COMPLEX VARIABLE FUNCTION METHOD FOR HOLE SHAPE OPTIMIZATION IN AN ELASTIC PLANE

Applied Mathematics and Mechanics (English Edition) ›› 1987, Vol. 8 ›› Issue (2): 137-146.

COMPLEX VARIABLE FUNCTION METHOD FOR HOLE SHAPE OPTIMIZATION IN AN ELASTIC PLANE

孙焕纯¹, 张巨勇², 严国梅³, 张积珠³

1. Department of Engineering Mechanics, Dalian Institute of Technology, Dalian;
2. Research Institute of Engineering Mechanics, Hefei Industry University, Hefei;
3. Deparament of Engineering Mechanics, Dalian Institute of Technology, Dalian

收稿日期:1985-10-25 出版日期:1987-02-18 发布日期:1987-02-18

COMPLEX VARIABLE FUNCTION METHOD FOR HOLE SHAPE OPTIMIZATION IN AN ELASTIC PLANE

Sun Huan-chun¹, Zhang Ju-yong², Yan Guo-mei³, Zhang Ji-zhu³

1. Department of Engineering Mechanics, Dalian Institute of Technology, Dalian;
2. Research Institute of Engineering Mechanics, Hefei Industry University, Hefei;
3. Deparament of Engineering Mechanics, Dalian Institute of Technology, Dalian

Received:1985-10-25 Online:1987-02-18 Published:1987-02-18

摘要/Abstract

摘要： In this paper, a complex variable function method for solving the hole, shape optimization problem in an elastic plane is presented. In this method, the stresses in hole problems are analysed by taking advantage of the efficiency of the complex variable Junction method. To optimize the hole shape, the coeffecients in conformal mapping functions are taken as design variables, and the sensitivity analysis and gradient methods are used to reduce the largest circumferential stress in absolute value and at the same time to make the second largest circumferential stress in absolute value not to exceed the largest one (in fact, these two stresses are the stationary values of the circumferential stresses). The coefficients in conformal mapping function are revised by iteration step by step until the largest circumferential stress in absolute value is reduced to the second largest stress. This method guarantees the continuity, differentiability and accuracy of the stress solution along the boundary, and it is evident that this method is better than either the difference method or the finite element method.

关键词: rectangular ferromagnetic plates, magnetoelasticity, bedding andinstability, nonlinearity, numerical simulation

Abstract: In this paper, a complex variable function method for solving the hole, shape optimization problem in an elastic plane is presented. In this method, the stresses in hole problems are analysed by taking advantage of the efficiency of the complex variable Junction method. To optimize the hole shape, the coeffecients in conformal mapping functions are taken as design variables, and the sensitivity analysis and gradient methods are used to reduce the largest circumferential stress in absolute value and at the same time to make the second largest circumferential stress in absolute value not to exceed the largest one (in fact, these two stresses are the stationary values of the circumferential stresses). The coefficients in conformal mapping function are revised by iteration step by step until the largest circumferential stress in absolute value is reduced to the second largest stress. This method guarantees the continuity, differentiability and accuracy of the stress solution along the boundary, and it is evident that this method is better than either the difference method or the finite element method.

Key words: rectangular ferromagnetic plates, magnetoelasticity, bedding andinstability, nonlinearity, numerical simulation

孙焕纯;张巨勇;严国梅;张积珠. COMPLEX VARIABLE FUNCTION METHOD FOR HOLE SHAPE OPTIMIZATION IN AN ELASTIC PLANE[J]. Applied Mathematics and Mechanics (English Edition), 1987, 8(2): 137-146.

Sun Huan-chun;Zhang Ju-yong;Yan Guo-mei;Zhang Ji-zhu. COMPLEX VARIABLE FUNCTION METHOD FOR HOLE SHAPE OPTIMIZATION IN AN ELASTIC PLANE[J]. Applied Mathematics and Mechanics (English Edition), 1987, 8(2): 137-146.

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COMPLEX VARIABLE FUNCTION METHOD FOR HOLE SHAPE OPTIMIZATION IN AN ELASTIC PLANE

COMPLEX VARIABLE FUNCTION METHOD FOR HOLE SHAPE OPTIMIZATION IN AN ELASTIC PLANE

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