基于薄壳等几何分析的压力容器断裂建模

IF 5.3 Q1 ENGINEERING, MECHANICAL
Rijul Singla, C. Anitescu, S. Singh, I. Singh, B. K. Mishra, T. Rabczuk, X. Zhuang
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引用次数: 4

摘要

我们的目标是对压力容器表面的裂缝进行建模,以避免其破裂。众所周知,压力容器在几乎所有行业中都有广泛的应用。它们经常受到高压和极端温度的影响,在一些典型的应用中,它们甚至携带高度易燃或危险的物质。在存在裂纹的情况下,由于裂纹尖端的应力奇异现象,断裂区附近的应力状态变得非常高。这大大降低了材料的强度,并可能导致早期失效。在本文中,压力容器的几何形状使用样条离散化,样条被用作等几何分析(IGA)的基础。首先,通过实施基于IGA的Kirchhoff-Love壳理论,在没有裂纹的情况下对薄压力容器进行应力分析,并将结果与分析或标准可用解决方案进行比较。假设裂纹穿过整个厚度,并沿轴向或周向引入。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Modelling of fracture in pressure vessels by thin shell isogeometric analysis
We aim to model fracture on pressure vessel surfaces so that its rupture can be avoided. It is well known that pressure vessels have wide-spread applications in almost all industries. They are often subjected to high pressures and extreme temperatures and in some typical applications they even carry highly flammable or hazardous substances. In the presence of cracks, the state of stress near the fracture zone becomes very high, due to the phenomenon of stress singularity at the crack tips. This greatly reduces the strength of the material and can lead to early failure. In this paper, the geometry of pressure vessels is discretised using splines which are used as the basis for isogeometric analysis (IGA). Initially, the stress analysis of thin pressure vessel is carried out in the absence of cracks by implementing IGA-based Kirchhoff-Love shell theory, and the results are compared with analytical or standard available solutions. The crack is assumed to cross the entire thickness and is introduced either in axial or circumferential direction.
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来源期刊
CiteScore
7.60
自引率
0.00%
发文量
32
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