Finite element simulation of low velocity impact on shape memory alloy composite plates

IF 7.1 2区材料科学 Q1 MATERIALS SCIENCE, COMPOSITES Composite Structures Pub Date : 2005-12-01 DOI:10.1016/j.compstruct.2005.09.029

M. Meo , E. Antonucci , P. Duclaux , M. Giordano

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引用次数: 45

Abstract

Delamination of composite materials due to low velocity impacts is one of the major failure types of aerospace composite structures. The low velocity impact may not immediately induce any visible damage on the surface of structures whilst the stiffness and compressive strength of the structures can decrease dramatically.

Shape memory alloy (SMA) materials possess unique mechanical and thermal properties compared with conventional materials. Many studies have shown that shape memory alloy wires can absorb a lot of the energy during the impact due to their superelastic and hysteretic behaviour. The superelastic effect is due to reversible stress induced transformation from austenite to martensite. If a stress is applied to the alloy in the austenitic state, large deformation strains can be obtained and stress induced martensite is formed. Upon removal of the stress, the martensite reverts to its austenitic parent phase and the SMA undergoes a large hysteresis loop and a large recoverable strain is obtained. This large strain energy absorption capability can be used to improve the impact tolerance of composites. By embedding superelastic shape memory alloys into a composite structure, impact damage can be reduced quite significantly.

This article investigates the impact damage behaviour of carbon fiber/epoxy composite plates embedded with superelastic shape memory alloys wires. The results show that for low velocity impact, embedding SMA wires into composites increase the damage resistance of the composites when compared to conventional composites structures.

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形状记忆合金复合材料板低速冲击的有限元模拟

复合材料的低速冲击分层是航空航天复合材料结构的主要失效类型之一。低速冲击可能不会立即对结构表面产生明显的损伤，但会使结构的刚度和抗压强度急剧下降。形状记忆合金(SMA)材料与传统材料相比，具有独特的机械性能和热性能。许多研究表明，形状记忆合金丝由于其超弹性和滞回特性，在冲击过程中会吸收大量的能量。超弹性效应是由可逆应力诱导的奥氏体向马氏体转变引起的。在奥氏体状态下对合金施加应力，可获得较大的变形应变，形成应力诱发马氏体。在去除应力后，马氏体恢复到其奥氏体母相，SMA经历了一个大的滞后回路，获得了一个大的可恢复应变。这种巨大的应变能吸收能力可用于提高复合材料的抗冲击能力。通过在复合材料结构中嵌入超弹性形状记忆合金，可以显著降低复合材料的冲击损伤。研究了超弹性形状记忆合金丝嵌入碳纤维/环氧复合材料板的冲击损伤行为。结果表明，在低速冲击下，与传统复合材料结构相比，在复合材料中嵌入SMA金属丝可以提高复合材料的抗损伤能力。

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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来源期刊

Composite Structures 工程技术-材料科学：复合

CiteScore

12.00

自引率

12.70%

发文量

1246

审稿时长

78 days

期刊介绍： The past few decades have seen outstanding advances in the use of composite materials in structural applications. There can be little doubt that, within engineering circles, composites have revolutionised traditional design concepts and made possible an unparalleled range of new and exciting possibilities as viable materials for construction. Composite Structures, an International Journal, disseminates knowledge between users, manufacturers, designers and researchers involved in structures or structural components manufactured using composite materials. The journal publishes papers which contribute to knowledge in the use of composite materials in engineering structures. Papers deal with design, research and development studies, experimental investigations, theoretical analysis and fabrication techniques relevant to the application of composites in load-bearing components for assemblies, ranging from individual components such as plates and shells to complete composite structures.