On New Method and 3D Codes for Shock Wave Simulation in Fluids and Solids in Euler Variables based on a Modified Godunov Scheme

Q3 Engineering

WSEAS Transactions on Fluid Mechanics Pub Date : 2023-12-14 DOI:10.37394/232013.2023.18.17

M. Abuziarov, E. G. Glazova, A. V. Kochetkov, S. V. Krylov

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引用次数: 0

Abstract

A three-dimensional technique for modeling shock-wave processes both in fluids and solids and for modeling fluid-structure interaction problems is proposed. The technique is based on a modified Godunov's scheme of increased accuracy, which is the same for both fluids and solids, and uses Eulerian-Lagrangian multimesh algorithms. Improving the accuracy of the scheme is achieved only by changing the "predictor" step of the original Godunov scheme. A three-dimensional and time-dependent solution of Riemann's problem is used, which provides a second-order approximation in time and space in the domain of smooth solutions. Monotonicity in the domain of discontinuous solutions is ensured by the transition to the "predictor" step of the first-order scheme. A similar solution of the Riemann problem is used at the contact "fluids - solids”. For each body, three types of computational grids are used with an explicit Lagrangian choice of movable free and contact surfaces. The first type of mesh used is a Lagrangian surface mesh in the form of a continuous set of triangles (STL file), which is used both to set the initial geometry of an object and to accompany it in the calculation process, and two types of volumetric three-dimensional meshes. These are the basic Cartesian fixed grid for each object, and auxiliary movable local Euler-Lagrangian grids associated with each triangle of the surface Lagrangian grid. The results of numerical simulation of the processes of the impact of ice fragments on a titanium plate, acceleration by detonation products of deformable elastoplastic bodies of various shapes, and steel strikers piercing an aluminum plate are presented.

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基于修正戈杜诺夫方案的欧拉变量流体和固体冲击波模拟新方法和三维代码

提出了一种三维技术，用于模拟流体和固体中的冲击波过程，以及模拟流固耦合问题。该技术基于精度更高的改进型戈杜诺夫方案，该方案对流体和固体均相同，并使用欧拉-拉格朗日多时算法。只需改变原始戈杜诺夫方案的 "预测器 "步骤，即可提高该方案的精度。采用了黎曼问题的三维时变解，在光滑解域中提供了时间和空间上的二阶近似。通过过渡到一阶方案的 "预测 "步骤，确保了非连续解域的单调性。在 "流体-固体 "接触处使用了类似的黎曼问题解决方案。对于每一个体，都使用了三种类型的计算网格，并对可移动的自由表面和接触表面进行了明确的拉格朗日选择。第一种网格是连续三角形集形式的拉格朗日表面网格（STL 文件），用于设置物体的初始几何形状，并在计算过程中伴随它；还有两种体积三维网格。它们是每个物体的基本笛卡尔固定网格，以及与表面拉格朗日网格的每个三角形相关联的辅助可移动局部欧拉-拉格朗日网格。本文介绍了冰碎片撞击钛板、各种形状的可变形弹塑性体的爆炸产物加速以及钢制冲锋枪刺穿铝板等过程的数值模拟结果。

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

WSEAS Transactions on Fluid Mechanics Engineering-Computational Mechanics

CiteScore

1.50

自引率

0.00%

发文量

期刊介绍： WSEAS Transactions on Fluid Mechanics publishes original research papers relating to the studying of fluids. We aim to bring important work to a wide international audience and therefore only publish papers of exceptional scientific value that advance our understanding of this particular area. The research presented must transcend the limits of case studies, while both experimental and theoretical studies are accepted. It is a multi-disciplinary journal and therefore its content mirrors the diverse interests and approaches of scholars involved with multiphase flow, boundary layer flow, material properties, wave modelling and related areas. We also welcome scholarly contributions from officials with government agencies, international agencies, and non-governmental organizations.