| METALS AND METAL MATRIX COMPOSITES |
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| Study on Evolution Law of Microstructure of Cladding Layer by Laser Rescanning and Numerical Simulation |
| WANG Wei,SUN Wenlei, ZHANG Zhihu, YU Jiangtong, HUANG Haibo,WANG Yangxiao,XIAO Qi
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| School of Mechanical Engineering, Xinjiang University, Urumqi 830047, China |
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Abstract The aim is to study the influence of the laser rescanning process on the cladding layer structure (grain size and grain morphology) to determine the best laser rescanning power. In this work, the temperature field of laser cladding and laser rescanning was established and the thermal cycle curve of its key nodes was extracted. Combined with experimental verification, the effect of peak temperature and heat dissipation capacity on the microstructure growth of coating was analyzed. The results show that no matter in the stage of laser cladding or the laser rescanning, with the peak temperature and heat dissipation capacity gradually increasing along the molten pool center from the bonding zone to the top of the cladding layer, the coating microstructure gradually transits from planar crystal to cellular crystal, columnar cell crystal, dendrite and equiaxed crystal. With the increase of the laser rescanning power, the crystal grains of the cladding layer will grow thicker and larger, and the performance is particularly remarkable when the laser rescanning power is 1 200 W and 1 500 W. And if the rescanning power is too large, it will increase the melting of the substrate and the dilution rate of the coating. In contrast, when the laser rescanning power is 900 W, the crystal grains are relatively small and the increase of dilution ratio can be avoided. In addition, after the laser rescanning, the pores retained in the cladding layer can be released again. The unmelted powder particles on the surface of the cladding layer are fully melted, becoming more flat, smooth and full of metallic luster. The loose structure at the top of cladding layer is also significantly improved, which not only improves the quality of the coating, but also shortens the subsequent processing cycle, while also saving a certain amount of cladding materials.
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Published: 25 January 2022
Online: 2022-01-26
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| Fund:Xinjiang Karamay Major Project (2018ZD002B) and Open Foundation of Key Laboratory of the Autonomous Region (2020520002). |
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1 Jiang S S,Liang L S,Shu F Y. Materials Reports,2020,34(Z1),448(in Chinese).
蒋三生,梁立帅,舒凤远. 材料导报,2020,34(Z1),448.
2 Huang G K,Qu L D,Lu Y Z,et al. Vacuum,2018,153,39.
3 Liu J F, Li H L,Yu X Y,et al. Materials Protection,2014,47(6),69(in Chinese).
刘敬福,李赫亮,于小月,等. 材料保护,2014,47(6),69.
4 Shi J,Bai S Q,et al. Key Engineering Materials,2013,546,40.
5 Zhang Y,Han T F,Xiao M,et al. International Journal of Minerals Metallurgy and Materials,2020,27(5),630.
6 Tan J H,Sun R L,Niu W,et al. Materials Reports A:Review Papers,2020,34(8),15132(in Chinese).
谭金花,孙荣禄,牛伟,等. 材料导报:综述篇,2020,34(8),15132.
7 Yang D,Ning Y H,Zhao Y G,et al. Materials Reports B:Research Papers,2017,31(12),133(in Chinese).
杨丹,宁玉恒,赵宇光,等. 材料导报:研究篇,2017,31(12),133.
8 Wang Y Y,Chai L J,Wu L,et al. Journal of Chongqing University of Technology(Natural Science), 2020,34(9),159 (in Chinese).
王月圆,柴林江,吴璐,等.重庆理工大学学报(自然科学版),2020,34(9),159.
9 Gao W Y,Zhao S S,Wang Y B,et al. Surface & Coatings Technology,2015,270,16.
10 Gao W Y,Zhang Z Y,Zhao S S,et al. Surface & Coatings Technology,2016,291,423.
11 Dai D P,Jiang X H,Cai J P,et al. Chinese Journal of Lasers,2015,42(9),121(in Chinese).
戴德平,蒋小华,蔡建鹏, 等. 中国激光,2015,42(9),121.
12 Yang G,Wang W,Qin L Y,et al. Applied Mechanics and Materials,2012,117,1633.
13 Li M Y,Han B,Cai C B,et al. Transactions of the China Welding Institution,2015,36(5),25(in Chinese).
李美艳,韩 彬,蔡春波,等. 焊接学报,2015,36(5),25.
14 Li C,Yu Z B,Gao J X,et al. China Surface Engineering,2019,32(1),126(in Chinese).
李昌,于志斌,高敬翔,等. 中国表面工程,2019,32(1),126.
15 Wu D J,Wu N,Yang C,et al. Rare Metal Materials and Engineering,2013,42(10),2039(in Chinese).
吴东江,吴楠,杨策,等. 稀有金属材料与工程,2013,42(10),2039.
16 Zhao S J,Qi W J,Huang Y H,et al. Surface Technology,2020,49(2),301(in Chinese).
赵盛举,祁文军,黄艳华,等. 表面技术,2020,49(2),301.
17 Ren Z H,Wu M P,Cui C,et al. Chinese Journal of Lasers,2019,46(8),118(in Chinese).
任仲贺,武美萍,崔宸,等. 中国激光,2019,46(8),118.
18 Tian J Y,Xu P,Chen J H,et al. Optics and Lasers in Engineering,2019,122,97.
19 Zhang J,Yang L,Zhang W,et al. Optics and Lasers in Engineering,2020,126,105873.
20 Gao J L,Wu C Z,Hao Y B,et al. Optics and Laser Technology,2020,129,106287.
21 Song B X,Yu T B,Jiang X Y,et al. Numerical Heat Transfer,2020,78(2),48.
22 Yong Y W,Fu W,Deng Q L,et al. Journal of Manufacturing Processes,2017,28,364.
23 Gao W Y,Zhao S S,Wang Y B,et al. Materials and Design,2014,64,490.
24 Zhang D Q, Zhang J Q,Li J H. Machinery Design & Manufacture, 2016(5),122 (in Chinese).
张德强,张吉庆, 李金华,等. 机械设计与制造,2016(5),122.
25 Chen X, Chen B, Cheng X, et al. Journal of Iron and Steel Research International, 2020, 27(7), 842.
26 Yu Z Y, Zheng Y,Chen,J M,et al. Journal of Materials Processing Technology,2020,284(5),116738.
27 Zhou S S,Xu Y B,Liao Q,et al. Optics and Laser Technology,2018,103,8.
28 Li Y J,Dong S Y,Yan S X,et al. Optics and Laser Technology,2019,112,30.
29 Xiong A H,Ding J Q,Liu Y H,et al. Applied Laser,2019,39(3),381(in Chinese).
熊安辉,丁洁琼,刘延辉,等. 应用激光,2019,39(3),381.
30 Chen J,Li S H,Yan X F,et al. Hot Working Technology,2018,47(11),232(in Chinese).
陈晶,李少华,颜飞雪,等. 热加工工艺,2018,47(11),232.
31 Ding X F,Li X Z,Feng Q,et al. International Journal of Minerals Metallurgy and Materials,2017,24,884.
32 Chen J W,Xiong F Y,Huang C Y,et al. Scientia Sinica(Physica,Mechanica & Astronomica),2020,50(9),104(in Chinese).
陈嘉伟,熊飞宇,黄辰阳,等. 中国科学(物理学,力学,天文学),2020,50(9),104.
33 Wu D J, Wu N,Yang C,et al. Rare Metal Materials and Engineering, 2013,42(10),2039(in Chinese).
吴东江,吴楠,杨策,等. 稀有金属材料与工程,2013,42(10),2039.
34 Hu Z, Li W, Zhao Y. Materials, 2020, 13(8), 1867.
35 Yu T B,Song B X,Xi W C,et al. Laser Engineering,2019,44,11.
36 Zhao W,Zhang K,Liu P,et al. Journal of Functional Materials,2019,50(1),1098(in Chinese).
赵伟,张柯,刘平,等. 功能材料,2019,50(1),1098. |
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2022, Vol. 36 
