On the Free Recovery Bending Shape Memory Effect in Powder Metallurgy FeMnSiCrNi

The Annals of “Dunarea de Jos” University of Galati. Fascicle IX, Metallurgy and Materials Science Pub Date : 2021-09-15 DOI:10.35219/mms.2021.3.01

L. Ciurcă, B. Pricop, M. Popa, Victor Daniel Apostol, L. Bujoreanu

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Abstract

This paper presents the results of an original experimental study on the training capacity of a powder metallurgy (PM) FeMnSiCrNi shape memory alloy (SMA). The specimens were sintered under protective atmosphere from blended elemental powders, 50 vol.%. of alloy particles being mechanically alloyed. Lamellar specimens, hot rolled to 1 mm thickness, were bent against cylindrical calibres with five decreasing radii, to induce cold shapes with higher and higher deformation degree, as compared to the straight hot shape. During the training procedure, bent specimens were heated with a hot air gun, and developed free-recovery shape memory effect (SME) and partially deflected, by reducing their curvature. The first set of experiments involved fastening the specimens at one end, heating it and monitoring free end’s displacement by means of cinematographic analysis. Within the second set of experiments, both cold and hot shapes were recorded and digitalized and their chord’s length (b) and circle segment height (a) were measured and the radius was determined as R = a/2 + b2/8a for the cold (Rc) and hot shapes (Rh). Finally, the shape recovery degree was calculated for the nth calibre as Δrecn = (Rhn-Rrn)/(Rhn-1-Rrn) and the variation of Δrecn with calibre’s radius was discussed.

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粉末冶金FeMnSiCrNi自由恢复弯曲形状记忆效应研究

本文介绍了粉末冶金(PM) FeMnSiCrNi形状记忆合金(SMA)训练能力的原始实验研究结果。试样是在保护气氛下用体积分数为50%的混合元素粉烧结而成。合金颗粒被机械地合金化。热轧至1 mm厚度的板层状试样，对圆柱形口径以减小5个半径弯曲，与直热形相比，产生的冷形变形程度越来越高。在训练过程中，用热风枪加热弯曲试样，通过减小弯曲试样的曲率产生自由恢复形状记忆效应(SME)和部分偏转。第一组实验包括固定试样的一端，加热试样，并通过电影分析监测自由端位移。在第二组实验中，对冷型和热型进行记录和数字化，测量其弦长(b)和圆段高度(a)，确定冷型(Rc)和热型(Rh)的半径为R = a/2 + b2/8a。最后，计算了第n口径的形状恢复度Δrecn = (Rhn-Rrn)/(Rhn-1-Rrn)，并讨论了Δrecn随口径半径的变化规律。

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

The Annals of “Dunarea de Jos” University of Galati. Fascicle IX, Metallurgy and Materials Science

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审稿时长

8 weeks