约束槽压及热处理Ti6Al4V合金的EBSD研究

Volume 3: Advanced Materials: Design, Processing, Characterization, and Applications Pub Date : 2021-11-01 DOI:10.1115/imece2021-70393

A. Bhardwaj, N. Gohil, A. Sharma, K. Lakshman Rao, A. Gupta, S. Kumar

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引用次数: 0

摘要

由于其高强度重量比和优异的耐腐蚀性，Ti6Al4V金属板在航空航天，国防和生物医学领域得到了重要应用。织构对材料的机械性能起着重要的作用，可以通过热机械加工加以改变。约束槽压制是一种众所周知的金属板的严重塑性变形(SPD)技术，用于晶粒细化和力学性能的提高。在这项工作中，成功地对Ti6Al4V合金在550℃下进行了高温CGP，然后在500℃下进行热处理。CGP和热处理使晶粒细化，形成亚微米尺寸的晶粒。逆极图(IPF)显示，CGPed Ti6Al4V基面织构强度从5.9下降到4.5。热处理进一步降低了IPF织构强度至3.5。力学性能如YS、UTS和显微硬度的增强也被观察到。虽然屈服强度略有提高，但经过CGP和热处理后的极限抗拉强度提高了21%。在处理后的样品中也观察到高达20%的显微硬度改善。CGP和热处理可以作为一种有效的技术来定制Ti6Al4V和其他HCP合金的显微组织和力学性能。

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EBSD Investigation of Ti6Al4V Alloy Processed by Constrained Groove Pressing and Heat Treatment

Ti6Al4V sheet metal has found significant applications in the aerospace, defence and biomedical sectors due to its high strength-to-weight ratio and excellent corrosion resistance. The texture plays an important role in tailoring the mechanical properties which can be modified via thermo-mechanical processing. Constrained groove pressing (CGP) is a well-known sheet metal severe plastic deformation (SPD) technique for grain refinement and enhancement of mechanical properties. In this work, high temperature CGP has been performed successfully on Ti6Al4V alloy at 550°C followed by heat treatment at 500°C. CGP and heat treatment led to grain refinement and formation of submicron size grains. The inverse pole figure (IPF) reveals the decrease in texture intensity of basal planes from 5.9 to 4.5 in CGPed Ti6Al4V. Heat treatment further reduced the IPF texture intensity to 3.5. Enhancement in mechanical properties such as YS, UTS and microhardness is also observed. Although slight enhancement is observed in yield strength, ultimate tensile strength has been improved by 21% after CGP and heat treatment. Up to 20% improvements in microhardness have also been observed in processed samples. CGP and heat treatment together can serve as an efficient technique for tailoring microtexture and mechanical properties of Ti6Al4V and other HCP alloys.

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Volume 3: Advanced Materials: Design, Processing, Characterization, and Applications

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