Fault-tolerant elastic–plastic lattice material

M. Ryvkin, V. Slesarenko, A. Cherkaev, S. Rudykh
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引用次数: 11

Abstract

The paper describes a fault-tolerant design of a special two-dimensional beam lattice. The morphology of such lattices was suggested in the theoretical papers (Cherkaev and Ryvkin 2019 Arch. Appl. Mech. 89, 485–501; Cherkaev and Ryvkin 2019 Arch. Appl. Mech. 89, 503–519), where its superior properties were found numerically. The proposed design consists of beam elements with two different thicknesses; the lattice is macro-isotropic and stretch dominated. Here, we experimentally verify the fault-tolerant properties of these lattices. The specimens were three-dimensional-printed from the VeroWhite elastoplastic material. The lattice is subjected to uniaxial tensile loading. Due to its morphology, the failed beams are evenly distributed in the lattice at the initial stage of damage; at this stage, the material remains intact, preserves its bearing ability, and supports relatively high strains before the final failure. At the initial phase of damage, the thinner beams buckle; then another group of separated thin beams plastically yield and rupture. The fatal macro-crack propagates after the distributed damage reaches a critical level. This initial distributed damage stage allows for a better energy absorption rate before the catastrophic failure of the structure. The experimental results are supported by simulations which confirm that the proposed fault-tolerant material possesses excellent energy absorption properties thanks to the distributed damage stage phenomenon. This article is part of the theme issue ‘Modelling of dynamic phenomena and localization in structured media (part 2)’.
容错弹塑性点阵材料
本文描述了一种特殊二维梁格的容错设计。理论论文(Cherkaev and Ryvkin 2019 Arch)提出了这种晶格的形态。达成。机械89、485-501;Cherkaev和Ryvkin 2019拱门。达成。机械,89,503-519),在那里它的优越性能被发现的数值。提出的设计由两种不同厚度的梁单元组成;晶格是宏观各向同性和拉伸主导的。在这里,我们通过实验验证了这些格的容错特性。这些样本是用VeroWhite弹塑性材料三维打印出来的。晶格受到单轴拉伸载荷。由于其形态的原因,在损伤初始阶段,失效梁均匀分布在晶格中;在此阶段,材料保持完整,保持其承载能力,并在最终破坏之前承受相对较高的应变。在损伤初期,较薄的梁发生屈曲;然后另一组分离的薄梁塑性屈服并断裂。当分布损伤达到临界水平后,致命宏裂纹开始扩展。这种初始分布损伤阶段允许在结构发生灾难性破坏之前有更好的能量吸收率。实验结果与仿真结果相吻合,表明该容错材料由于存在分布式损伤阶段现象,具有良好的能量吸收性能。本文是主题“结构化媒体中动态现象的建模和定位(第二部分)”的一部分。
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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