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采用改进的多道次等通道转角挤压(ECAP)技术对RZ5镁合金板材进行严重塑性变形效应的研究。

Investigation of Severe Plastic Deformation Effects on Magnesium RZ5 Alloy Sheets Using a Modified Multi-Pass Equal Channel Angular Pressing (ECAP) Technique.

作者信息

Sahoo Partha Sarathi, Mahapatra Manas Mohan, Vundavilli Pandu Ranga, Sabat Rama Krushna, Sirohi Sachin, Kumar Sanjeev

机构信息

School of Mechanical Sciences, Indian Institute of Technology Bhubaneswar, Kansapada 752050, India.

School of Minerals, Metallurgical and Materials Engineering, Indian Institute of Technology Bhubaneswar, Kansapada 752050, India.

出版信息

Materials (Basel). 2023 Jul 21;16(14):5158. doi: 10.3390/ma16145158.

DOI:10.3390/ma16145158
PMID:37512434
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10385315/
Abstract

The present study investigates the effects of multiple passes of equal channel angular pressing (ECAP) on magnesium alloy sheets with the assistance of an Inconel plunger along with a die setup having a channel angle of 120° and corner angle of 10° operating at a temperature of 200 °C followed by the required heat treatment processes. The microstructural analysis of the sheet samples at various stages of the multi-pass hot ECAP has shown evidence of ultrafine grain refinement (UFG) due to the occurrence of severe plastic deformation. X-ray diffraction analysis has also exhibited the presence of phases like MgZn and CeZn which is supposedly responsible for the enhancement of the mechanical properties. As a result, the room temperature tensile and compressive strengths have improved by 6.12% and 6.63%, respectively, after the second pass, and 11.56% and 15.64%, respectively, after the fourth pass of ECAP. Additionally, the hardness of the sheets has increased by 6.49% and 16.64% after the second and fourth pass of hot ECAP, respectively, mainly attributed to the drastic decrease in grain size from 164 μm to 12 μm within four ECAP passes, all these with a negligible change in ductility. This success in the thermomechanical processing of Mg-RZ5 alloy sheets using a die channel angle of 120° with a minimal number of passes of hot ECAP under a controlled equivalent strain, further opens doors for incorporating optimizations and/or additional aspects so as to achieve even better grain refinements, and consequently, mechanical strength improvements thereby catering to the industrial needs of aerospace and construction areas.

摘要

本研究借助因科镍合金冲头,在通道角为120°、转角为10°的模具装置下,于200°C温度下对镁合金板材进行等通道转角挤压(ECAP)多道次加工,并随后进行所需的热处理工艺,以此研究多道次ECAP对镁合金板材的影响。对板材样品在多道次热ECAP不同阶段的微观结构分析表明,由于发生了严重的塑性变形,存在超细晶粒细化(UFG)的迹象。X射线衍射分析还显示出MgZn和CeZn等相的存在,据推测这些相是机械性能提高的原因。结果,在ECAP第二道次后,室温拉伸强度和压缩强度分别提高了6.12%和6.63%,在第四道次后分别提高了11.56%和15.64%。此外,热ECAP第二道次和第四道次后,板材硬度分别提高了6.49%和16.64%,这主要归因于在四道次ECAP过程中晶粒尺寸从164μm急剧减小至12μm,而所有这些过程中延展性的变化可忽略不计。在可控等效应变下,使用120°的模具通道角并采用最少的热ECAP道次对Mg-RZ5合金板材进行热机械加工取得的这一成功,进一步为纳入优化和/或其他方面敞开了大门,以便实现更好的晶粒细化,从而提高机械强度,进而满足航空航天和建筑领域的工业需求。

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