THE BOUNDARY INTEGRAL-VARIATIONAL THEOREMS OF AN ARBITRARY ELEMENT IN THE SOLID—COMPUTE THE ENERGY RELEASE RATE OF AN ARBITRARY CRACK EXTENSION

Applied Mathematics and Mechanics (English Edition) ›› 1984, Vol. 5 ›› Issue (1): 1071-1082.

THE BOUNDARY INTEGRAL-VARIATIONAL THEOREMS OF AN ARBITRARY ELEMENT IN THE SOLID—COMPUTE THE ENERGY RELEASE RATE OF AN ARBITRARY CRACK EXTENSION

牛庠均

Beijing Polytechnic University

收稿日期:1982-04-26 出版日期:1984-01-18 发布日期:1984-01-18

THE BOUNDARY INTEGRAL-VARIATIONAL THEOREMS OF AN ARBITRARY ELEMENT IN THE SOLID—COMPUTE THE ENERGY RELEASE RATE OF AN ARBITRARY CRACK EXTENSION

Niu Xiang-jun

Beijing Polytechnic University

Received:1982-04-26 Online:1984-01-18 Published:1984-01-18

摘要/Abstract

摘要： Based on the solid mechanics of the discrete form and its variational principles proposed by Niu^[1-2], this paper puts forward four kinds of boundary integral-variational theorems of an arbitrary element. In the course of the fracture analysis, they can be used to compute the energy release rate along the normal direction of the crack boundary. When there is a hole in the solid, and whether there are given surface forces on the hole boundary or not they can be used to compute the variation of the energy along the normal direction of the hole boundary. In the course of the discrete analysis, they can be used to establish the discrete equations, so that the values of the unknown functions are solved. At the same time, from this paper we know that the J -integral proposed by Rice^[3] represents an integral to be independent of a path imperfectly.

关键词: two-phase mixture, near-wall flow, mist boundary layer, droplet evaporation, heat transfer, accumulation effect

Abstract: Based on the solid mechanics of the discrete form and its variational principles proposed by Niu^[1-2], this paper puts forward four kinds of boundary integral-variational theorems of an arbitrary element. In the course of the fracture analysis, they can be used to compute the energy release rate along the normal direction of the crack boundary. When there is a hole in the solid, and whether there are given surface forces on the hole boundary or not they can be used to compute the variation of the energy along the normal direction of the hole boundary. In the course of the discrete analysis, they can be used to establish the discrete equations, so that the values of the unknown functions are solved. At the same time, from this paper we know that the J -integral proposed by Rice^[3] represents an integral to be independent of a path imperfectly.

Key words: two-phase mixture, near-wall flow, mist boundary layer, droplet evaporation, heat transfer, accumulation effect

牛庠均. THE BOUNDARY INTEGRAL-VARIATIONAL THEOREMS OF AN ARBITRARY ELEMENT IN THE SOLID—COMPUTE THE ENERGY RELEASE RATE OF AN ARBITRARY CRACK EXTENSION[J]. Applied Mathematics and Mechanics (English Edition), 1984, 5(1): 1071-1082.

Niu Xiang-jun. THE BOUNDARY INTEGRAL-VARIATIONAL THEOREMS OF AN ARBITRARY ELEMENT IN THE SOLID—COMPUTE THE ENERGY RELEASE RATE OF AN ARBITRARY CRACK EXTENSION[J]. Applied Mathematics and Mechanics (English Edition), 1984, 5(1): 1071-1082.

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THE BOUNDARY INTEGRAL-VARIATIONAL THEOREMS OF AN ARBITRARY ELEMENT IN THE SOLID—COMPUTE THE ENERGY RELEASE RATE OF AN ARBITRARY CRACK EXTENSION

THE BOUNDARY INTEGRAL-VARIATIONAL THEOREMS OF AN ARBITRARY ELEMENT IN THE SOLID—COMPUTE THE ENERGY RELEASE RATE OF AN ARBITRARY CRACK EXTENSION

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