超音速活性电弧制备锅炉用耐磨涂层性能研究

doi:10.13228/j.boyuan.issn1006-6543.20160096

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摘要以FeCrNiBSi丝材为喷涂材料，采用FlameArc超音速活性电弧喷涂系统在Q235钢为基体的工业锅炉用材料表面制备出结合强度高、耐磨性强的涂层；通过金相观察、拉伸试验、摩擦磨损试验，分别评价FeCrNiBSi涂层的孔隙率、显微硬度、结合强度和耐磨损性能；并通过扫描电子显微镜观察涂层微观形貌和磨损形貌。结果表明，涂层与基体结合良好，界面处未见任何分离，涂层结构比较致密，孔隙较少，孔隙率为0.71%，硬度为720 HV0.3，与基体结合强度达到60 MPa。相对于Q235钢，FeCrNiBSi涂层具有优异的抗磨损性能，其抗磨损性能是Q235钢的28倍。FeCrNiBSi涂层磨损机理为显微犁削和黏着磨损，耐磨性良好，具有良好的应用前景。

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关键词 ：超音速电弧喷涂, Q235, FeCrNiBSi, 工业锅炉, 磨损

Abstract：Using FeCrNiBSi wire as coating material， the coating with high bonding strength and strong wear resistance was prepared on the surface of the industrial boiler with supersonic active arc spraying system on Q235 steel substrate. The porosity， microhardness， bonding strength and wear resistance of FeCrNiBSi coating were evaluated by metallographic observation， tensile test， friction and wear test. The microstructure and wear morphology of the coating were also observed by scanning electron microscope. The results show that the coating has good adhesion to the substrate， no separation is found at the interface. The coating structure is relatively dense with porosity of 0.71% and hardness of 720 HV0.3. The bonding strength between the coating and the matrix is 60 MPa. Compared to Q235 steel， FeCrNiBSi coating has excellent wear resistance， which is 28 times that of Q235 steel. The wear mechanism of FeCrNiBSi coating is micro-ploughing and adhesive wear. The coating has good wear resistance and good application prospect.

Key words： supersonic arc spray system Q235 FeCrNiBSi industrial boiler

收稿日期: 2016-08-15 出版日期: 2018-02-27

通讯作者: 伏利 E-mail: fulitop@163.com

引用本文:

伏利，，陈小明，，刘伟，马红海，. 超音速活性电弧制备锅炉用耐磨涂层性能研究[J]. , 2018, 28(01): 34-37.
FU Li，，，CHEN Xiao-ming，，，LIU Wei，，MA Hong-hai，. Study on performance of wear-resistant coating for boiler with supersonic active arc spraying. , 2018, 28(01): 34-37.

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