the increase in temperature, the yield strength decreases from 120 MPa to 75 MPa, which can promote the water tree propagation. According to the early stage in the water tree propagation, a water tree model was constructed with water tree branches like a string of pearls to calculate electric field force. According to the results of electric field force at different expansion conditions, with the increase in temperature, due to expansion of the water tree branches, the electric field force at water tree tips drops, which can suppress the water tree propagation. Regardless of high temperature or low temperature, the water tree propagation is closely related to the mechanical behaviors of the material. With the increase in temperature, the increased deformation will suppress the water tree propagation, whereas the decreased yield strength will promote water tree propagation. For this reason, at different temperatures, the promotion or suppression in water tree propagation is determined by who plays a dominant role.
Highlights
Water trees are regarded as one of the principal aging factors of crosslinked polyethylene (XLPE) cables [1,2,3]
This paper investigated the propagation characteristics of water trees at a wide temperature range and showed that the changing trends of water tree propagation are different at different temperature ranges
Water tree growth can be promoted at some temperature ranges, whereas water tree growth can be suppressed at other temperature ranges
Summary
Water trees are regarded as one of the principal aging factors of crosslinked polyethylene (XLPE) cables [1,2,3]. Cables buried in soil would withstand prolonged temperature gradients during their service life. These temperature variations and electrical stresses can cause breakdown in XLPE cables [4]. The chemical and physical structures of XLPE and other insulation systems of power cables can be altered at varying degrees, which can cause different propagation characteristics of electrical trees and water trees [5,6]. Electrical and thermal aging for polymeric and nanocomposite- based polymeric insulating material [7,8,9,10,11], and the aging mechanism of in-service cables due to water trees and electrical trees at different temperatures, has become a topic of interest in recent years [12,13,14,15].
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