力、电、热作用下晶内微裂纹的演化

THE EVOLUTION OF INTRAGRANULAR MICROCRACKS INDUCED BY STRESS-, ELECTRO- AND THERMO-MIGRATIONS

  • 摘要: 基于表面扩散的经典理论及其弱解描述,对曲率、力、电和热共同作用下金属材料内部晶内微裂纹的演化进行了有限元分析。详细讨论了微裂纹初始形态、电场大小、应力大小和电致生热对微裂纹演化的影响。结果表明:对于形态比为的微裂纹,存在一临界电场值和临界应力值。当且时,微裂纹逐渐圆柱化;当或时,微裂纹分节为上、下或左、右两个小裂纹。热应力可减小的值,即有利于微裂纹分节。同时热应力可加快微裂纹的漂移速度,缩短分节时间。

     

    Abstract: Based on the classical theory of surface diffusion and its weak statement,a finite element analysis is conducted for the evolution of intragranular microcracks in metal materials due to the curvature,stress field,electric field and thermal gradient. The effects of the aspect ratio,the magnitude of the stress,the electric field and the thermal stress field induced by the electric current on the evolution are investigated in detail. The results show that the evolution of microcracks depends on the competition of surface energy,strain energy and electric energy. There exists a critical value of electric filed and stress filed for a given aspect ratio . When and,the microcrack will evolve into a cylinder directly. When or,the microcrack will be divided into two right-and-left or lower-and-upper microcracks. The thermal stress caused by the electric current could decrease the value of,which is conducive to the microcrack splitting. Besides,thermal stress can increase the drift speed and decrease the splitting time of the microcrack

     

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