Numerical Investigation on the Capability of Modeling Approaches for Composite Cylinders under Low-Velocity Impact Loading

Shiva Rezaei Akbarieh, D. Ma, C. Sbarufatti, A. Manes
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Abstract

Composite pressure vessels can be exposed to extreme loadings, for instance, impact loading, during manufacturing, maintenance, or their service lifetime. These kinds of loadings may provoke both visible and invisible levels of damage, e.g., fiber breakage matrix cracks and delamination and eventually may lead to catastrophic failures. Thus, the quantification and evaluation of such damages are of great importance. Considering the cost of relevant full-scale experiments, a numerical model can be a powerful tool for such a kind of study. This paper aims to provide a numerical study to investigate the capability of different modeling methods to predict delamination in composite vessels. In this study, various numerical modeling aspects, such as element types (solid and shell elements) and material parameters (such as interface properties), were considered to investigate delamination in a composite pressure vessel under low-velocity impact loading. Specifically, solid elements were used to model each layer of the composite pressure vessel, while, in another model, shell elements with composite layup were considered. Compared with the available experimental data from low-velocity impact tests described in the literature, the capability of these two models to predict both mechanical responses and failure phenomena is shown.
低速冲击载荷下复合材料圆柱体建模方法能力的数值研究
复合材料压力容器在制造、维护或使用寿命期间可能会受到极端载荷的影响,例如冲击载荷。这些载荷可能会引发可见和不可见的损伤,例如纤维断裂、基体裂纹和分层,最终可能导致灾难性的故障。因此,量化和评估此类损坏非常重要。考虑到相关全尺寸实验的成本,数值模型可以成为此类研究的有力工具。本文旨在提供一项数值研究,探讨不同建模方法预测复合材料容器分层的能力。在这项研究中,考虑了各种数值建模方面的因素,如元素类型(实体和壳体元素)和材料参数(如界面属性),以研究复合材料压力容器在低速冲击载荷下的分层问题。具体来说,复合材料压力容器的每一层都使用了实体元素建模,而在另一个模型中,则考虑了复合材料层叠的壳元素。与文献中描述的现有低速冲击试验数据相比,这两个模型都显示出预测机械响应和破坏现象的能力。
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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