Tensile properties of 2024 Al alloy processed by enhanced solid-solution and equal-channel angular pressing 被引量：3

Tensile properties of 2024 Al alloy processed by enhanced solid-solution and equal-channel angular pressing

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摘要 Equal-channel angular pressing(ECAP) of an enhanced solid-solution treated 2024 Al alloy was successfully performed at room temperature, with an imposed equivalent normal strain of about 0.5. A very high hardness about HV191 and yield strength about 610 MPa (30% higher than those of the unECAPed 2024 Al alloy) in terms of commercial aluminum alloys were observed for the ECAPed 2024 Al alloy. In addition to the strengthening, this process allows the ECAPed 2024 Al alloy have a moderate level of tensile ductility (about 12.7%) and a significant strain hardening capability up to tensile failure. After aged at 373 K for 48 h, the ECAPed alloy increases its hardness (about HV201) and tensile ductility (about 14 %) further. The TEM results show that the ECAPed 2024 Al alloy presents a plate structure (about 50-100 nm) with high density of dislocation and additional thin plate (approximately <10 nm= inside. The XRD results show that the ECAP processing decreases the texture and increases the dislocation density of the alloy considerably. The theoretical calculations show that the increase of dislocation density resulting from ECAP processing makes a considerable contribution about 55.2 % for the improvement of yield strength. Equal-channel angular pressing（ECAP） of an enhanced solid-solution treated 2024 Al alloy was successfully performed at room temperature, with an imposed equivalent normal strain of about 0.5. A very high hardness about HV191 and yield strength about 610 MPa （30% higher than those of the unECAPed 2024 Al alloy） in terms of commercial aluminum alloys were observed for the ECAPed 2024 Al alloy. In addition to the strengthening, this process allows the ECAPed 2024 Al alloy have a moderate level of tensile ductility （about 12.7%） and a significant strain hardening capability up to tensile failure. After aged at 373 K for 48 h, the ECAPed alloy increases its hardness （about HV201） and tensile ductility （about 14 %） further. The TEM results show that the ECAPed 2024 AI alloy presents a plate structure （about 50-100 nm） with high density of dislocation and additional thin plate （approximately 〈10 nm= inside. The XRD results show that the ECAP processing decreases the texture and increases the dislocation density of the alloy considerably. The theoretical calculations show that the increase of dislocation density resulting from ECAP processing makes a considerable contribution about 55.2 % for the improvement of yield strength.

作者许晓静曹进琪程晓农莫纪平

机构地区 School of Mechanical Engineering

出处《中国有色金属学会会刊：英文版》 CSCD 2006年第A03期1541-1544,共4页 Transactions of Nonferrous Metals Society of China

基金 Project(02KJD460004) supported by the Natural Science Foundation of Jiangsu Province, China

关键词铝合金固相机械性能有色金属 aluminum alloy enhanced solid-solution treatment equal-channel angular pressing mechanical properties

分类号 TG306 [金属学及工艺—金属压力加工]

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