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Mg-Bi合金中超-细混晶结构的构筑及其强韧化机理
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1.兰州理工大学 省部共建有色金属先进加工与再利用国家重点实验室;2.山东建筑大学 高端装备材料可靠性研究院;3.兰州理工大学温州泵阀工程研究院

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国家自然科学基金资助(52265048);甘肃省科技重大专项(22ZD6GA008);甘肃省高等学校创新项目(2022A-025);中国博士后科学基金(2022M713656);温州市级科技计划项目(G2023018);甘肃省青年科技基金计划(21JR7RA261);兰州理工大学红柳优秀青年基金人才支持计划(062205)


Construction of bimodal-grained Mg-Bi alloy composed of ultrafine grains and fine grains and its strengthening and toughening mechanisms
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国家自然科学基金资助(52265048);甘肃省科技重大专项(22ZD6GA008);甘肃省高等学校创新项目(2022A-025);中国博士后科学基金(2022M713656);温州市级科技计划项目(G2023018);甘肃省青年科技基金计划(21JR7RA261);兰州理工大学红柳优秀青年基金人才支持计划(062205)

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    摘要:

    为制备出由超细晶(<1 μm)和细晶(1-10 μm)构成的超-细混晶结构镁合金,基于低温等径角挤压(ECAP)加工在制备超-细混晶结构金属材料方面的巨大潜力以及细晶Mg-Bi基合金优异的低温塑性变形性能,本研究选取细晶Mg-6Bi合金为坯料,提出逆温度场等径角挤压(ITF-ECAP)技术,实现了细晶Mg-6Bi合金的低温(<100 ℃)多道次强塑性变形加工。微观组织与力学性能表征结果表明,细晶Mg-6Bi合金在多道次ITF-ECAP加工过程中,优先在初始晶界处发生动态再结晶,同时有大量亚微米级Mg3Bi2相析出。4道次ITF-ECAP加工后,Mg-6Bi合金中形成了由平均晶粒尺寸(AGS)约为600 nm的超细晶区和AGS约为2 μm的细晶区构成的超-细混晶结构,其超细晶区体积分数约占72.5%。归因于细晶强化、沉淀强化、位错强化与背应力强化共同作用的结果,超-细混晶结构Mg-6Bi合金兼具优异的强度和塑性,其屈服强度和延伸率分别达到315.6±3.6 MPa与22.3±1.0 %。

    Abstract:

    Low-temperature equal channel angular pressing (ECAP) processing technology has great potential in fabricating bimodal-grained alloys composed of ultrafine grains and fine grains. Besides, fine grain Mg-Bi based alloys demonstrate excellent low temperature plastic deformation performance. Based on this, a new inverse temperature field ECAP (ITF-ECAP) processing method was developed to realize the severe plastic processing of a fine grained Mg-6Bi (B6) alloy at low temperature (<100 ℃) to construct a bimodal-grained microstructure composed of ultrafine (<1 μm) and fine grains (1-10 μm). The microstructure and mechanical properties characterization results show that dynamic recrystallization preferentially occurred at the initial grain boundaries of the fine-grained B6 alloy during the multi pass ITF-ECAP processing. Besides a large amount of submicron sized Mg3Bi2 phase precipitated during ITF-ECAP processing. As a result, bimodal-grained microstructure consisting of ultrafine grains with an average grain size (AGS) of about 600 nm and fine grain region with an AGS of about 2 μm was successfully constructed in B6 alloy through 4-pass ITF-ECAP processing. The volume fraction of the ultrafine grain region accounts for about 72.5 %. Due to the combined effects of grain-boundary strengthening, precipitation strengthening, dislocation strengthening, and back stress strengthening, the bimodal-grained B6 alloy exhibits excellent strength and ductility, with yield strength and elongation reaching 315.6±3.6 MPa and 22.3±1.0 %, respectively.

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孟帅举,宋金龙,陈可意,崔 敏,王立冬,毕广利,曹 驰,杨贵荣. Mg-Bi合金中超-细混晶结构的构筑及其强韧化机理[J].稀有金属材料与工程,,().[mengshuaiju, songjinlong, chenkeyi, cuimin, wanglidong, biguangli, caochi, yangguirong. Construction of bimodal-grained Mg-Bi alloy composed of ultrafine grains and fine grains and its strengthening and toughening mechanisms[J]. Rare Metal Materials and Engineering,,().]
DOI:10.12442/j. issn.1002-185X.20240480

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  • 收稿日期:2024-08-02
  • 最后修改日期:2024-09-18
  • 录用日期:2024-09-27
  • 在线发布日期: 2024-11-21
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