Bending of Plates with Complex Shape Made from Materials that Differently Resist to Tension and Compression

IF 1.1 Q4 ENGINEERING, MECHANICAL
S. Sklepus
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引用次数: 0

Abstract

A new numerical-analytical method for solving physically nonlinear bending problems of thin plates with complex shape made from materials that differently resist to tension and compression is developed. The uninterrupted parameter continuation method is used to formulate and linearize the problem of physically nonlinear bending. For the linearized problem, a functional in the Lagrange form, given on the kinematically possible displacement rates, is constructed. The main unknown problems (displacements, strains, stresses) were found from the solution of the initial problem, which was solved by the Runge-Kutta-Merson method with automatic step selection, by the parameter related to the load. The initial conditions are found from the solution of the problem of linear elastic deformation. The right-hand sides of the differential equations at fixed values of the load parameter corresponding to the Runge-Kutta-Merson scheme are found from the solution of the variational problem for the functional in the Lagrange form. Variational problems are solved using the Ritz method in combination with the R-function method, which allows to submit an approximate solution in the form of a formula – a solution structure that exactly satisfies the boundary conditions and is invariant with respect to the shape of the domain where the approximate solution is sought. The test problem for the nonlinear elastic bending of a square hinged plate is solved. Satisfactory agreement with the three-dimensional solution is obtained. The bending problem of the plate of complex shape with combined fixation conditions is solved. The influence of the geometric shape and fixation conditions on the stress-strain state is studied. It is shown that failure to take into account the different behavior of the material under tensile and compression can lead to significant errors in the calculations of the stress-strain state parameters.
由抗拉和抗压能力不同的材料制成的复杂形状板的弯曲
提出了一种新的求解复杂形状薄板物理非线性弯曲问题的数值解析方法。采用不间断参数延拓法对物理非线性弯曲问题进行了形式化和线性化处理。对于线性化问题,构造了关于运动可能位移率的拉格朗日泛函。通过对初始问题的求解,找到了主要的未知问题(位移、应变、应力),并采用自动步长选择的龙格-库塔-默森方法,通过与载荷相关的参数对初始问题进行求解。从线弹性变形问题的解中得到了初始条件。通过求解拉格朗日形式泛函的变分问题,得到了负载参数定值时对应龙格-库塔-默逊格式的微分方程的右侧。变分问题是用里兹方法和r函数方法相结合来解决的,它允许以公式的形式提交一个近似解——一个完全满足边界条件的解结构,并且对于寻求近似解的域的形状是不变的。解决了方形铰接板非线性弹性弯曲的试验问题。所得结果与三维解吻合较好。解决了复合固定条件下复杂形状板的弯曲问题。研究了几何形状和固定条件对应力-应变状态的影响。结果表明,不考虑材料在拉伸和压缩作用下的不同行为会导致应力-应变状态参数的计算出现较大误差。
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来源期刊
自引率
0.00%
发文量
42
审稿时长
20 weeks
期刊介绍: The Journal of Mechanical Engineering & Sciences "JMES" (ISSN (Print): 2289-4659; e-ISSN: 2231-8380) is an open access peer-review journal (Indexed by Emerging Source Citation Index (ESCI), WOS; SCOPUS Index (Elsevier); EBSCOhost; Index Copernicus; Ulrichsweb, DOAJ, Google Scholar) which publishes original and review articles that advance the understanding of both the fundamentals of engineering science and its application to the solution of challenges and problems in mechanical engineering systems, machines and components. It is particularly concerned with the demonstration of engineering science solutions to specific industrial problems. Original contributions providing insight into the use of analytical, computational modeling, structural mechanics, metal forming, behavior and application of advanced materials, impact mechanics, strain localization and other effects of nonlinearity, fluid mechanics, robotics, tribology, thermodynamics, and materials processing generally from the core of the journal contents are encouraged. Only original, innovative and novel papers will be considered for publication in the JMES. The authors are required to confirm that their paper has not been submitted to any other journal in English or any other language. The JMES welcome contributions from all who wishes to report on new developments and latest findings in mechanical engineering.
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