A Finite Element Based Method to Predict and Tailor the Energy Associated With Snap-Through Buckling of a Curved Beam

Volume 3: Advanced Materials: Design, Processing, Characterization, and Applications Pub Date : 2021-11-01 DOI:10.1115/imece2021-67793

C. S. Florio

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Abstract

Although structural instabilities have traditionally been avoided in design as undesirable causes of failure, the rapid and potentially significant energy changes that result from the large displacements induced by buckling have gained recent interest as a favorable design feature for systems whose intent is energy dissipation or energy storage. Computational methods to quantify the energy changes associated with buckling of a transversely loaded curved beam are developed in this work. The methods are then used to predict the occurrence of buckling based on initial geometry and input load. The influence of the parameters of the numerical approximation, such as mesh and time step, is also explored. Correlations are made between the simpler behavior of a truss structure and the more complex behavior of a curved beam so that analytical solutions may be used to guide the understanding of structures whose response can only be predicted computationally. The techniques which are presented can aid in the more efficient design of energy dissipation, transfer, and storage systems that take advantage of buckling instability phenomena.

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一种基于有限元的弯曲梁屈曲能量预测与调整方法

虽然结构不稳定性在设计中一直被视为不希望的失效原因，但由于屈曲引起的大位移导致的快速且潜在的重大能量变化最近引起了人们的兴趣，因为它是旨在耗散或储存能量的系统的有利设计特征。在这项工作中，开发了量化与横向加载弯曲梁屈曲相关的能量变化的计算方法。然后利用这些方法根据初始几何形状和输入载荷预测屈曲的发生。探讨了数值逼近参数(如网格和时间步长)的影响。在较简单的桁架结构和较复杂的弯曲梁之间建立了关联，以便用解析解来指导对那些只能通过计算预测响应的结构的理解。所提出的技术可以帮助更有效地设计利用屈曲不稳定现象的能量耗散、传递和存储系统。

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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Volume 3: Advanced Materials: Design, Processing, Characterization, and Applications

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