镁合金倾斜薄壁电弧熔丝增材制造工艺与力学性能研究
Deposition process and mechanical properties of magnesium alloy inclined thin-walls fabricated by wire-arc additive manufacturing
查看参考文献48篇
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文摘
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电弧增材制造是一种以金属丝材为填充材料,以电弧作为热源的新型制造技术,易于制造大型复杂零件。通过往复单向路径实验,发现单向路径制造的斜壁有更好的形貌,飞溅少且表面光滑,并在有限元软件中建立了往复、单向制造路径仿真模型并求解,仿真得到单向路径沉积温度267.4 ℃,沉积热应力357.4 MPa,往复路径沉积温度307.0 ℃,沉积热应力420.4 MPa,发现单向路径的热积累和热应力更低;以单向制造路径,采用电弧增材制造技术制备AM11,AM12,AM21三种不同斜率的斜壁样件,研究其组织和力学性能。结果表明:AM11,AM12,AM21的晶粒尺寸分别为35,39,42 μm;AM21薄壁晶粒中析出相β-Mg_(17)Al_(12)比另外两种样品多且分布均匀、拉伸断口的韧窝更大且更多;AM21与AM11显微硬度在81.5HV左右,均高于AM12的73.1HV;且AM21的斜壁样件的水平、竖直方向抗拉强度为255.7,224.4 MPa,屈服强度为103.8,96.0 MPa,伸长率达到13.1%,8.2%,抗拉强度与伸长率均大于AM11和AM12,但屈服强度接近。AM21斜率薄壁具有更好的强度和塑性,验证了镁合金电弧增材制造的斜壁越接近垂直,其强度、塑性等力学性能越好。 |
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其他语种文摘
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Wire-arc additive manufacturing is a new type of manufacture using wire as filling material and arc as a heat source, making it easier to manufacture complex-shaped and big-sized parts. The reciprocating and unidirectional process path experiment was conducted. The inclined wall made by unidirectional path has better morphology, less splash, and a smoother surface. The simulation model of AM11 reciprocating and unidirectional manufacturing path was established in finite element software and solved. The simulation results show that the unidirectional path deposition temperature is 267.4 ℃, the deposition thermal stress is 357.4 MPa, the reciprocating path deposition temperature is 307.0 ℃, and the deposition thermal stress is 420.4 MPa, the heat accumulation and thermal stress of unidirectional path are lower than that of reciprocating path. AM11, AM12, and AM21 inclined wall samples with different slope factors by wirearc additive manufacturing in unidirectional path were prepared, and their microstructure and properties were analyzed. The results indicate that the grain size of AM11, AM12, and AM21 is 35, 39 μm, and 42 μm, there is more precipitated β-Mg_(17)Al_(12) in AM21 thin-walled grains, which has larger and more dimples than that of the other two samples. The micro-hardness values of AM21 and AM11 are both about 81.5HV, higher than 73.1HV of AM12. The horizontal and vertical tensile strengths of the AM21 inclined wall sample are 255.7,224.4MPa, the yield strengths are 103.8,96.0 MPa, and the elongations reach 13.1% and 8.2%. The tensile strengths and elongations are both greater than those of AM11 and AM12 samples, but the yield strengths are close. The AM21 inclined wall has much better strength and plasticity, and verify that the more perpendicular the inclined wall of magnesium alloy arc additive manufacturing is, the better the mechanical properties such as strength and plasticity. |
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来源
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材料工程
,2024,52(7):57-70 【核心库】
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DOI
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10.11868/j.issn.1001-4381.2024.000149
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关键词
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电弧增材制造
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AZ91D镁合金
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薄壁件
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微观组织
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力学性能
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断口组织
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地址
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北京理工大学机械与车辆学院, 北京, 100081
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语种
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中文 |
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文献类型
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研究性论文 |
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ISSN
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1001-4381 |
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学科
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一般工业技术;金属学与金属工艺 |
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文献收藏号
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CSCD:7782213
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参考文献 共
48
共3页
|
|
1.
Zhang C H. Additive manufacturing of magnesium matrix composites: comprehensive review of recent progress and research perspectives.
Journal of Magnesium and Alloys,2023,11(2):425-461
|
CSCD被引
21
次
|
|
|
|
|
2.
叶健廷.
复合生物活性涂层3D打印多孔镁金属支架体外实验研究,2023
|
CSCD被引
1
次
|
|
|
|
|
3.
曹千卉. 镁合金电弧增材制造技术研究进展.
电焊机,2023,53(2):41-51
|
CSCD被引
1
次
|
|
|
|
|
4.
Ahmadi M. Review of selective laser melting of magnesium alloys: advantages, microstructure and mechanical characterizations, defects, challenges, and applications.
Journal of Materials Research and Technology,2022,19:1537-1562
|
CSCD被引
12
次
|
|
|
|
|
5.
李景利.
铸造高强耐热Mg-Gd-Y-Zr合金显微组织和力学行为研究,2019
|
CSCD被引
4
次
|
|
|
|
|
6.
Hou Y. Defect band formation in high pressure die casting AE44 magnesium alloy.
China Foundry,2022,19(3):201-210
|
CSCD被引
3
次
|
|
|
|
|
7.
Zhu S. Advanced additive remanufacturing technology.
Chinese Journal of Mechanical Engineering: Additive Manufacturing Frontiers,2023,2(1):100066
|
CSCD被引
4
次
|
|
|
|
|
8.
Roy R. Continuous maintenance and the future-foundations and technological challenges.
CIRP Annals-Manufacturing Technology,2016,65(2):667-688
|
CSCD被引
6
次
|
|
|
|
|
9.
Pidge A P. Additive manufacturing: a review on 3D printing of metals and study of residual stress, buckling load capacity of strut members.
Materials Today: Proceedings,2020,21(3):1689-1694
|
CSCD被引
4
次
|
|
|
|
|
10.
Chaudhary V. Additive manufacturing of functionally graded Co-Fe and Ni-Fe magnetic materials.
Journal of Alloys and Compounds,2020,823:153817
|
CSCD被引
6
次
|
|
|
|
|
11.
凤文桢.
镁粉尘的爆炸特性及抑爆研究,2021
|
CSCD被引
1
次
|
|
|
|
|
12.
Ma D. Study on anisotropy of microstructure and mechanical properties of AZ31 magnesium alloy fabricated by wire arc additive manufacturing.
China Foundry,2023,20(4):280-288
|
CSCD被引
1
次
|
|
|
|
|
13.
Shi X Z. Influence of ship-based vibration on characteristics of arc and droplet and morphology in wire arc additive manufacturing.
Chinese Journal of Mechanical Engineering:Additive Manufacturing Frontiers,2023,2(1):100067
|
CSCD被引
1
次
|
|
|
|
|
14.
朱科宇.
AZ91镁合金TIG电弧增材工艺及组织性能研究,2021
|
CSCD被引
1
次
|
|
|
|
|
15.
Cui X J. Wire oscillating laser additive manufacturing of 2319 aluminum alloy: optimization of process parameters, microstructure, and mechanical properties.
Chinese Journal of Mechanical Engineering: Additive Manufacturing Frontiers,2022,1(3):100035
|
CSCD被引
4
次
|
|
|
|
|
16.
Yi H. Achieving material diversity in wire arc additive manufacturing: leaping from alloys to composites via wire innovation.
International Journal of Machine Tools and Manufacture,2023,194:104103
|
CSCD被引
1
次
|
|
|
|
|
17.
赵淘. 基于自适应轮廓骨架分区的电弧增材制造成形路径优化方法.
焊接学报,2023,44(10):34-40
|
CSCD被引
1
次
|
|
|
|
|
18.
Fu Q. Research perspective and prospective of additive manufacturing of biodegradable magnesium-based materials.
Journal of Magnesium and Alloys,2023,11(5):1485-1504
|
CSCD被引
8
次
|
|
|
|
|
19.
郭靖.
镁合金电弧增材制造工艺参数的试验研究,2016
|
CSCD被引
4
次
|
|
|
|
|
20.
唐伟能. 增材制造镁合金技术现状与研究进展.
金属学报,2023,59(2):205-225
|
CSCD被引
4
次
|
|
|
|
|
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