激光熔覆涂层增韧改性方法的研究进展

doi:10.13251/j.issn.0254-6051.2023.06.041

摘要/Abstract

摘要： 激光熔覆涂层能够改善金属表面性能, 实现表面强化, 然而常发现由于涂层韧性降低, 涂层表面出现裂纹缺陷问题。概述了激光熔覆涂层由于韧性降低造成裂纹的原因, 包括温度梯度差引起的内应力、激光熔覆层中的应力集中以及熔覆层中的微小气孔等。同时归纳了影响激光熔覆层韧性的因素, 包括熔覆材料的选择、激光熔覆工艺参数的设定以及熔覆材料的热处理方式等。在此基础上, 重点阐述了近年来改善激光熔覆涂层裂纹缺陷问题的进展, 并从中寻找增强激光熔覆涂层韧性的方法, 包括在熔覆粉体中加入复合陶瓷增强相和稀土元素粉末等改变熔覆粉体组成、在基体与熔覆层之间增加过渡层、改变激光熔覆功率和扫描速率以及光斑直径等工艺参数、对熔覆前基体的预热和熔覆后涂层的热处理、外加超声振动和电磁场以及超声振动与电磁场的耦合等能场辅助等。针对各种增强激光熔覆涂层韧性方法的不足, 探讨今后激光熔覆涂层增韧改性方法的研究前景。

关键词: 激光熔覆, 涂层韧性, 裂纹, 增韧方法

Abstract: Laser cladding improves the performance of metal surfaces and achieves surface strengthening. However, it is often found that due to the reduced toughness of the coating, cracks and defects appear on the surface of the coating. The reasons for cracks in laser clad coatings due to reduced toughness are summarized, including internal stress caused by temperature gradient difference, stress concentration in laser clad layers, and small pores in clad layers. At the same time, factors affecting the toughness of laser clad layers are summarized, including the selection of clad materials, the setting of laser cladding process parameters, and the heat treatment methods of cladding materials. On this basis, the progress in improving the crack defects of laser clad coatings in recent years is emphasized, and methods to enhance the toughness of laser clad coatings are studied and searched for, including adding composite ceramic reinforcement phase and rare earth element powder to the cladding powder to change its composition, adding a transition layer between the substrate and the cladding layer, changing laser cladding process parameters such as the laser power, scanning rate, and spot diameter, preheating the substrate before cladding and heat treating the coating after cladding, external ultrasonic vibration and electromagnetic field, as well as coupling of ultrasonic vibration and electromagnetic field and other energy field assistance. Aiming at the shortcomings of various methods for enhancing the toughness of laser clad coatings, the research prospects of future methods for toughening and modifying laser clad coatings are explored.

Key words: laser cladding, coating toughness, cracks, toughening method

中图分类号:

TG174.4

魏新龙, 付二广, 戴凡昌, 班傲林, 吴多利, 张超. 激光熔覆涂层增韧改性方法的研究进展[J]. 金属热处理, 2023, 48(6): 237-248.

Wei Xinlong, Fu Erguang, Dai Fanchang, Ban Aolin, Wu Duoli, Zhang Chao. Research progress on toughening modification of laser clad coating[J]. Heat Treatment of Metals, 2023, 48(6): 237-248.

参考文献

[1]Cai Yangchuan, Chen Yao, Luo Zhen, et al. Manufacturing of FeCoCrNiCu_x medium-entropy alloy coating using laser cladding technology[J]. Materials & Design, 2017, 133(5): 91-108.
[2]高雪松, 田宗军, 沈理达, 等. 激光熔覆Al₂O₃-13%TiO₂陶瓷层制备及其抗热震性能[J]. 中国激光, 2012, 39(2): 85-90.
Gao Xuesong, Tian Zhongjun, Shen Lida, et al. Study on Al₂O₃-13%TiO₂ coatings prepared by laser cladding and thermal shock resistance[J]. Chinese Journal of Lasers, 2012, 39(2): 85-90.
[3]冯淑容, 张述泉, 王华明. 钛合金激光熔覆硬质颗粒增强金属间化合物复合涂层耐磨性[J]. 中国激光, 2012, 39(2): 60-65.
Feng Shurong, Zhang Shuquan, Wang Huaming. Wear resistance of laser clad hard particles reinforced intermetallic composite coating on TA15 alloy[J]. Chinese Journal of Lasers, 2012, 39(2): 60-65.
[4]李嘉宁, 巩水利, 王西昌, 等. TA15-2合金表面激光熔覆Ni基涂层物理与表面性能[J]. 中国激光, 2013, 40(11): 120-125.
Li Jianing, Gong Shuili, Wang Xichang, et al. Physical and surface performance of laser clad Ni based coating on a TA15-2 alloy[J]. Chinese Journal of Lasers, 2013, 40(11): 120-125.
[5]祝柏林, 胡木林, 陈俐, 等. 激光熔覆层开裂问题的研究现状[J]. 金属热处理, 2000, 25(7): 1-4.
Zhu Bolin, Hu Mulin, Chen Li, et al. Research status of cracking in laser cladding layer[J]. Heat Treatment of Metals, 2000, 25(7): 1-4.
[6]张坚, 吴文妮, 赵龙志. 激光熔覆研究现状及发展趋势[J]. 热加工工艺, 2013, 42(6): 131-134, 139.
Zhang Jian, Wu Wenni, Zhao Longzhi, et al. Research progress and development trend of laser cladding[J]. Hot Working Technology, 2013, 42(6): 131-134, 139.
[7]刘海青, 葛超, 王志文, 等. 激光熔覆复合涂层裂纹控制研究进展[J]. 金属热处理, 2018, 43(8): 228-232.
Liu Haiqing, Ge Chao, Wang Zhiwen, et al. Research progress on crack control of laser clad composite coating[J]. Heat Treatment of Metals, 2018, 43(8): 228-232.
[8]Ebrahimnia M, Malek G F, Gholizade S, et al. Effect of cooling rate and powder characteristics on the soundness of heat affected zone in powder welding of ductile cast iron[J]. Materials and Design, 2012, 33: 551-556.
[9]钟敏霖, 刘文今. Stellite和NiCrSiB合金激光送粉熔覆裂纹倾向的比较研究[J]. 中国激光, 2002, 29(11): 1031-1036.
Zhong Minlin, Liu Wenjin. Comparative research on cracking tendency in power feeding laser cladding Stellite and NiCrSiB alloys[J]. Chinese Journal of Lasers, 2002, 29(11): 1031-1036.
[10]Wang Dongsheng, Liang Erjun, Chao Mingju, et al. Investigation on the microstructure and cracking susceptibility of laser-clad V₂O₅/NiCrBSi Calloy coatings[J]. Surface and Coatings Technology, 2008, 202(8): 1371-1378.
[11]杨伟, 曾大新, 刘建永, 等. 激光熔覆H13钢的裂纹敏感性及形成机理[J]. 金属热处理, 2020, 45(6): 206-211.
Yang Wei, Zeng Daxin, Liu Jianyong, et al. Crack sensitivity and formation mechanism of laser clad H13 steel[J]. Heat Treatment of Metals, 2020, 45(6): 206-211.
[12]余廷, 邓琦林, 张伟, 等. 激光熔覆NiCrBSi合金涂层的裂纹形成机理[J]. 上海交通大学学报, 2012, 46(7): 1043-1048.
Yu Ting, Deng Qilin, Zhang Wei, et al. Study on cracking mechanism of laser clad NiCrBSi coating[J]. Journal of Shanghai Jiaotong University, 2012, 46(7): 1043-1048.
[13]Xu P Y, Liu Y C, Yi P, et al. Research on variation and stress status of graphite in laser cladding process of grey cast iron[J]. Materials Science and Technology, 2014, 30(14): 1728-1734.
[14]罗西希. 激光熔覆铁铝基涂层的制备及其增韧和抗磨机理研究[D]. 南京: 南京航空航天大学, 2018.
Luo Xixi. Preparation of Fe-Al based laser cladding coating and its toughening and anti-wearing mechanism[D]. Nanjing: Nanjing University of Aeronautics and Astronautics, 2018.
[15]刘贵仲, 钟文华, 高原. 激光熔覆涂层缺陷的形成及防治[J]. 表面技术, 2012, 41(5): 89-92.
Liu Guizhong, Zhong Wenhua, Gao Yuan. Formation and resolving method of the structure defect about laser cladding coatings[J]. Surface Technology, 2012, 41(5): 89-92.
[16]Smurov Igor. Laser cladding and laser assisted direct manufacturing[J]. Surface & Coatings Technology, 2008, 202(18): 4496-4502.
[17]Wu Xinhua, Liang Jing, Mei Junfa, et al. Microstructures of laser-deposited Ti-6Al-4V[J]. Materials & Design, 2004, 25(2): 137-144.
[18]王伟, 孙文磊, 周浩南, 等. 激光熔覆镍基合金涂层裂纹形成机理及匹配方法的研究[J]. 热加工工艺, 2022, 51(14): 83-88.
Wang Wei, Sun Wenlei, Zhou Haonan, et al. Study on crack formation mechanism and matching method of laser cladding nickel-based alloy coating[J]. Hot Working Technology, 2022, 51(14): 83-88.
[19]郑启池, 金亚娟, 李瑞峰, 等. 功率输入对激光熔覆镍基涂层组织和裂纹生成的影响[J]. 江苏科技大学学报(自然科学版), 2017, 31(3): 293-297.
Zheng Qichi, Jin Yajuan, Li Ruifeng, et al. Effect of power input on microstructure and crack formation of Ni based coating by laser cladding[J]. Journal of Jiangsu University of Science and Technology (Natural Science Edition), 2017, 31(3): 293-297.
[20]李洪玉, 魏连峰, 王泽明, 等. 预热温度对激光熔覆层组织和应力的影响[J]. 激光与光电子学进展, 2021, 58(7): 249-257.
Li Hongyu, Wei Lianfeng, Wang Zeming, et al. Effect of preheating temperature on microstructure and stress of laser cladding layer[J]. Laser & Optoelectronics Progress, 2021, 58(7): 249-257.
[21]Inoue A, Shen B L, Yavari A R, et al. Mechanical properties of Fe-based bulk glassy alloys in Fe-B-Si-Nb and Fe-Ga-P-C-B-Si systems[J]. Journal of Materials Research, 2003, 18(6): 1487-1492.
[22]Shen L Q, Luo P, Hu Y C, et al. Shear-band affected zone revealed by magnetic domains in a ferromagnetic metallic glass[J]. Nature Communications, 2018, 9(1): 1-9.
[23]Cheng Jiangbo, Liang Xiubing, Wu Yixiong, et al. Microstructure and wear behavior of FeBSiNbCr metallic glass coatings[J]. Journal of Materials Science & Technology, 2009, 25(5): 687-690.
[24]Qiao Jianghao, Jin Xin, Qin Jiahao, et al. A super-hard superhydrophobic Fe-based amorphous alloy coating[J]. Surface & Coatings Technology, 2018, 334: 286-291.
[25]王天聪, 朱彦彦, 姚成武, 等. 激光熔覆碳纳米管增韧铁基非晶涂层的组织与力学性能[J]. 机械工程材料, 2020, 44(5): 54-59, 65.
Wang Tiancong, Zhu Yanyan, Yao Chengwu, et al. Microstructure and mechanical properties of laser cladding carbon nanotubes toughened Fe-based amorphous coating[J]. Materials for Mechanical Engineering, 2020, 44(5): 54-59, 65.
[26]Luo Xixi, Yao Zhengjun, Zhang Pingze, et al. Al₂O₃ nanoparticles reinforced Fe-Al laser cladding coatings with enhanced mechanical properties[J]. Journal of Alloys and Compounds, 2018, 755: 41-54.
[27]闫洪, 窦明民, 李和平. 二氧化锆陶瓷的相变增韧机理和应用[J]. 陶瓷学报, 2000, 21(1): 46-50.
Yan Hong, Dou Mingmin, Li Heping. Transformation toughening mechanisms and application of ZrO₂ ceramics[J]. Journal of Ceramics, 2000, 21(1): 46-50.
[28]张三川, 姚建铨. 氧化锆掺杂激光熔覆涂层成形、结构与增韧机制[J]. 激光杂志, 2007, 28(2): 73-74.
Zhang Sanchuan, Yao Jianquan. Study on the forming structure and toughening mechanism of coating intermingled with ZrO₂ by laser cladding[J]. Laser Journal, 2007, 28(2): 73-74.
[29]张维平, 路董华, 余娟娟, 等. 氧化锆增韧机制在激光熔覆技术中的应用[J]. 中国激光, 2014, 41(11): 90-94.
Zhang Weiping, Lu Donghua, Yu Juanjuan, et al. Application of Zirconia toughening mechanism on laser cladding[J]. Chinese Journal of Lasers, 2014, 41(11): 90-94.
[30]邝海, 谭敦强, 何文, 等. 稀土元素对硬质合金影响的研究进展[J]. 稀有金属与硬质合金, 2018, 46(3): 69-74.
Kuang Hai, Tan Dunqiang, He Wen, et al. Research progress on the effects of rare earth elements on cemented carbides[J]. Rare Metals and Cemented Carbides, 2018, 46(3): 69-74.
[31]钟文华, 刘贵仲, 潘洁宗, 等. Y₂O₃对镍基碳化铬激光熔覆层结构性能的影响[J]. 材料热处理学报, 2013, 34(2): 147-151.
Zhong Wenhua, Liu Guizhong, Pan Jiezong, et al. Effect of Y₂O₃ on structure and properties of Ni/Cr₃C₂ cladding layer[J]. Transactions of Materials and Heat Treatment, 2013, 34(2): 147-151.
[32]王成磊, 张光耀, 高原, 等. Y₂O₃在6063铝合金表面激光熔覆Ni基熔覆层中的作用机制[J]. 稀有金属, 2016, 40(3): 201-206.
Wang Chenglei, Zhang Guangyao, Gao Yuan, et al. Mechanism of Y₂O₃ affecting laser cladding of Ni-based coating on 6063 Al alloy substrate[J]. Chinese Journal of Rare Metals, 2016, 40(3): 201-206.
[33]匡建新, 汪新衡, 朱航生. La₂O₃对激光熔覆镍基碳化钛复合涂层组织和耐腐蚀性能的影响[J]. 热加工工艺, 2011, 40(2): 118-120.
Kuang Jianxin, Wang Xinheng, Zhu Hangsheng. Effect of La₂O₃ on microstructure and corrosion resistance of Ni/TiC composite coating prepared by laser cladding[J]. Hot Working Technology, 2011, 40(2): 118-120.
[34]王成磊, 高原, 张光耀. CeO₂对铝合金表面激光熔覆增材制造Ni60合金层组织及耐蚀性影响[J]. 稀有金属材料与工程, 2017, 46(8): 2306-2312.
Wang Chenglei, Gao Yuan, Zhang Guangyao. Effect of CeO₂ addition on interface structure and corrosion resistance of laser cladding additive manufactured Ni60 alloy layers on the surface of Al alloys[J]. Rare Metal Materials and Engineering, 2017, 46(8): 2306-2312.
[35]陈顺高, 张晓明, 郑启池, 等. CeO₂对激光熔覆Ni60合金涂层组织及性能的影响[J]. 激光技术, 2017, 41(6): 904-908.
Chen Shungao, Zhang Xiaoming, Zheng Qichi, et al. Effect of CeO₂ on microstructure and properties of Ni60 alloy coating by laser cladding[J]. Laser Technology, 2017, 41(6): 904-908.
[36]陈传忠, 王文中, 曹怀华, 等. 激光熔覆Al₂O₃-NiCrAl层的脆性及摩擦磨损特性[J]. 中国激光, 1999, 26(9): 841-846.
Chen Chuanzhong, Wang Wenzhong, Cao Huaihua, et al. Brittleness and tribological characteristics of Al₂O₃ ceramic coatings cladding by laser on W18Cr4V steel[J]. Chinese Journal of Lasers, 1999, 26(9): 841-846.
[37]沈大臣, 叶宏, 汪砚青, 等. Cr12MoV钢表面激光熔覆多层Ni基合金涂层的组织及性能[J]. 金属热处理, 2020, 45(12): 169-174.
Shen Dachen, Ye Hong, Wang Yanqing, et al. Microstructure and properties of laser clad multi-layer Ni-based coating on Cr12MoV steel surface[J]. Heat Treatment of Metals, 2020, 45(12): 169-174.
[38]范鹏飞, 孙文磊, 张冠, 等. 激光熔覆铁基合金梯度涂层的组织性能及应用[J]. 材料导报, 2019, 33(22): 3806-3810.
Fan Pengfei, Sun Wenlei, Zhang Guan, et al. Microstructure, properties and applications of laser cladding Fe-based alloy gradient coatings[J]. Materials Reports, 2019, 33(22): 3806-3810.
[39]Wang Fujun, Mao Huaidong, Zhang Dawei, et al. The crack control during laser cladding by adding the stainless steel net in the coating[J]. Applied Surface Science, 2009, 255(21): 8846-8854.
[40]Khalili Arman, Goodarzi Massoud, Mojtahedi Milad, et al. Solidification microstructure of in-situ laser-synthesized Fe-TiC hard coating[J]. Surface and Coatings Technology, 2016, 307: 747-752.
[41]童文辉, 张新元, 李为轩, 等. 激光工艺参数对TiC增强钴基合金激光熔覆层组织及性能的影响[J]. 金属学报, 2020, 56(9): 1265-1274.
Tong Wenhui, Zhang Xinyuan, Li Weixuan, et al. Effect of laser process parameters on the microstructure and properties of TiC reinforced Co-based alloy laser cladding layer[J]. Acta Metallurgica Sinica, 2020, 56(9): 1265-1274.
[42]赵栓峰, 郭颖潇, 柴蓉霞, 等. 扫描速度对激光熔覆铁基合金的组织与性能影响研究[J]. 应用激光, 2020, 40(5): 811-820.
Zhao Shuanfeng, Guo Yingxiao, Chai Rongxia, et al. Research on the effect of scanning speed on microstructure and properties of laser cladding the Fe-base alloy[J]. Applied Laser, 2020, 40(5): 811-820.
[43]易湘斌, 梁泽芬, 郭小汝, 等. 扫描速度对不锈钢激光熔覆铁基合金涂层组织与性能的影响[J]. 热处理技术与装备, 2017, 38(6): 7-11.
Yi Xiangbin, Liang Zefen, Guo Xiaoru, et al. Effect of scanning speed on microstructure and properties of laser cladding Fe based alloy coating on stainless steel[J]. Heat Treatment Technology and Equipment, 2017, 38(6): 7-11.
[44]谭金花, 孙荣禄, 牛伟, 等. 激光扫描速度对TC4合金表面激光熔覆复合涂层组织及性能的影响[J]. 材料导报, 2020, 34(12): 12094-12100.
Tan Jinhua, Sun Ronglu, Niu Wei, et al. Effect of laser scanning speed on microstructure and properties of TC4 alloy surface laser cladding composite coating[J]. Materials Reports, 2020, 34(12): 12094-12100.
[45]韩基泰, 武美萍, 崔宸. 激光功率对42CrMo钢激光熔覆层组织和摩擦磨损性能的影响[J]. 金属热处理, 2020, 45(11): 214-217.
Han Jitai, Wu Meiping, Cui Chen. Effect of laser power on microstructure and friction and wear properties of laser clad layer on 42CrMo steel[J]. Heat Treatment of Metals, 2020, 45(11): 214-217.
[46]Fu Fuxing, Zhang Yanli, Chang Gengrong, et al. Analysis on the physical mechanism of laser cladding crack and its influence factors[J]. Optik-International Journal for Light and Electron Optics, 2016, 127(1): 200-202.
[47]于希辰, 王志文, 刘海青, 等. 后热处理对激光熔覆涂层应用的研究进展[J]. 金属热处理, 2019, 44(3): 114-119.
Yu Xichen, Wang Zhiwen, Liu Haiqing, et al. Research progress of application of post heat-treatment on laser cladded coatings[J]. Heat Treatment of Metals, 2019, 44(3): 114-119.
[48]李美艳, 蔡春波, 韩彬, 等. 预热对激光熔覆陶瓷涂层温度场和应力场影响[J]. 材料热处理学报, 2015, 36(12): 197-203.
Li Meiyan, Cai Chunbo, Han Bin, et al. Numerical simulation of preheating on temperature and stress fields by laser cladding Ni-based ceramic coating[J]. Transactions of Materials and Heat Treatment, 2015, 36(12): 197-203.
[49]姚永强. 真空环境与基体预热对激光熔覆Ni基WC涂层性能及缺陷改善的研究[D]. 青岛: 青岛理工大学, 2019.
Yao Yongqiang. Study on performance and defects improvement of laser cladding Ni-based WC coating by vacuum environment and matrix preheating[D]. Qingdao: Qingdao University of Technology, 2019.
[50]吴祖鹏, 李涛, 李向波. 复合工艺参数对激光熔覆Ni60A合金裂纹的影响[J]. 应用激光, 2019, 39(5): 765-769.
Wu Zupeng, Li Tao, Li Xiangbo. Effect of hybrid process parameters on crack behavior of laser cladding Ni60A alloy[J]. Applied Laser, 2019, 39(5): 765-769.
[51]Liu Xiubo, Liu Haiqing, Meng Xiangjun, et al. Effects of aging treatment on microstructure and tribological properties of nickel-based high-temperature self-lubrication wear resistant composite coatings by laser cladding[J]. Materials Chemistry and Physics, 2014, 143(2): 616-621.
[52]张尧成, 黄希望, 杨莉, 等. 热处理前后镍基高温合金激光熔覆层的组织和力学性能[J]. 机械工程材料, 2016, 40(11): 22-26, 30.
Zhang Yaocheng, Huang Xiwang, Yang Li, et al. Microstructure and mechanical properties of laser cladded Ni-based superalloy coating before and after heat treatment[J]. Materials for Mechanical Engineering, 2016, 40(11): 22-26, 30.
[53]Taposh Roy, Ralph Abrahams, Anna Paradowska, et al. Evaluation of the mechanical properties of laser cladded hypereutectoid steel rails[J]. Wear, 2019, 432-433(2): 202930.
[54]崔宸, 武美萍, 夏思海. 热处理对42CrMo钢表面激光熔覆钴基涂层性能的影响[J]. 中国激光, 2020, 47(6): 154-161.
Cui Chen, Wu Meiping, Xia Sihai. Effect of heat treatment on properties of laser cladding cobalt-based coating on 42CrMo steel surface[J]. Chinese Journal of Lasers, 2020, 47(6): 154-161.
[55]李丽, 孙峰, 张尧成. 固溶处理对激光熔覆Stellite6合金涂层性能的影响[J]. 表面技术, 2017, 46(1): 78-81.
Li Li, Sun Feng, Zhang Yaocheng. Effect of solution treatment on the performance of laser cladding of Stellite6 alloy coating[J]. Surface Technology, 2017, 46(1): 78-81.
[56]陆小龙, 刘秀波, 余鹏程, 等. 后热处理对304不锈钢激光熔覆Ni60/h-BN自润滑耐磨复合涂层组织和摩擦学性能的影响[J]. 摩擦学学报, 2016, 36(1): 48-54.
Lu Xiaolong, Liu Xiubo, Yu Pengcheng, et al. Effects of post heat-treatment on microstructure and tribological properties of Ni60/H-BN self-lubricating anti-wear composite coating on 304 stainless steel by laser cladding[J]. Tribology, 2016, 36(1): 48-54.
[57]邓德伟, 马云波, 马玉山, 等. 重熔及退火对316L不锈钢激光熔覆层残余应力的影响[J]. 金属热处理, 2020, 45(8): 113-118.
Deng Dewei, Ma Yunbo, Ma Yushan, et al. Influence of remelting and annealing on residual stress of 316L stainless steel laser clad layer[J]. Heat Treatment of Metals, 2020, 45(8): 113-118.
[58]张蕾涛, 李海涛, 贾润楠, 等. 激光重熔Ni60/50%WC复合涂层的制备及性能[J]. 金属热处理, 2021, 46(5): 229-234.
Zhang Leitao, Li Haitao, Jia Runnan, et al. Preparation and properties of laser remelted Ni60/50%WC composite coating[J]. Heat Treatment of Metals, 2021, 46(5): 229-234.
[59]Lu Yunzhuo, Huang Guokun, Wang Yongzhe, et al. Crack-free Fe-based amorphous coating synthesized by laser cladding[J]. Materials Letters, 2018, 210: 46-50.
[60]Liu Hongxi, Xu Qian, Wang Chuanqi, et al. Corrosion and wear behavior of Ni60CuMoW coatings fabricated by combination of laser cladding and mechanical vibration processing[J]. Journal of Alloys and Compounds, 2015, 621: 357-363.
[61]Foroozmehr Ehsan, Lin Dechao, Kovacevic Radovan. Application of vibration in the laser powder deposition process[J]. Journal of Manufacturing Processes, 2009, 11(1): 38-44.
[62]沈言锦, 李雪丰, 唐利平. 超声功率对激光熔覆WC强化Fe基复合涂层组织与性能的影响[J]. 金属热处理, 2018, 43(5): 168-172.
Shen Yanjin, Li Xuefeng, Tang Liping. Effect of ultrasonic power on microstructure and properties of laser-clad WC strengthened Fe-based composite coating[J]. Heat Treatment of Metals, 2018, 43(5): 168-172.
[63]王冉, 王玉玲, 姜芙林, 等. 超声辅助激光熔覆技术研究现状[J]. 工具技术, 2020, 54(8): 3-9.
Wang Ran, Wang Yuling, Jiang Fulin, et al. Research status of ultrasonic assisted laser cladding technology[J]. Tool Engineering, 2020, 54(8): 3-9.
[64]Ma G, Yan S, Wu D, et al. Microstructure evolution and mechanical properties of ultrasonic assisted laser clad yttria stabilized zirconia coating[J]. Ceramics International, 2017, 43(13): 9622-9629.
[65]李洋. 超声振动辅助激光熔覆制备TiC/FeAl原位涂层研究[D]. 上海: 华东交通大学, 2016.
Li Yang. Investigation on in-situ TiC/FeAl coating prepared with ultrasonic vibration aided laser cladding technology[D]. Shanghai: East China Jiaotong University, 2016.
[66]Yan Shuai, Wu Dongjiang, Niu Fangyong, et al. Al₂O₃-ZrO₂ eutectic ceramic via ultrasonic-assisted laser engineered net shaping[J]. Ceramics International, 2017, 43(17): 15905-15910.
[67]钦兰云, 王维, 杨光. 超声辅助钛合金激光沉积成形试验研究[J]. 中国激光, 2013, 40(1): 82-87.
Qin Lanyun, Wang Wei, Yang Guang. Experimental study on ultrasonic-assisted laser metal deposition of titanium alloy[J]. Chinese Journal of Lasers, 2013, 40(1): 82-87.
[68]李德英, 赵龙志, 张坚, 等. 超声振动对激光熔覆TiC/FeAl复合涂层温度场的影响[J]. 金属热处理, 2015, 40(3): 190-194.
Li Deying, Zhao Longzhi, Zhang Jian, et al. Influence of ultrasonic vibration on temperature field of TiC/FeAl composite coating in laser cladding[J]. Heat Treatment of Metals, 2015, 40(3): 190-194.
[69]Zhang Nan, Liu Weiwei, Deng Dewei, et al. Effect of electric-magnetic compound field on the pore distribution in laser cladding process[J]. Optics and Laser Technology, 2018, 108: 247-254.
[70]Zhu Kuisong, Ma Wenhui, Wei Kuixian, et al. Separation mechanism of TiSi₂ crystals from a Ti-Si eutectic alloy via directional solidification[J]. Journal of Alloys & Compounds, 2018, 750: 102-110.
[71]Chen Jicheng, Wei Yanhong, Zhan Xiaohong, et al. Melt flow and thermal transfer during magnetically supported laser beam welding of thick aluminum alloy plates[J]. Journal of Materials Processing Technology, 2018, 254: 325-337.
[72]Velde O, Gritzki R, Grundmann R. Numerical investigations of Lorentz force influenced Marangoni convection relevant to aluminum surface alloying[J]. International Journal of Heat and Mass Transfer, 2001, 44(14): 2751-2762.
[73]余本海, 胡雪惠, 吴玉娥, 等. 电磁搅拌对激光熔覆WC-Co基合金涂层的组织结构和硬度的影响及机理研究[J]. 中国激光, 2010, 37(10): 2672-2677.
Yu Benhai, Hu Xuehui, Wu Yue, et al. Studies of the effects and mechanism of electromagnetic stirring on the microstructures and hardness of laser cladding WC-Co based alloy coating[J]. Chinese Journal of Lasers, 2010, 37(10): 2672-2677.
[74]林英华, 袁莹, 王梁, 等. 电磁复合场对Ni60合金凝固过程中显微组织和裂纹的影响[J]. 金属学报, 2018, 54(10): 1442-1450.
Lin Yinghua, Yuan Ying, Wang Liang, et al. Effect of electric-magnetic compound field on the microstructure and crack in solidified Ni60 alloy[J]. Acta Metallurgica Sinica, 2018, 54(10): 1442-1450.
[75]胡勇, 王梁, 李珏辉, 等. 定向洛伦兹力对激光熔覆熔池排气的影响[J]. 中国激光, 2018, 45(8): 56-65.
Hu Yong, Wang Liang, Li Juehui, et al. Effect of directional Lorentz force on molten pool exhaust in laser cladding[J]. Chinese Journal of Lasers, 2018, 45(8): 56-65.
[76]曹阳, 姚宏凯, 吴国庆, 等. 磁场辅助激光熔覆5CrNiMo/Ni60涂层组织微结构及性能研究[J]. 南通大学学报, 2020, 19(4): 57-62.
Cao Yang, Yao Hongkai, Wu Guoqing, et al. Study on microstructure and properties of magnetic field assisted laser cladding 5CrNiMo/Ni60 coating[J]. Journal of Nantong University, 2020, 19(4): 57-62.
[77]蔡川雄, 刘洪喜, 蒋业华, 等. 交变磁场对激光熔覆Fe基复合涂层组织结构及其耐磨性的影响[J]. 摩擦学学报, 2013, 33(3): 229-235.
Cai Chuanxiong, Liu Hongxi, Jiang Yehua, et al. Influence of AC magnetic field on microstructure and wear behaviors of laser cladding Fe-based composite coating[J]. Tribology, 2013, 33(3): 229-235.
[78]Bachmann M, Avilov V, Gumenyuk A, et al. Numerical assessment and experimental verification of the influence of the Hartmann effect in laser beam welding processes by steady magnetic fields[J]. International Journal of Thermal Sciences, 2016, 101: 24-34.
[79]杨光, 薛雄, 钦兰云, 等. 旋转磁场对激光熔凝钛合金熔池的影响[J]. 稀有金属材料与工程, 2016, 45(7): 1804-1810.
Yang Guang, Xue Xiong, Qin Lanyun, et al. Influence of a rotating magnetic field on laser melting titanium alloy melt pool[J]. Rare Metal Materials and Engineering, 2016, 45(7): 1804-1810.
[80]徐家乐. 电磁超声复合能场辅助激光熔覆钴基合金涂层组织及性能研究[D]. 镇江: 江苏大学, 2019.
Xu Jiale. Study on microstructure and properties of Co-based coatings by laser cladding coupled with electromagnetic/ultrasonic compound energy field[D]. Zhenjiang: Jiangsu University, 2019.