Research on Present Situation of Quality Control and Performance Optimization of Thermal Spraying Coating Based on Remelting Technology

doi:10.3969/j.issn.1004-132X.2022.06.012

Abstract

Abstract: The research progresses of various remelting techniques to improve the quality of thermal spraying coatings in recent years were summarized. The following conclusions are obtained: laser remelting may obviously improve the quality of coatings by eliminating microcracks and unmelted particles in coatings， induction remelting may significantly reduce the porosity of coatings and enhance the mechanics properties of the coatings， and tungsten argon arc remelting can effectively improve the wear and corrosion resistance of coatings and improve the comprehensive properties of coatings. Electron beam remelting and flame remelting also improve the microstructure， microhardness and interfacial bonding strength of the coatings. Finally， the advantages and disadvantages of different remelting technologies were compared， and the development prospects of remelting technology were prospected.

Key words: , thermal spraying coating, remelting, wear resistance, corrosion resistance

摘要： 总结了近年来各种重熔技术改善热喷涂涂层质量的研究进展，得到如下结论：激光重熔通过消除涂层中微裂纹、未熔颗粒等缺陷明显改善涂层的质量；感应重熔可以显著降低涂层的孔隙率，增强涂层的力学性能；钨极氩弧重熔可以更有效地提高涂层的耐磨耐蚀性，提升涂层综合性能；电子束重熔、火焰重熔等对涂层的微观组织、显微硬度、界面结合强度也有一定的改善作用。最后分析对比了不同重熔技术的优缺点和适用范围，并对重熔技术的发展前景进行了展望。

关键词: 热喷涂涂层, 重熔, 耐磨损, 耐腐蚀

CLC Number:

TG17

HAN Bingyuan, , CHU Jiajie, ZHOU Kebing, ZHU Sheng. Research on Present Situation of Quality Control and Performance Optimization of Thermal Spraying Coating Based on Remelting Technology[J]. China Mechanical Engineering, 2022, 33(06): 727-739.

韩冰源, 楚佳杰, 周克兵, 朱胜. 基于重熔技术的热喷涂涂层质量调控与性能优化现状研究[J]. 中国机械工程, 2022, 33(06): 727-739.

References

［1］丁述宇，马国政，陈书赢，等.热喷涂成形过程热量累积行为与温度控制研究现状［J］. 材料导报， 2019， 33（21）：3644-3653.
DING Shuyu， MA Guozheng， CHEN Shuying， et al. Research Status of Heat Accumulation Behavior and Temperature Control in Thermal Spray Forming Process［J］. Materials Report， 2019， 33（21）：3644-3653.
［2］TEJERO M D， REZVANI R M， MCDONALD A， et al. Beyond Traditional Coatings：a Review on Thermal-sprayed Functional and Smart Coatings［J］. Journal of Thermal Spary Technology， 2019， 28（4）：598-644.
［3］MATIKAINEN V， RUBIO P S， OJALA N， et al. Erosion Wear Performance of WC-10Co4Cr and Cr3C2 -25NiCr Coatings Sprayed with High-velocity Thermal Spray Processes［J］. Surface & Coatings Technology， 2019， 370（5）：196-212.
［4］刘黎明，肖金坤，徐海峰，等. 热喷涂汽车发动机气缸内壁涂层的研究进展［J］. 表面技术， 2017， 46（2）：68-76.
LIU Liming， XIAO Jinkun， XU Haifeng， et al. Research Progress of Thermal Spraying Coating on Inner Wall of Automobile Engine Cylinder［J］. Surface Technology， 2017， 46（2）：68-76.
［5］SHUKLA R K， KUMAR A， KUMAR R， et al. Numerical Study of Pore Formation in Thermal Spray Coating Process by Investigating Dynamics of Air Entrapment［J］. Surface&Coatings Technology， 2019， 378（19）：2178-2218.
［6］周超极，朱胜，王晓明，等. 热喷涂涂层缺陷形成机理与组织结构调控研究概述［J］. 材料导报， 2018， 32（19）：3444-3455.
ZHOU Chaoji， ZHU Sheng， WANG Xiaoming， et al. Overview of Research on Defect Formation Mechanism and Microstructure Regulation of Thermal Sprayed Coatings［J］. Materials Report， 2018， 32（19）：3444-3455.
［7］SZALA M， WALCZAK M， ATKA L， et al. Cavitation Erosion and Sliding Wear of MCrAlY and NiCrMo Coatings Deposited by HVOF Thermal Spraying［J］. Advances in Materials Science， 2020， 20（2）：26-38.
［8］POLIARUS O， MORGIEL J， BOBROWSKI P， et al. Effect of Powder Preparation on the Microstructure and Wear of Plasma-sprayed NiAl/CrB2 Composite Coatings［J］. Journal of Thermal Spray Technology， 2019， 28（5）：1039-1048.
［9］刘明，陈书赢，马国政，等. 热喷涂涂层/基体异质界面结合强度优化理论与方法现状研究［J］. 机械工程学报， 2020， 56（10）：64-77.
LIU Ming， CHEN Shuying， MA Guozheng， et al. Research on Optimization Theory and Method of Bonding Strength between Thermal Sprayed Coating and Substrate［J］. Journal of Mechanical Engineering， 2020， 56（10）：64-77.
［10］KARIMI M R， SALIMIJAZI H R， GOLOZAR M A. Effects of Remelting Processes on Porosity of NiCrBSi Flame Sprayed Coatings［J］. Surface Engineering， 2016， 32（3）：238-243.
［11］HE Qungong， LI Linxu， GAO Zhenhuan， et al. Effect of Hot Isostatic Pressing on Microstructures and Mechanical Properties of IN738LC Superalloy［J］. Materials Science Forum， 2017， 898（1）：401-406.
［12］LI Wei， YAN Shisong， ZHANG Le. Effects of Surface Shot Peening Strengthening on Fatigue Property of TC11 Titanium Alloy［J］. Surface Technology， 2017， 46（3）：184-188.
［13］杨秀从，李国禄，王海斗，等. 热喷涂Ni基复合涂层重熔处理的研究现状［J］. 表面技术， 2016， 45（3）：64-71.
YANG Xiucong， LI Guolu， WANG Haidou， et al. Research Status of Remelting Treatment of Thermal Sprayed Ni Based Composite Coatings［J］. Surface Technology， 2016， 45（3）：64-71.
［14］XU Qingdong， LUO Yu， LIU Xiangdong， et al. Microstructural Evolution and Hardness of As-cast Be-Al-Sc-Zr Alloy Processed by Laser Surface Remelting［J］. Chinese Journal of Aeronautics， 2021， 34（8）：131-142.
［15］XU Lifeng， WANG Dongsheng. Grain Growth Characteristics of Plasma-sprayed Nanostructured Al2O3-13wt. %TiO2Coatings during Laser Remelt-ing［J］. Ceramics International， 2021， 47（11）：15052-15058.
［16］XIN Bo， REN Jiangyu， WANG Xiaoqi， et al. Effect of Laser Remelting on Cladding Layer of Inconel 718 Superalloy Formed by Laser Metal Deposition［J］. Materials， 2020， 13（21）：1-13.
［17］XU Mengkuo， ZHU Shigen， DING Hao. Electrical Contact Strengthening of Induction-clad Ni-40% WC Composite Coatings on 40Cr Substrates［J］. Surface & Coatings Technology， 2015， 279：32-38.
［18］CHEN Liangyu， WANG Haiyang， ZHAO Cuihua， et al. Automatic Remelting and Enhanced Mechanical Performance of a Plasma Sprayed NiCrBSi Coating［J］. Surface & Coatings Techno-logy， 2019， 369：31-43.
［19］杜辉辉，赵运才. 激光重熔喷涂涂层研究进展［J］. 激光与红外， 2018， 48（11）：1330-1336.
DU Huihui， ZHAO Yuncai. Research Progress of Laser Remelting Sprayed Coatings［J］. Laser and Infrared， 2018， 48（11）：1330-1336.
［20］KANG N， VERDY C， CODDET P， et al. Effects of Laser Remelting Process on the Microstructure， Roughness and Microhardness of In-situ Cold Sprayed Hypoeutectic Al-Si Coating［J］. Surface & Coatings Technology， 2017， 318：355-359.
［21］纪秀林，顾鹏，王振松，等. 激光重熔对电弧喷涂含非晶相铁基涂层性能的影响［J］. 表面技术， 2019， 48（4）：68-74.
JI Xiulin， GU Peng， WANG Zhensong， et al. Effect of Laser Remelting on the Properties of Arc Sprayed Iron-based Coatings Containing Amorphous Phase［J］. Surface Technology， 2019， 48（4）：68-74.
［22］赵运才，上官绪超，张继武，等. 激光重熔改性WC/Fe等离子喷涂涂层组织及其耐磨性能［J］. 表面技术， 2018， 47（3）：20-27.
ZHAO Yuncai， SHANGGUAN Xuchao， ZHANG Jiwu， et al. Microstructure and Wear Rresistance of WC/Fe Plasma Sprayed Coating Modified by Laser Remelting［J］. Surface Technology， 2018， 47（3）：20-27.
［23］YU Jianbing， WANG You， ZHOU Feifei， et al. Laser Remelting of Plasma-sprayed Nanostructured Al2O3-20wt.% ZrO2Coatings onto 316L Stainless Steel［J］. Applied Surface Science， 2018， 431（15）：112-121.
［24］WU Zhilin， WANG Wenqin， LI Xuewen， et al. Microstructure and Mechanical Properties of Ti-6Al-4V Prepared by Nickel Preplating and Electron Beam Surface Remelting［J］. Journal of Materials Processing Tech. ， 2019， 271：420-428.
［25］何文. 激光重熔工艺参数对喷涂Fe基Ni/WC涂层微观缺陷的抑制机制研究［D］. 赣州：江西理工大学， 2018.
HE Wen. Study on Inhibition Mechanism of Laser Remelting Process Parameters on Micro Defects of Sprayed Fe Based Ni/WC Coating［D］. Ganzhou：Jiangxi University of Technology， 2018.
［26］LIU Wenming， SHENG Tianyuan， KONG Dejun. Effects of Laser Remelting on Surface-interface Morphologies， Bonding Modes and Corrosion Performances of Arc-sprayed Al coating［J］. Anti-corrosion Methods and Materials， 2017， 64（1）：46-51.
［27］KE Yang， LI Jiaqi， WANG Qiuyu， et al. Effect of Laser Remelting on Microstructure and Wear Resistance of Plasma Sprayed Al2O3-40%TiO2Coating［J］. Wear， 2019， 426-427（Pt A）.
［28］盛忠起，周静，胡岚，等. 激光重熔高速电弧喷涂FeNiCrAl涂层的组织与断裂韧性［J］. 东北大学学报（自然科学版）， 2018， 39（4）：506-510.
SHENG Zhongqi， ZHOU Jing， HU Lan， et al. Microstructure and Fracture Toughness of Fenicral Coating by Laser Remelting High Speed Arc Spraying［J］. Journal of Northeast University（Natural Science Edition）， 2018， 39（4）：506-510.
［29］SUN Ze， ZHANG Donghui， YAN Baoxu， et al. Effects of Laser Remelting on Microstructures and Immersion Corrosion Performance of Arc Sprayed Al Coating in 3. 5% NaCl Solution［J］. Optics and Laser Technology， 2018， 99：282-290.
［30］DAS B， BANDYOPADHYAY P P， NATH A K. An Investigation on Corrosion Resistance and Mechanical Properties of Laser Remelted Flame Sprayed Coating［J］. Advances in Materials and Processing Technologies， 2018， 4（4）：660-668.
［31］杜辉辉，赵运才，黄丽容，等. 激光重熔轨迹对Fe基Ni/WC喷涂层摩擦学性能的影响［J］. 中国表面工程， 2018， 31（3）：152-160.
DU Huihui， ZHAO Yuncai， HUANG Lirong， et al. Effect of Laser Remelting Trajectory on Tribological Properties of Fe Based Ni/WC Sprayed Coatings［J］. China Surface Engineering， 2018， 31（3）：152-160.
［32］ZHANG Panpan， ZHANG Xiaofeng， LI Fuhai， et al. Hot Corrosion Behavior of YSZ Thermal Barrier Coatings Modified by Laser Remelting and Al Deposition［J］. Journal of Thermal Spray Technology， 2019， 28（6）：1225-1238.
［33］虞礼嘉，梁文萍，林浩，等. 激光重熔YSZ热障涂层950℃的热腐蚀行为［J］. 中国腐蚀与防护学报， 2019， 39（1）：77-82.
YU Lijia， LIANG Wenping， LIN Hao， et al. Thermal Corrosion Behavior of Laser Remelted YSZ Thermal Barrier Coating at 950 ℃［J］. Chinese Journal of Corrosion and Protection， 2019， 39（1）：77-82.
［34］孙文. 基于感应重熔温度场模拟的控制系统设计及改性Ni60涂层研究［D］. 北京：机械科学研究总院， 2019.
SUN Wen. Control System Design Based on Induction Remelting Temperature Field Simulation and Research on Modified Ni60 Coating［D］. Beijing：General Institute of Mechanical Sciences， 2019.
［35］万丽宁，董艳春，路项媛，等. 感应重熔对NiCrBSi/WC-Ni复合涂层组织和力学性能的影响［J］. 材料热处理学报， 2016， 37（12）：160-166.
WAN Lining， DONG Yanchun， LU Xiangyuan， et al. Effect of Induction Remelting on Microstructure and Mechanical Properties of NiCrBSi/ WC-Ni Composite Coating［J］. Journal of Material Heat Treatment， 2016， 37（12）：160-166.
［36］DONG Tianshun， LIU Li， LI Guolu， et al. Effect of Induction Remelting on Microstructure and Wear Resistance of Plasma Sprayed NiCrBSiNb Coatings［J］. Surface & Coatings Technology， 2019， 364：347-357.
［37］CHEN Jingbai， DONG Yanchun， WAN Lining， et al. Effect of Induction Remelting on the Microstructure and Properties of in Situ TiN-reinforced NiCrBSi Composite Coatings［J］. Surface & Coatings Technology， 2018， 340：159-166.
［38］张生欣，狄平，徐梦廓，等. 感应重熔-热处理对镍基碳化钨涂层的影响［J］. 中国表面工程， 2016， 29（1）：46-50.
ZHANG Shengxin， DI Ping， XU Mengkuo， et al. Effect of Induction Remelting Heat Treatment on Nickel Based Tungsten Carbide Coating［J］. China Surface Engineering， 2016， 29（1）：46-50.
［39］解芳，翟长生，王迎春，等. 等温淬火处理对感应重熔镍基合金涂层摩擦学性能的影响［J］. 表面技术， 2020， 49（4）：205-212.
XIE Fang， ZHAI Changsheng， WANG Yingchun， et al. Effect of Isothermal Quenching on Tribological Properties of Induction Remelted Nickel Base Alloy Coatings［J］. Surface Technology， 2020， 49（4）：205-212.
［40］赵锐，杨红军，于鹤龙，等. 高频感应重熔处理火焰喷涂NiCrBSi涂层的显微组织与力学性能［J］. 中国表面工程， 2016， 29（3）：65-73.
ZHAO Rui， YANG Hongjun， YU Helong， et al. Microstructure and Mechanical Properties of Flame Sprayed NiCrBSi Coating Treated by High Frequency Induction Remelting［J］. China Surface Engineering， 2016， 29（3）：65-73.
［41］DONG Tianshun， LIU Li， FU Binguo， et al. Investigation of Rolling/Sliding Contact Fatigue Behaviors of Induction Remelted Ni-based Coating［J］. Surface & Coatings Technology， 2019， 372：451-462.
［42］杨效田，王鹏春，李霞，等. 复合制备Ni基合金涂层的组织结构及性能演变特征［J］. 稀有金属材料与工程， 2017， 46（3）：693-698.
YANG Xiaotian， WANG Pengchun， LI Xia， et al. Microstructure and Property Evolution Characteristics of Ni Based Alloy Coating Prepared by Composite［J］. Rare Metal Materials and Engineering， 2017， 46（3）：693-698.
［43］LIANG Bu， ZHANG Zhenyu， GUO Hongjian. Comparison on the Microstructure and Wear Behaviour of Flame Sprayed Ni-based Alloy Coatings Remelted by Flame and Induction［J］. Transactions of the Indian Institute of Metals， 2017， 70（7）：1911-1919.
［44］VALEAN P C， KAZAMER N， MUNTEAN R， et al. Investigations on the Characteristics of Thermally Sprayed NiCrBSi Coatings Fused by Flame and Inductive Processing［J］. IOP Conference Series：Materials Science and Engineering， 2018， 416（1）：1-5.
［45］DONG Tianshun， ZHENG Xiaodong， LI Guolu， et al. Effect of Tungsten Inert Gas Remelting on Microstructure， Interface， and Wear Resistance of Fe-based Coating［J］. Journal of Engineering Materials and Technology， 2018， 140（4）：71-78.
［46］马力，张亚明. 金属及表面强化层氩弧重熔工艺研究进展［J］. 表面技术， 2016， 45（4）：218-225.
MA Li， ZHANG Yaming. Research Progress of Argon Arc Remelting Process of Metal and Surface Strengthening Layer［J］. Surface Technology， 2016， 45（4）：218-225.
［47］董天顺，李小兵，李国禄，等. 重熔对NiCrBSi涂层组织及高温耐磨性能的影响［J］. 表面技术， 2018， 47（8）：105-112.
DONG Tianshun， LI Xiaobing， LI Guolu， et al. Effect of Remelting on Microstructure and High Temperature Wear Resistance of NiCrBSi Coating［J］. Surface Technology， 2018， 47（8）：105-112.
［48］董天顺，郑晓东，李国禄，等. 大气等离子喷涂Fe基涂层及其氩弧重熔层的组织与力学性能［J］. 材料导报， 2019， 33（4）：679-683.
DONG Tianshun， ZHENG Xiaodong， LI Guolu， et al. Microstructure and Mechanical Properties of Atmospheric Plasma Sprayed Fe Based Coating and Its Argon Arc Remelting Layer［J］. Materials Report， 2019， 33（4）：679-683.
［49］DONG Tianshun， ZHENG Xiaodong， LI Yalong， et al. Microstructure and Wear Resistance of FeCrBSi Plasma-sprayed Coating Remelted by Gas Tungsten Arc Welding Process［J］. Journal of Materials Engineering and Performance， 2018， 27（8）：4069-4076.
［50］蹤雪梅，王井，员霄，等. 电弧喷涂Fe-Cr-B涂层的钨极氩弧重熔处理［J］. 中国表面工程， 2016， 29（5）：102-108.
ZONG Xuemei， WANG Jing， YUAN Xiao， et al. Tungsten Argon Arc Aemelting of Arc Sprayed Fe-Cr-B Coating［J］. China Surface Engineering， 2016， 29（5）：102-108.
［51］YUAN Jingmin， DONG Tianshun， FU Binguo， et al. Effect of Tungsten Inert Gas Arc Remelting on Microstructure and Wear Properties of Plasma-Sprayed NiCr-Cr3C2 Coating［J］. Journal of Materials Engineering and Performance， 2019， 28（10）：6320-6329.
［52］ZHU Lisong， CUI Yan， CAO Jinming， et al. Effect of TIG Remelting on Microstructure Corrosion and Wear Resistance of Coating on Surface of 4Cr5MoSiV1（AISI H13）［J］. Surface & Coatings Technology， 2021， 405（15）：547-550.
［53］GONG Zhuo， ZHANG Guodong， ZHENG Fei， et al. Performance of Different TIG Remelting Processes in Hypereutectic Al-Si Cast Alloy［J］. Engineering Research Express， 2019， 1（2）：1-8.
［54］董天顺，郑晓东，孟宏杰，等. Fe基氩弧重熔涂层的制备及其磨损性能研究［J］. 表面技术， 2018， 47（12）：155-165.
DONG Tianshun， ZHENG Xiaodong， MENG Hongjie， et al. Preparation and Wear Properties of Fe Based Argon Arc Remelting Coatings［J］. Surface Technology， 2018， 47（12）：155-165.
［55］陈松，董天顺，李国禄，等. 热喷涂层的重熔技术及其发展现状［J］. 焊接技术， 2016， 45（5）：76-79.
CHEN Song， DONG Tianshun， LI Guolu， et al. Remelting Technology of Thermal Spray Coating and Its Development Status［J］. Welding Technology， 2016， 45（5）：76-79.
［56］WU Yizhe， LIAO Weibing， WANG Fan， et al. Effect of Electron Beam Remelting Treatments on the Performances of Plasma Sprayed Zirconia Coatings［J］. Journal of Alloys and Compounds， 2018， 756（5）：33-39.
［57］LI Yulong， SONG Peng， WANG Wenqin， et al. Microstructure and Wear Resistance of a Ni-WC Composite Coating on Titanium Grade 2 Obtained by Electroplating and Electron Beam Rremelting［J］. Materials Characterization， 2020， 170：110674-110686.
［58］JUNG A， BUCHWALDER A， HEGELMANN E， et al. Surface Engineering of Spray-formed Aluminium-Silicon Alloys by Plasma Nitriding and Subsequent Electron Beam Remelting［J］. Surface & Coatings Technology， 2018， 335：166-172.
［59］方超，姚正军，张莎莎，等. 电子束重熔对机械合金化法制备TiC/Ti复合涂层组织及摩擦性能的影响［J］. 复合材料学报， 2019， 36（1）：167-177.
FANG Chao， YAO Zhengjun， ZHANG Shasha， et al. Effect of Electron Beam Remelting on Microstructure and Friction Properties of TiC / Ti Composite Coatings Prepared by Mechanical Alloying［J］. Journal of Composites， 2019， 36（1）：167-177.
［60］LIU Hailang， WANG Bo， QI Zhengwei， et al. Surface Microstructure and Anti-wear of WC-CoCr Coatings Cladded by Electron Beam［J］. Rare Metal Materials and Engineering， 2018， 47（11）：3338-3344.
［61］WANG Zhigang， YANG Jiahu， MA Yonghu， et al. Formation Mechanism of a Wrinkled and Textured Al2O3-ZrO2 Nanoeutectic Rapidly Solidified from Oxyacetylene Flame Remelting［J］. Journal of the American Ceramic Society， 2019， 102（1）：63-69.
［62］YANG Xinhui， LI Guolu， WANG Haidou， et al. Effect of Flame Remelting on Micro-structure and Wear Behaviour of Plasma Sprayed NiCrBSi-30%Mo Coating［J］.Surface Engineering， 2018， 34（3）：181-188.
［63］ZHANG Nannan， LIN Danying， ZHANG Guowei， et al. Effect of Oxyacetylene Flame Remelting on Wear Behaviour of Supersonic Air-plamsa Sprayed NiCrBSi/h-BN Composite Coatings［J］. Surface Review and Letters， 2017， 24（6）：917-924.
［64］DARAM P， BANJONGPRASERT C. The Influence of Post Treatments on the Microstructure and Corrosion Behavior of Thermally Sprayed NiCrMoAl Alloy Coating［J］. Surface & Coatings Technology， 2020， 384：1405-1446.
［65］史茜. 纳米等离子涂层制备—整体加热重熔及其点蚀特性研究［D］. 上海：上海大学， 2016.
SHI Qian. Preparation of Nano Plasma Coating-integral Heating Remelting and Pitting Characteristics［D］. Shanghai：Shanghai University， 2016.
［66］王韶云. 超音速等离子喷涂层接触疲劳性能及疲劳损伤机理研究［D］. 天津：河北工业大学， 2011.
WANG Shaoyun. Study on Contact Fatigue Performance and Fatigue Damage Mechanism of Supersonic Plasma Spraying Coating［D］. Tianjin：Hebei University of Technology， 2011.
［67］GHADAMI F， HEYDARZADEH S M， GHADAMI S. Effect of Bond Coat and Post-heat Treatment on the Adhesion of Air Plasma Sprayed WC-Co Coatings［J］. Surface & Coatings Technology， 2015， 261：289-294.
［68］叶秀，武美萍，缪小进，等. 激光重熔对Ti-6Al-4V选区激光熔化成形质量的影响［J］. 表面技术， 2021， 50（8）：301-310.
YE Xiu， WU Meiping， MIAO Xiaojin， et al. Effect of Laser Remelting on the Quality of Ti-6Al-4V Selective Laser Melting［J］. Surface Technology， 2021， 50（8）：301-310.
［69］SUN Fuzhen， LI Yan， TAN Wendan， et al. Effect of Laser Scanning Speed on the Thermal-mechanical Coupling Field of Laser Remelting of Valve Seat［J］. Optik， 2021， 225：165776-165789.
［70］吴勉，潘邻，童向阳，等. 感应重熔技术及其在现代工业中的应用［J］. 表面工程与再制造， 2017， 17（增刊1）：29-31.
WU Mian， PAN Lin， TONG Xiangyang， et al. Induction Remelting Technology and Its Application in Modern Industry［J］. Surface Engineering and Remanufacturing， 2017， 17（S1）：29-31.
［71］NIU Shaoqiang， YIN Kexin， YOU Qifan， et al. The Alloying Elements Dispersion and Its Mechanisms in a Ni-based Superalloy during Electron Beam Remelting［J］. Vacuum， 2019， 166（5）：107-113.
［72］BUCHAALDER A， ZENKER R. Pre- and Post-Surface Treatments Using Electron Beam Technology for Load-related Application of Thermochemical and PVD Hard Coatings on Soft Substrate Materials［J］. Surface & Coatings Technology， 2019， 375：920-932.
［73］PAREDES R S， NIKKEL W， SUCHARSKI G B， et al. Optimization of Arc-sprayed Iron-based Tungsten Carbide Hard Coatings on Harvester Blades［J］. Journal of the Brazilian Society of Mechanical Sciences and Engineering， 2019， 41（5）：1-9.
［74］李亚龙，董天顺，郑晓东，等. 热喷涂Ni基金属陶瓷层的重熔处理研究进展与展望［J］. 材料保护， 2018， 51（5）：111-114.
LI Yalong， DONG Tianshun， ZHENG Xiaodong， et al. Research Progress and Prospect of Remelting Treatment of Thermally Sprayed Ni Based Cermet Layers［J］. Material Protection， 2018， 51（5）：111-114.

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