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挤压管材与泡沫填充材料配对对复合AA6061/PVC结构能量吸收的影响

Influence of Extruded Tubing and Foam-Filler Material Pairing on the Energy Absorption of Composite AA6061/PVC Structures.

作者信息

Magliaro John, Mohammadkhani Pouya, Rahimidehgolan Foad, Altenhof William, Alpas Ahmet T

机构信息

Department of Mechanical, Automotive and Materials Engineering, University of Windsor, 401 Sunset Avenue, Windsor, ON N9B 3P4, Canada.

出版信息

Materials (Basel). 2023 Sep 19;16(18):6282. doi: 10.3390/ma16186282.

DOI:10.3390/ma16186282
PMID:37763559
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10533103/
Abstract

There is accelerating demand for energy-absorbing structures fabricated from lightweight materials with idealized, near-constant force responses to simultaneously resolve the engineering challenges of vehicle mass reduction and improved occupant safety. A novel compounded energy dissipation system composed of AA6061-T6 and AA6061-T4 tubing subjected to hybrid cutting/clamping and H130, H200 and H250 PVC foam compression was investigated utilizing quasi-static experiments, finite element simulations and theoretical modeling. Identical structures were also subjected to axial crushing to compare with the current state of the art. The novel cutting/foam crushing system exhibited highly stable collapse mechanisms that were uniquely insensitive to the tube/foam material configuration, despite the disparate material properties, and exceeded the energy-absorbing capacity and compressive force efficiency of the axial crushing mode by 14% and 44%, respectively. The simulated deformation profiles and force responses were consistent with the experiments and were predicted with an average error of 12.4%. The validated analytical models identified numerous geometric/material configurations with superior performance for the compounded AA6061/PVC foam cutting/foam crushing system compared to axial crushing. An Ashby plot comparing the newly obtained results to several findings from the open literature highlighted the potential for the compounded cutting/foam crushing system to significantly outperform several alternative lightweight safety systems.

摘要

对于由轻质材料制成的能量吸收结构的需求正在加速增长,这些结构具有理想化的、近乎恒定的力响应,以同时解决车辆减重和提高乘客安全性的工程挑战。利用准静态实验、有限元模拟和理论建模,研究了一种由AA6061-T6和AA6061-T4管材组成的新型复合能量耗散系统,该系统经过混合切割/夹紧以及H130、H200和H250 PVC泡沫压缩处理。相同的结构也进行了轴向压缩,以与现有技术水平进行比较。这种新型切割/泡沫压缩系统表现出高度稳定的坍塌机制,尽管材料性能不同,但对管材/泡沫材料配置具有独特的不敏感性,其能量吸收能力和压缩力效率分别比轴向压缩模式高出14%和44%。模拟的变形轮廓和力响应与实验结果一致,预测平均误差为12.4%。经过验证的分析模型确定了与轴向压缩相比,复合AA6061/PVC泡沫切割/泡沫压缩系统具有卓越性能的多种几何/材料配置。将新获得的结果与公开文献中的几项研究结果进行比较的阿什比图突出了复合切割/泡沫压缩系统显著优于几种替代轻质安全系统的潜力。

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