引用本文:黄奇胜,陈志国,魏祥,汪力,侯志伟,杨威.脉冲能量对电火花沉积Mo2FeB2基金属陶瓷涂层组织与性能的影响[J].中国表面工程,2017,30(3):89~96
HUANG Qi-sheng,CHEN Zhi-guo,WEI Xiang,WANG Li,HOU Zhi-wei,YANG Wei.Effects of Pulse Energy on Microstructure and Properties of Mo2FeB2-based Ceramet Coatings Prepared by Electro-spark Deposition[J].China Surface Engineering,2017,30(3):89~96
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脉冲能量对电火花沉积Mo2FeB2基金属陶瓷涂层组织与性能的影响
黄奇胜1, 陈志国1,2,3, 魏祥3, 汪力2, 侯志伟2, 杨威1
1.中南大学 材料科学与工程学院, 长沙 410083;2.湖南人文科技学院 材料工程系, 湖南 娄底 417000;3.中南大学 轻合金研究院, 长沙 410083
摘要:
为研究脉冲能量对电火花沉积制备Mo2FeB2基金属陶瓷涂层组织及性能的影响,在3种脉冲能量(1.35,6.41和17.81 J)下分别制备了沉积涂层。采用扫描电镜(SEM)、X射线衍射仪(XRD)、电子探针(EPMA)、显微硬度计及摩擦磨损实验机对涂层的组织与性能进行研究和表征。结果表明:3种脉冲能量所制备的涂层物相组成均由非晶相、马氏体和Fe3B相组成,脉冲能量17.81 J时涂层的非晶相含量最低;单个沉积点的溅射范围和涂层表面裂纹数随着脉冲能量的增大而增大,涂层厚度随脉冲能量增加到一定厚度后变化不显著;涂层与基体间形成良好的冶金结合。脉冲能量6.41 J时,涂层截面具有最高的峰值显微硬度1 349 HV0.05;同时,该涂层稳定阶段的摩擦因数(0.313)和1 h磨损量(0.7 mg)均为3种涂层中最低,耐磨性最佳。
关键词:  电火花沉积  脉冲能量  物相组成  微观形貌
DOI:10.11933/j.issn.1007-9289.20170106002
分类号:TG174.44
基金项目:湖南省应用基础研究重点项目(2016JC2007);湖南省自然科学基金(2017JJ31221)
Effects of Pulse Energy on Microstructure and Properties of Mo2FeB2-based Ceramet Coatings Prepared by Electro-spark Deposition
HUANG Qi-sheng1, CHEN Zhi-guo1,2,3, WEI Xiang3, WANG Li2, HOU Zhi-wei2, YANG Wei1
1.School of Materials Science and Engineering, Central South University, Changsha 410083;2.Department of Materials Engineering, Hunan University of Humanities, Science and Technology, Loudi 417000, Hunan;3.Light Alloy Research Institute, Central South University, Changsha 410083
Abstract:
In order to investigate the effects of pulse energy on microstructure and properties of Mo2FeB2-based ceramet coatings, three kinds of coatings were prepared under different pulse energy (1.35, 6.41 and 17.81 J) by electro-spark deposition.The microstructure and phase composition of the coatings were analyzed by XRD and SEM. Mircohardness test, friction and wear test were conducted for further investigation of their properties. The results show that all the coatings are consisted of amorphous, martensite and Fe3B. The content of amorphous phase is the lowest when the pulse energy is 17.81 J. The splash area of single spot and the quantity of cracks on the coatings surface increase with the pulse energy increasing, while the thickness variation is limited. Metallurgical bonding to the substrate is formed in all the coatings. The coating deposited at pulse energy of 6.41 J has a maximum peak microhardness of 1 395 HV0.05, the minimum mean friction coefficient (0.313) in the steady state and the minimum wear mass (0.7 mg) after 1 h of abrasion, indicating its better friction and wear performance.
Key words:  electro-spark deposition  pulse energy  phase content  micro morphology
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