<strong>Cu</strong>对搅拌摩擦加工高锌镁合金性能的影响

doi:10.11901/1005.3093.2025.199

材料研究学报

2025, Vol. 39

Issue (11): 813-823 DOI: 10.11901/1005.3093.2025.199

研究论文

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Cu对搅拌摩擦加工高锌镁合金性能的影响

戴衡霞¹, 董旭光¹(

), 薛鹏¹^,², 倪丁瑞², 马宗义¹^,²

^1.沈阳理工大学材料科学与工程学院沈阳 110159
^2.中国科学院金属研究所师昌绪先进材料创新中心沈阳 110016

Effect of Cu Content on Properties of Friction Stir Processed Mg-8Zn-xCu Alloys

DAI Hengxia¹, DONG Xuguang¹(

), XUE Peng¹^,², NI Dingrui², Ma Zongyi¹^,²

^1.School of Materials Science and Engineering, Shenyang Ligong University, Shenyang 110159, China
^2.Shi -changxu Innovation Center for Advanced Materials, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China

引用本文:

戴衡霞, 董旭光, 薛鹏, 倪丁瑞, 马宗义. Cu对搅拌摩擦加工高锌镁合金性能的影响[J]. 材料研究学报, 2025, 39(11): 813-823.
Hengxia DAI, Xuguang DONG, Peng XUE, Dingrui NI, Zongyi Ma. Effect of Cu Content on Properties of Friction Stir Processed Mg-8Zn-xCu Alloys[J]. Chinese Journal of Materials Research, 2025, 39(11): 813-823.

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摘要:

用搅拌摩擦加工(FSP)技术制备3种不同Cu含量的Mg-8Zn-xCu合金 (x = 0, 0.5, 1, 质量分数，%)并使用差热分析法和背散射电子成像等手段对其表征，研究了Cu含量对其性能的影响。结果表明，随着Cu含量的提高Mg-8Zn合金的凝固共晶相由346 ℃低熔点二元共晶向434 ℃高熔点三元共晶转变，主要共晶化合物由Mg₇Zn₃相转变为MgZnCu相，共晶温度的提高抑制了FSP过程中的共晶熔化开裂。Cu含量为0.5%的合金，搅拌摩擦热-力耦合作用使加工区中大部分粗大第二相固溶于镁基体，使Zn元素的固溶量高达6.62% (质量分数)，约为室温平衡固溶度的4倍。与FSP Mg-8Zn 合金相比，FSP Mg-8Zn-0.5Cu合金的抗拉强度(提高50 MPa)达到了300 MPa，断裂伸长率从13.4%显著提高到30.2%。产生这一优异的强韧化效果的原因是组织均匀性的提高、高含量Zn的固溶强化、晶粒细化以及MgZn₂动态沉淀相的协同作用。Cu含量提高到1%使未固溶的第二相在加工区呈带状偏聚，导致合金的拉伸性能显著降低。

关键词 ：金属材料, 高锌镁合金, 搅拌摩擦加工, 热裂, 共晶, 固溶

Abstract：

Three Mg-8Zn-xCu (x = 0, 0.5 and 1, mass fraction, %) alloys were prepared by friction stir processing (FSP). Meanwhile, the influence of Cu content on the formability and mechanical properties of FSP Mg-8Zn alloys at high rotation rate was investigated by differential thermal analysis (DTA) and backscattered electron (BSE) etc. It was found that with the increasing Cu content, the eutectic in the Mg-8Zn-xCu alloys was transformed from a low-melting-point binary eutectic (346 °C) to a high-melting-point ternary eutectic (434 °C) during solidification process. The predominant eutectic phase was evolved from the Mg₇Zn₃ to the MgZnCu phase. The elevated eutectic temperature effectively suppressed the liquation (i.e., liquid formation) and liquation-induced cracking during FSP. By a Cu content of 0.5%, most of the secondary phases were dissolved into the Mg matrix via the thermo-mechanical coupling effect of FSP. This resulted in a super high Zn solid solution content of 6.62% (mass fraction) in Mg matrix, approximately 4 times of the room-temperature equilibrium solubility. Compared with the FSP Mg-8Zn alloy, the FSP Mg-8Zn-0.5Cu alloy exhibits a 50 MPa increase in tensile strength, achieving 300 MPa, and the elongation to fracture significantly increases from 13.4% to 30.2%. It is the improvement of microstructural uniformity that leads to a simultaneous enhancement of strength and ductility, supplemented by the synergistic action of high-content Zn solid solution strengthening, grain refinement, and MgZn₂ dynamic precipitation strengthening. As the Cu content was increased to 1%, stripe-like particle clusters formed within the processing zone due to the undissolved secondary phases, leading to a significant degradation in tensile properties.

Key words： metallic materials high-zinc magnesium alloy friction stir processing liquation-induced cracking eutectic solid solution

收稿日期: 2025-06-10

ZTFLH:

TG146.22

基金资助:国家自然科学基金(52071317);沈阳市U40杰出青年基金(RC230864)

通讯作者: 董旭光，副教授，xgdong@sylu.edu.cn，研究方向为轻合金设计及先进制备技术

Corresponding author: DONG Xuguang, Tel: 13555804884, E-mail: xgdong@sylu.edu.cn

作者简介: 戴衡霞，女，2000年生，硕士

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https://www.cjmr.org/CN/10.11901/1005.3093.2025.199 或 https://www.cjmr.org/CN/Y2025/V39/I11/813

表1 镁基二元合金的共晶特性和固溶度参数

图1 铸态组织的SEM形貌

图2 Mg-Zn二元合金的相图[17]和共晶点[Mg-51.3Zn，613 K (340 ℃)]附近的局部放大图[19]

图3 铸态合金的差热分析

图4 FSP样品的表面形貌图

图5 FSP Mg-8Zn合金的横截面组织形貌

图6 FSP Mg-8Zn-xCu合金加工区的横截面组织形貌

图7 Mg-8Zn-0.5Cu合金的EBSD微观组织

图8 Mg-8Zn和Cu改性合金的XRD谱

图9 FSP Mg-8Zn-0.5Cu合金中纳米析出相的形貌(电子束平行于<112¯0> α )

图10 FSP Mg-8Zn-xCu合金横截面硬度的分布

图11 FSP Mg-8Zn-xCu合金的工程应力-应变曲线和FSP Mg-Zn合金力学性能[23~30]

图12 FSP Mg-8Zn-xCu合金断口的形貌

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