材料科学
结晶
复合材料
无定形固体
化学工程
结晶度
聚丙烯
储能
脆性
玻璃化转变
电介质
韧性
电容器
成核
复合数
活化能
脆化
转变温度
介电损耗
聚合物
介电强度
降级(电信)
晶界
作者
Tiandong Zhang,Yumeng Lu,Zhiwu Xiong,Hai Sun,Haixin Ma,Yue Zhang,Changhai Zhang,Qingguo Chi
标识
DOI:10.1021/acsapm.5c03388
摘要
Polypropylene (PP) film capacitors have excellent dielectric properties at room temperature and are widely used in electric power systems. However, the deterioration of the mechanical embrittlement at low temperatures and the electrical insulating degradation at high elevated temperatures limit their high reliability under extreme temperature conditions. In this article, flexible ethylene chain segments were introduced by blending copolymerized polypropylene (PP-B) with homopolymerized propylene (HPP). Lowering its glass transition temperature causes the film to change from brittle to flexible at low temperatures, thus improving its mechanical toughness at low temperatures. Experimental results showed that the glass transition temperatures of HPP and 10 wt % HPP/PP-B were 18.5 and 15.61 °C, respectively, and the elongation at break of the 10 wt % HPP/PP-B film was 45% higher than that of the HPP film. Further, the β-phase nucleating agent was added to the HPP/PP-B composite film, which can induce the β-crystalline phase and refine the grain size. The deep traps at the interface between the amorphous and crystalline regions can effectively inhibit the long-range transport of the carriers. The leakage current density of (PP-WB2) at high temperature was significantly reduced by adding 0.03 wt % of the β-phase nucleating agent, and the discharge energy density of (PP-WB2) film at 85 °C was as high as 4.01 J/cm 3, which is 69% higher than that of HPP. This study is instructive for improving the energy storage performance of PP capacitor films under severe operating conditions.
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