Electromagnetic Expansion and Fragmentation of Hollow Aluminium 5052 Tube

Journal of Minerals and Materials Characterization and Engineering Pub Date : 2020-10-21 DOI:10.4236/jmmce.2020.86027

H. Choudhary, C. Gupta, N. Tiwari, T. Kolge, R. Kapoor, Archana Sharma

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引用次数: 2

Abstract

Electromagnetic forming is a high-speed forming technology by which hollow profiles can be compressed or expanded. It is done with a pulsed magnetic field to apply Lorentz’ forces at electrically conductive material. Electromagnetic hollow tube expansion is limited by the fragmentation tendency. This work attempts to use a combination of analytical and computational approach to compute the net tangential stress during tube expansion. A simplified analytical framework to estimate the temporal evolution of plastic stresses present in aluminium alloy AA5052 at low and high applied magnetic pressures is developed based upon dynamic imaging. The time resolved images captured using current synchronised high speed camera record the overall dimensional changes of the tube that is validated by multi-physics simulation of expansion process. Imaging of hollow tube expansions at two selected peak currents has been carried out at various current levels in the range 76 - 160 kA. The direct visualisation of the increase in the tube diameter at two current levels provided a comparison of the developing net tangential stresses in the hollow tube during the undamaged and fragmented expansion. Imaging of tube expansion also facilitates the estimation of the strain rate experienced by the tube and was in the range of ~1700 s-1 to ~1200 s-1. The propensity of fragmentation was found to be due to the level and duration of generated tangential stresses above the yield stress during expansion of the aluminium tubes. Presented study provides a mean of exploiting the enhanced formability of aluminium alloys using electromagnetic forming.

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5052中空铝管的电磁膨胀与碎裂

电磁成形是一种高速成形技术，可以对空心型材进行压缩或膨胀。它是通过脉冲磁场在导电材料上施加洛伦兹力来完成的。电磁空心管的膨胀受到破碎倾向的限制。本工作尝试使用分析和计算相结合的方法来计算管道膨胀过程中的净切向应力。建立了一种基于动态成像的简化分析框架，用于估计在低和高外加磁压力下AA5052铝合金塑性应力的时间演变。利用当前同步高速相机拍摄的时间分辨图像记录了管道的整体尺寸变化，并通过多物理场模拟验证了膨胀过程。在76 - 160 kA范围内的不同电流水平下，对两个选定的峰值电流下的空心管膨胀进行了成像。在两个当前水平下，管径增加的直接可视化提供了空心管在未损坏和破碎膨胀期间发展的净切向应力的比较。管的膨胀成像也有助于估计管所经历的应变速率，其范围为~1700 s-1至~1200 s-1。在铝管膨胀过程中，由于产生的切向应力高于屈服应力的水平和持续时间，铝管碎裂的倾向被发现。本研究为利用电磁成形技术提高铝合金成形性能提供了一种手段。

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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Journal of Minerals and Materials Characterization and Engineering

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