孙铁龙,徐流杰,魏世忠,范晓嫚

• 1:河南科技大学材料科学与工程学院
• 2:河南科技大学金属材料磨损控制与成型技术国家地方联合工程研究中心

摘要(Abstract)：

金属材料的磨粒磨损性能常采用载荷(p)或磨粒尺寸(d)单因素参数进行评估,为了考察载荷和磨粒尺寸对金属材料磨损性能的综合影响,本文提出用pd因子(载荷与磨粒尺寸的乘积)来表征金属材料的磨损行为,研究了pd因子与不同金属材料磨损量之间的关系。结果表明:根据统计分析结果,金属材料的磨损量与pd因子呈现线性关系,随着pd因子值的增加,金属材料的磨损量也随之增加。利用弹性理论,建立了金属材料磨粒磨损的新模型,该模型能较好的反映pd因子对金属材料磨粒磨损性能影响的特征和机制。

关键词(KeyWords)： 金属材料;磨粒磨损;载荷;磨粒尺寸;pd因子

Abstract:

Keywords:

基金项目(Foundation): 国家自然科学基金(U1704152);; 长江学者和创新团队发展计划(IRT1234)

作者(Author): 孙铁龙,徐流杰,魏世忠,范晓嫚

DOI: 10.13289/j.issn.1009-6264.2018-0419

参考文献(References)：

• [1] 周陈新,罗军明,李乐乐,等.TiB2钢结硬质合金摩擦磨损行为[J].材料热处理学报,2018,39(8):114-121.ZHOU Chen-xin,LUO Jun-ming,LI Le-le,et al.Friction and wear behavior of TiB2 steel-bonded cemented carbide[J]. Transactions of Materials and Heat Treatment,2018,39(8):114-121.
• [2] 刘爱辉,丁红燕,周广宏.原位Al2O3颗粒增强铜基复合材料的微动磨损特性[J].材料热处理学报,2012,33(S1):20-23.LIU Ai-hui,DING Hong-yan,ZHOU Guang-hong.Frictional wear characteristics of in-situ Al2O3 particle reinforced copper matrix composites[J].Transactions of Materials and Heat Treatment,2012,33(S1):20-23.
• [3] Khruschov M M.Principles of abrasive wear[J].Wear,1974,28(1):69-88.
• [4] Pellizzari M,Cescato D,Flora M G D.Hot friction and wear behavior of high speed steel and high chromium iron for rolls[J].Wear,2009,267(1):467-475.
• [5] 王伟,崔洪芝,王泽宁,等.50CrMo4钢感应淬火微观组织和磨损机制[J].材料热处理学报,2015,36(7):62-68.WANG Wei,CUI Hong-zhi,WANG Ze-ning,et al.Microstructure and wear mechanism of induction hardening of 50CrMo4 steel[J].Transactions of Materials and Heat Treatment,2015,36(7):62-68.
• [6] Mondal D P,Das S,Jha A K,et al.Abrasive wear of Al alloy-Al2O3,particle composite:a study on the combined effect of load and size of abrasive[J].Wear,1998,223(1-2):131-138.
• [7] Singh M,Mondal D P,Modi O P,et al.Two-body abrasive wear behavior of aluminum alloy-sillimanite particle reinforced composite[J].Wear,2002,253(3):357-368.
• [8] 张开源,尹延国,张国涛,等.FeS/Cu-Bi铜基轴承材料的摩擦磨损性能[J].材料热处理学报,2018,39(9):44-51.ZHANG Kai-yuan,YIN Yan-guo,ZHANG Guo-tao,et al.Friction and wear properties of FeS/Cu-Bi copper-based bearing materials[J].Transactions of Materials and Heat Treatment,2018,39(9):44-51.
• [9] Xu L,Wei S,Xiao F,et al.Effects of carbides on abrasive wear properties and failure behaviours of high speed steels with different alloy element content[J].Wear,2017,s376-377:968-974.
• [10] Han X M,Gao F,Song B Y,et al.Effect of friction speed on friction and wear performance of Cu-matrix friction materials[J].Tribology,2009,103(5):1860-1867.
• [11] Das S,Mondal D P,Sawla S,et al.Synergic effect of reinforcement and heat treatment on the two body abrasive wear of an Al-Si alloy under varying loads and abrasive sizes[J].Wear,2008,264(1/2):47-59.
• [12] Wu S B,Cai Z B,Lin Y,et al.Study on the effect of hard sand on the impact wear behavior of TC4 alloy[J].Tribology,2018,25(4):1-11.
• [13] Trevisiol C,Jourani A,Bouvier S.Effect of martensitic volume fraction and abrasive particles size on friction and wear behavior of a low alloy steel[J].Tribology International,2016,113:411-425.
• [14] Kaushik N C,Rao R N.Effect of grit size on two body abrasive wear of Al6082 hybrid composites produced by stir casting method[J].Tribology International,2016,102:52-60.
• [15] Archard J F.Contact and rubbing of flat surfaces[J].Journal of Applied Physics,2004,24(8):981-988.
• [16] Hornbogen E.The role of fracture toughness in the wear of metals[J].Wear,1975,33(2):251-259.
• [17] Modi O P,Yadav R P,Mondal D P,et al.Abrasive wear behavior of zinc-aluminum alloy-10% Al2O3 composite through factorial design of experiment[J].Journal of Materials Science,2001,36(7):1601-1607.
• [18] Tozetti K D,Albertin E,Scandian C.Abrasive size and load effects on the wear of a 19.9% chromium and 2.9% carbon cast iron[J].Wear,2017,376-377:46-53.
• [19] Kumar P S,Manisekar K,Narayanasamy R.Experimental and prediction of abrasive wear behavior of sintered Cu-SiC composites containing graphite by using artificial neural networks[J].Tribology Transactions,2014,57(3):455-471.
• [20] 潘学福,武会宾,巨彪,等.耐磨管线钢磨粒磨损机理[J].热加工工艺,2016(10):109-113.PAN Xue-fu,WU Hui-bin,JU Biao,et al.Wear mechanism of wear-resistant pipeline steel abrasives[J].Hot Working Technology,2016(10):109-113.
• [21] Bouvier S.Friction and wear mechanisms of 316L stainless steel in dry sliding contact:Effect of abrasive particle size[J].Tribology Transactions,2015,58(1):131-139.
• [22] (日)中原一郎著.弹性力学手册[M].西安:西安交通大学出版社,2014.

文章评论(Comment)：