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中文核心期刊

功能梯度材料数据驱动格点型有限体积法

FUNCTIONALLY GRADED MATERIAL DATA DRIVEN CELL-VERTER FINTE VOLUME METHOD

  • 摘要: 复合材料结构力学性能的评估是机械工程领域迫切需要解决的关键问题. 将材料应力应变数据与格点型有限体积法(CV-FVM)相结合形成数据驱动格点型有限体积法, 用于解决复合材料本构建模复杂和成本高昂的难题. 该方法将材料应力应变数据与格点型有限体积法相结合, 利用交错网格技术, 将应力-应变定义在单元内, 位移和拉格朗日乘子定义于节点, 围绕节点构建控制体, 为每个单元分配应力应变数据, 基于格点型有限体积法对每个控制体的几何方程和平衡方程进行离散和求解, 最终通过满足守恒定律的点与材料数据库中的点的距离极值最小化以寻求出问题的最优解. 采用C++语言开发数值求解程序, 通过该程序分析均匀材料带孔方板和功能梯度材料复合拉压板力学性能, 数值计算结果表明: 所提出的方法对三角形网格、双线性四边形单元和混合网格适用性良好; 数据库数据点数量、数据点间距以及常数矩阵取值对计算结果的影响与现有文献中有限单元法的结论吻合; 在保持计算成本相近时, 该方法计算结果的精度与有限单元法格式下的数据驱动算法结果精度接近, 验证了该方法的有效性; 最后通过功能梯度板的数值模拟计算, 展示了该方法具备对复合材料的力学行为进行预测和模拟的能力.

     

    Abstract: The evaluation of structural mechanical properties of composite materials is a key problem that needs to be solved urgently in the field of mechanical engineering. In this paper, the material stress and strain data are combined with the cell-vertex Finite Volume Method (CV-FVM) to form a data-driven cell-vertex Finite Volume Method, which is used to solve the complex and costly problem of the composite construction mode. In this method, the stress-strain data of materials are combined with the lattice type finite volume method. By using staggered grid technology, the stress-strain data are defined in the element, and the displacement and Lagrange multipliers are defined in the node, a control body is constructed around the node, and the stress-strain data is allocated to each element. The geometric equations and equilibrium equations of each control body are discrete and solved based on the cell-vertex Finite Volume Method. Finally, the optimal solution of the problem was found by minimizing the extreme distance between the points satisfying the conservation law and the points in the material database. The numerical solution program is developed in C++language, and the mechanical properties of the square plate with holes of uniform materials and the composite tensile and pressing plate of functionally graded materials are analyzed by the program. The numerical results show that the proposed method is suitable for triangular meshes, bilinear quadrilateral elements and hybrid meshes. The influence of the number of data points, the distance between data points and the value of constant matrix on the calculation results is consistent with the conclusions of finite element method in the existing literature. When the computational cost is similar, the accuracy of the results of the proposed method is close to that of the data-driven algorithm in the finite element scheme, which verifies the effectiveness of the proposed method. Finally, the numerical simulation of functional gradient plate shows that the method has the ability to predict and simulate the mechanical behavior of composite materials.

     

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