A new approach to numerical simulation of boundary value problems of the theory of elasticity in stresses and strains

Q3 Engineering
A. Khaldjigitov, Umidjon Djumayozov, Otajon Tilovov
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引用次数: 1

Abstract

The main parameters characterizing the process of deformation of solids are displacements, strain and stress tensors. From the point of view of the strength and reliability of the structure and its elements, researchers and engineers are mainly interested in the distribution of stresses in the objects under study. Unfortunately, all boundary value problems are formulated and solved in solid mechanics mainly with respect to displacements, or an additional stress functions. And the required stresses are calculated from known displacements or stress functions. In this case, the accuracy of stress calculation is strongly affected by the error of numerical differentiation, as well as the approximation order of the boundary conditions. The formulation of boundary value problems directly with respect to stresses or strains allows to increase the accuracy of stress calculation by bypassing the process of numerical differentiation. Therefore, the present work is devoted to the formulation and numerical solution of boundary value problems directly with respect to stresses and strains. Using the well-known Beltrami-Miеchell equation, and considering the equilibrium equation as ah additional boundary condition, a boundary value problem(BVP) is formulated directly with respect to stresses. In a similar way, using the strain compatibility condition, the Beltrami-Mitchell type equations for strains are written. The finite difference equations for two-dimensional BVP are constructed and written in convenient a form for the use of iterative method. A number of problems on the equilibrium of a rectangular plate under the action of various loads applied on opposite sides are numerically solved. The reliability of the results is ensured by comparing the numerical results of the 2D elasticity problems in stresses and strains, and with the exact solution, as well as with the known solutions of the plate tension problem under parabolic and uniformly distributed loads
应力应变弹性理论边值问题数值模拟的新方法
表征固体变形过程的主要参数是位移、应变和应力张量。从结构及其构件的强度和可靠性的角度来看,研究人员和工程师主要感兴趣的是所研究对象的应力分布。不幸的是,在固体力学中,所有的边值问题主要是根据位移或附加应力函数来表述和解决的。所需的应力由已知的位移或应力函数计算得到。在这种情况下,应力计算的精度受到数值微分误差和边界条件近似顺序的强烈影响。直接关于应力或应变的边值问题的公式可以通过绕过数值微分过程来提高应力计算的准确性。因此,目前的工作是致力于直接与应力和应变有关的边值问题的公式和数值解。利用著名的beltrami - minovelchell方程,将平衡方程作为附加的边界条件,直接建立了关于应力的边值问题。同样地,利用应变相容条件,写出了应变的Beltrami-Mitchell型方程。构造了二维BVP的有限差分方程,并将其写成便于使用迭代法的形式。本文用数值方法解决了矩形板在不同载荷作用下的平衡问题。通过将二维应力应变弹性问题的数值结果与抛物线和均布荷载作用下板张力问题的精确解以及已知解进行比较,保证了计算结果的可靠性
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
EUREKA: Physics and Engineering
EUREKA: Physics and Engineering Engineering-Engineering (all)
CiteScore
1.90
自引率
0.00%
发文量
78
审稿时长
12 weeks
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