改进了柔性首柱的计算方法,考虑了截面上的应力

V. Chepurnenko, K. Hashhozhev, S. Yazyev, A. Avakov
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引用次数: 2

摘要

本文致力于一种新开发的复杂有限元,该有限元允许对钢管混凝土柱进行建模,同时考虑钢管混凝土核心的压缩以及几何非线性。求解方程的推导,以及刚度矩阵元素的表达式,是基于平面截面的假设。利用MATLAB语言编写的程序代码和ANSYS软件进行了复杂的有限元测试,并与现代软件系统中经典的cfst柱建模方法进行了对比分析。在现有的设计复体中,使用SOLID单元对每个节点具有3个自由度的混凝土核心进行建模,使用SHELL单元对每个节点具有6个自由度的钢管进行建模,与此相比,FEM方程系统的顺序显著降低,在确定应力-应变状态方面具有相当的精度。本文假设钢和混凝土的行为是线性弹性的,然而,所描述的计算方法可以推广到使用材料的非线性变形模型的情况。
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IMPROVING THE CALCULATION OF FLEXIBLE CFST-COLUMNS, TAKING INTO ACCOUNT STRESSES IN THE SECTION PLANES
the article is devoted to a newly developed complex finite element that allows modeling concrete-filled steel tubular columns taking into account the compression of the concrete core from the steel tube, as well as ge-ometric nonlinearity. The derivation of the resolving equations, as well as expressions for the elements of the stiffness matrix, is based on the hypothesis of plane sections. The complex testing of the finite element was performed using the program code written by the authors in the MATLAB language and the ANSYS software, as well as the analysis of the effectiveness of the new FE in comparison with the classical methods of modeling CFST-columns in modern software systems. A significant decrease in the order of the system of FEM equations is demonstrated in comparison with the modeling of CFST-structures in a volumetric formu-lation in existing design complexes using SOLID elements for a concrete core with 3 degrees of freedom in each of the nodes, and SHELL elements for a steel tube with 6 degrees of freedom in each of the nodes, with a comparable accuracy in determining the stress-strain state. The behavior of steel and concrete in the presented work is assumed to be linearly elastic, however, the described calculation method can be generalized to the case of using nonlinear deformation models of materials.
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CiteScore
1.40
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