目的:改善Q235钢板的耐磨性,以取代65 Mn在振动筛筛板中的应用。方法采用电阻丝加热非真空熔覆技术,在氩气保护条件下于Q235钢表面制备碳化钨/镍基合金复合熔覆层。通过SEM 和XRD观察分析熔覆层与基体的结合方式、碳化钨分布、熔覆层组织及相组成,通过硬度测试及磨损试验,分析碳化钨对熔覆层耐磨性的影响。结果熔覆层与钢基体达到冶金结合。熔覆层主要由奥氏体、碳化钨、碳化物及硼碳复合化合物等相组成,碳化钨弥散分布其中。当碳化钨用量为熔覆粉末总质量的35%时,熔覆层硬度为47.3HRC,磨损率为0.08 mg/m,约是钢基体耐磨性的5倍,65Mn耐磨性的4倍。结论采用氩气保护制备的碳化钨熔覆层与基体结合良好,提高了钢基体的耐磨性。
ABSTRACT:Objective To improve the wear resistance of Q235 steel sheet, and to replace the application of 65Mn in the sieve plate of shaker screen. Methods Tungsten carbide/Nickle-based alloy composite cladding layer was prepared on the surface of Q235 steel plate under the protection of argon gas by resistance wire heating non-vacuum cladding technique. SEM and XRD were used to observe and analyze the combination mode of the cladding layer and the substrate, tungsten carbide distribution, the organi-zation of cladding layer and the phase composition, meanwhile, the Rockwell hardness tester and wear tester were used to test the rock hardness and the wear rate of cladding layer, and analyze the effect of tungsten carbide on the wear resistance of the cladding layer. Results The steel substrate and the cladding layer achieved metallurgical bonding, and the microstructure of the cladding layer mainly consisted of binding phase, tungsten carbide, carbide and boron carbon composite compounds, where the distribution of tungsten carbide was well-proportioned in the cladding layer. With 35% WC content in the cladding layer alloy powder, its rock hardness reached 47. 3HRC and the wear rate was 0. 08 mg/m, which was 5 folds higher than the wear resistance of the steel sub-strate and 4 folds higher than that of 65Mn. Conclusion The tungsten carbide composite cladding layer prepared with argon gas pro-tection was well bonded with the steel substrate and improved the wear resistance of the steel substrate.
参考文献
| [1] | 杜彦斌 .退役机床再制造评价与再设计方法研究[D].重庆大学,2012. |
| [2] | 孙希泰.材料表面强化技术[M].北京:化学工业出版社,2005 |
| [3] | 张增志,韩桂泉,付跃文,沈立山.高频感应熔涂、激光熔覆与氧乙炔喷焊GNi-WC25涂层的性能研究[J].材料工程,2003(02):3-6. |
| [4] | Guozhi Xie;Xiaoyan Lin;Keyu Wang;Xiangyin Mo;Dongjie Zhang;Pinghua Lin .Corrosion characteristics of plasma-sprayed Ni-coated WC coatings comparison with different post-treatment[J].Corrosion Science: The Journal on Environmental Degradation of Materials and its Control,2007(2):662-671. |
| [5] | Zhou, SF;Huang, YJ;Zeng, XY .A study of Ni-based WC composite coatings by laser induction hybrid rapid cladding with elliptical spot[J].Applied Surface Science,2008(10):3110-3119. |
| [6] | K.S. Raja;S.A. Namjoshi;M. Misra .Improved corrosion resistance of Ni-22Cr-13Mo-4W Alloy by surface nanocrystallization[J].Materials Letters,2005(5):570-574. |
| [7] | S. Shrestha;T. Hodgkiess;A. Neville .Erosion-corrosion behaviour of high-velocity oxy-fuel Ni-Cr-Mo-Si-B coatings under high-velocity seawater jet impingement[J].Wear: an International Journal on the Science and Technology of Friction, Lubrication and Wear,2005(1):208-218. |
| [8] | 王慧萍,戴建强,张光钧,邹昌谷,奚文龙.喷涂与激光重熔技术制备镍基纳米钴包碳化物复合涂层的研究[J].热处理,2007(03):24-28. |
| [9] | 贺定勇,许静,马然,蒋建敏,王智慧.高频感应熔覆WC增强Ni60合金涂层性能研究[J].材料热处理学报,2008(03):138-141. |
| [10] | 张忠礼,丁勇,杨国强,沈威威.热喷涂涂层与电镀层的结合与界面[J].沈阳工业大学学报,2011(04):361-365,370. |
| [11] | 魏鑫 .45钢表面感应熔覆Ni60涂层及WC-Ni60复合涂层的研究[D].大连:大连理工大学,2010. |
| [12] | 李文虎.氩弧熔覆钢表面WC/NiCo硬质覆层的组织与性能[J].表面技术,2011(05):35-37. |
| [13] | 杨会龙,孙玉福,赵靖字,马永华,王刘利,肖志云,王璐,丁丽平.截齿表面感应熔覆WC增强Fe基熔覆层的研究[J].表面技术,2011(04):26-29. |
| [14] | 黄新波,贾建援,林化春,康春霞.钴基合金-碳化钨复合涂层耐磨抗蚀性能研究[J].材料工程,2004(08):36-38,43. |
| [15] | 贺定勇,许静,马然,蒋建敏.微米WC增强Ni60合金高频感应熔覆涂层耐磨性能[J].焊接学报,2008(08):1-4. |
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