锻压技术

钩织烧结多孔管与铝合金薄壁管复合结构的轴向冲击吸能特性

英文标题：Axial crushing energy absorption properties of composite structure for crochet-sintering porous tube and thin-walled aluminium alloy tube

作者：杨洁肖小亭吴菲刘倩

单位：广东工业大学

关键词：多孔管 6063铝合金空心薄壁管复合结构轴向冲击防撞性吸能特性

分类号：TG146

出版年,卷(期):页码：2018,43(7):176-182

摘要：

以超细软304不锈钢丝绳为基材，采用短针环形钩织和真空固相烧结的方法制备一种新型多孔管，研究了该多孔管的轴向冲击吸能特性。将多孔管（C）与6063铝合金空心薄壁管（T）复合制备了两种不同复合形式的复合管——外复合管（TC）、薄壁芯复合管（CTC）。对复合管结构及相应的铝合金空心薄壁管进行了轴向冲击吸能性能对比研究。结果表明：新型钩织多孔管具有优良的吸能特性，是良好的吸能结构组件。复合结构的能量吸收（EA）、初始峰值冲击载荷（PCF）和平均冲击载荷（MCF）均大于相应空心薄壁管。复合结构的变形模式受多孔管与空心薄壁管复合效应影响而发生变化。两种复合管中，薄壁芯复合管（CTC）的载荷效率（CFE）最大，并且高于相应的空心薄壁管，具有最好的吸能效果。

Taking ultrafine soft stainless steel 304 wire rope as the base material, a new type of porous tube was produced by the method of single annular crocheting and vacuum solidphase sintering, and the axial crushing energy absorption properties of porous tube were studied. Then, two kinds of composite tubes, external composite tube (TC) and thinwall core composite tube (CTC), were fabricated by the combination of porous tube (C) and thin-walled hollow tube(T) for aluminum alloy 6063, and the axial impact energy absorption properties of composite tube structures and corresponding thin-wall hollow tubes for aluminium alloy were researched comparatively. The results show that the new type of crochet-sintering porous tube has excellent energy-absorbing properties and it is a good energy-absorbing structural component. However, the energy absorption (EA), the initial peak crushing force (PCF) and the mean crusing force (MCF) of composite structures are all larger than the corresponding thin-walled hollow tubes, and the deformation mode of composite structures is influenced by the compound effect of porous tube and thin-walled hollow tube. Thus, between two kinds of composite tubes, the crushing force efficiency (CFE) of CTC is the maximum and even higher than that of the corresponding thin-walled hollow tube, and CTC has the best energy-absorbing effect.

基金项目：

国家自然科学基金资助项目（51705085）

杨洁（1993-），女，硕士研究生，E-mail：gdutyangjie@163.com；通讯作者：肖小亭（1957-），男，博士,教授，博士生导师，E-mail：xiaoxt@gdut.edu.cn

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