蛇纹石对铁基金属摩擦副的减摩修复作用

详细信息    查看全文 | 推荐本文 |

英文篇名：Antifriction Repair Function of Serpentine on Fe Based Metal Friction Pairs 作者：李桂金 ; 白志民 ; 赵平 英文作者：LI Guijin;BAI Zhimin;ZHAO Ping;China Building Materials Academy;School of Material Science and Technology, China University of Geoscience (Beijing); 关键词：蛇纹石 ; 减摩修复 ; 作用机制 ; 铁基金属 英文关键词：serpentine;;antifriction repair function;;action mechanism;;iron based metal 中文刊名：GXYB 英文刊名：Journal of the Chinese Ceramic Society 机构：中国建筑材料科学研究总院;中国地质大学(北京)材料科学与工程学院; 出版日期：2017-11-02 13:29 出版单位：硅酸盐学报 年：2018 期：v.46;No.347 基金：国家重点研发计划(2017YFB0310700)资助项目 语种：中文; 页：GXYB201802020 页数：9 CN：02 ISSN：11-2310/TQ 分类号：150-158

摘要

系统总结了蛇纹石粉体的粒度、在润滑油脂中分散稳定性、热处理、稀土镧化合物及应用工艺等对其减摩修复作用的影响,明确了提升蛇纹石摩擦性能的调控方向。深入分析了铁基摩擦副减摩修复层在表面形貌、化学成分、晶相结构与机械性能等方面的特征及形成过程,探讨了蛇纹石对铁基摩擦副的减摩修复作用机制,提出了本领域尚未解决的关键问题及未来重点研究方向。
        The influences of serpentine particle size, powder dispersion stability in lubrication oil, heat treatment, rare earth element La compounds and application process on antifriction repair performance of serpentine were investigated. The regulation direction of enhancing the tribology property of serpentine was proposed. The characteristics and formation process of antifriction repair layer of iron-based friction pairs in surface morphology, chemical composition, crystalline phase structure and mechanical properties were analyzed. The action mechanism of antifriction repair function of serpentine to iron-based friction pairs was investigated. In addition, some key problems unsolved in this field and the future research directions were also given.

引文

[1]杨其明,白志民.超细蛇纹石粉体的材料特性、摩擦学介入行为及其工业应用[J].润滑与密封,2010,35(9):98–101.YANG Qiming,BAI Zhimin.Lubr Eng(in Chinese),2010,35(9):98–101.
    [2]JIN Y S,LI S H,ZHANG Z Y,et al.In situ mechanochemical reconditioning of worn ferrous surfaces[J].Tribol Int,2004,37(7):561–567.
    [3]张保森,徐滨士,许一,等.蛇纹石微粉对球墨铸铁摩擦副的减摩抗磨作用机理[J].硅酸盐学报,2009,37(12):2037–2042.ZHANG Baosen,XU Binshi,XU Yi,et al.J Chin Ceram Soc,2009,37(12):2037–2042.
    [4]张博,徐滨士,许一,等.微纳米层状硅酸盐矿物润滑材料的摩擦学性能研究[J].中国表面工程,2009,22(1):29–32.ZHANG Bo,XU Binshi,XU Yi,et al.Chin Surf Eng(in Chinese),2009,22(1):29–32.
    [5]于鹤龙,许一,史佩京,等.蛇纹石热处理产物作为润滑油添加剂的摩擦学性能[J].摩擦学学报,2011,31(5):504–509.YU Helong,XU Yi,SHI Peijing,et al.Tribology(in Chinese),2011,31(5):504–509.
    [6]曹娟,张振忠,安少华,等.超细蛇纹石的表面修饰及其在基础油中的摩擦学性能[J].硅酸盐学报,2008,36(9):1210–1214.CAO Juan,ZHANG Zhenzhong,AN Shaohua,et al.J Chin Ceram Soc,2008,36(9):1210–1214.
    [7]金元生.蛇纹石内氧化效应对铁基金属磨损表面自修复层生成的作用[J].中国表面工程,2010,23(1):45–50.JIN Yuansheng.Chin Surf Eng(in Chinese),2010,23(1):45–50.
    [8]高飞,许一,徐滨士,等.天然蛇纹石粉体润滑油添加剂的自修复性能及自修复层形成机理研究[J].摩擦学学报,2011,31(5):431–438.GAO Fei,XU Yi,XU Binshi,et al.Tribology(in Chinese),2011,31(5):431–438.
    [9]YANG Y,GU J,KANG F,et al.Surface restoration induced by lubricant additive of natural minerals[J].Appl Surf Sci,2007,253(18):7549–7553.
    [10]YU H L,XU Y,SHI P J,et al.Microstructure,mechanical properties and tribological behavior of tribofilm generated from natural serpentine mineral powders as lubricant additive[J].Wear,2013,297(s1–2):802–810.
    [11]ZHANG J,TIAN B,WANG C B.Long-term surface restoration effect introduced by advanced silicate based lubricant additive[J].Tribol Int,2013,57(4):31–37.
    [12]赵福燕.微纳米蛇纹石粉体的摩擦行为及其成膜机理研究[D].中国地质大学(北京),2014.ZHAO Fuyan.Tribological Properties of serpentine micro-nanoparticles and mechanism of tribofilm formation(in Chinese,dissertation).Beijing:China University of Geoscience,2014.
    [13]杨其明.金属减摩修复技术及其在铁路内燃机车柴油机上的应用[J].中国设备工程,2007(9):59–61.YANG Qiming.Chin Plant Eng(in Chinese),2007(9):59–61.
    [14]周平安.金属磨损自修复材料的功能特点和应用前景[J].中国表面工程,2004,17(1):39–41.ZHOU Pingan.Chin Surf Eng(in Chinese),2004,17(1):39–41.
    [15]陈文刚,高玉周,张会臣.蛇纹石粉体作为自修复添加剂的抗磨损机理[J].摩擦学学报,2008,28(5):463–468.CHEN Wengang,GAO Yunzhou,ZHANG Huichen.Trobology(in Chinese),2008,28(5):463–468.
    [16]陈文刚,高玉周,张会臣.不同载荷对45#钢表面自修复膜成膜影响[J].大连海事大学学报,2007,33(4):109–112.CHEN Wengang,GAO Yuzhou,ZHANG Huichen.J Dalian Mar Univ(in Chinese),2007,33(4):109–112.
    [17]曹娟,张振忠,赵芳霞.超细蛇纹石粉体改善润滑油摩擦磨损性能的研究[J].润滑与密封,2007,32(12):53–55.CAO Juan,ZHANG Zhenzhong,ZHAO Fangxia.Lubr Eng(in Chinese),2007,32(12):53–55.
    [18]于鹤龙,许一,史佩京,等.蛇纹石超细粉体作润滑油添加剂的摩擦学性能[J].粉末冶金材料科学与工程,2009,14(5):310–315.YU Helong,XU Yi,SHI Peijing,et al.Mater Sci Eng Powder Metall(in Chinese),2009,14(5):310–315.
    [19]陈文刚,高玉周,张会臣,等.经热处理的蛇纹石粉体对金属磨损特性的影响[J].硅酸盐学报,2008,36(1):30–34.CHEN Wengang,GAO Yuzhou,ZHANG Huichen,et al.J Chin Ceram Soc,2008,36(1):30–34.
    [20]张保森,徐滨士,许一,等.天然矿物微粉润滑添加剂对钢摩擦副的自修复效应[J].摩擦学学报,2011,31(3):289–294.ZHANG Baosen,XU Binshi,XU Yi,et al.Tribology(in Chinese),2011,31(3):289–294.
    [21]张保森,许一,徐滨士,等.45钢表面原位摩擦化学反应膜形成过程及力学性能[J].材料热处理学报,2011,32(1):87–91.ZHANG Baosen,XU Yi,XU Binshi,et al.Trans Mater Heat Treat(in Chinese),2011,32(1):87–91.
    [22]李桂金,白志民,黄卫俊,等.蛇纹石粉体表面改性研究[J].硅酸盐通报,2008,27(6):1091–1095.LI Guijin,BAI Zhimin,HUANG Weijun,et al.Bull Chin Ceram Soc(in Chinese),2008,27(6):1091–1095.
    [23]陈文刚,高玉周,张会臣.自修复添加剂的热处理及其分散性研究[J].润滑与密封,2007,32(8):52–55.CHEN Wengang,GAO Yuzhou,ZHANG Huichen.Lubr Eng(in Chinese),2007,32(8):52–55.
    [24]宋立磊,朱新河,严志军,等.复配表面活性剂对纳米粒子在润滑油中分散稳定性的影响[J].润滑与密封,2016,41(4):82–85.SONG Lilei,ZHU Xinhe,YAN Zhijun,et al.Lubr Eng(in Chinese),2016,41(4):82–85.
    [25]郑威,张振忠,赵芳霞,等.蛇纹石粉体的热处理及其对基础油摩擦学性能的影响[J].石油炼制与化工,2013,44(3):71–74.ZHENG Wei,ZHANG Zhenzhong,ZHAO Fangxia,et al.Chin Petrol Process Petrochem Technol(in Chinese),2013,44(3):71–74
    [26]BAI Z M,YANG N,GUO M,et al.Antigorite:Mineralogical characterization and friction performances[J].Tribol Int,2016,(101):115–121.
    [27]顾彩香,顾卓明,王平宗.含纳米稀土、铁复合粒子润滑油的摩擦学性能[J].中国稀土学报,2006,24(z1):140–143.GU Caixiang,GU Zhuoming,WANG Pingzong.J Chin Rare Earth Soc(in Chinese),2006,24(z1):140–143.
    [28]张保森,徐滨士,许一,等.纳米氧化镧对超细蛇纹石微粉热相变行为的影响[J].材料热处理学报,2013,34(12):18–23.ZHANG Baosen,XU Binshi,XU Yi,et al.Trans Mater Heat Treat(in Chinese),2013,34(12):18–23.
    [29]赵福燕,白志民,赵栋,等.蛇纹石/La复合粉体的制备及其摩擦性能[J].硅酸盐学报,2012,40(1):126–130.ZHAO Fuyan,BAI Zhimin,ZHAO Dong,et al.J Chin Ceram Soc,2012,40(1):126–130.
    [30]许一,张保森,徐滨士,等.镧/蛇纹石复合润滑材料的热力学及摩擦学性能[J].粉末冶金材料科学与工程,2011,16(3):349–354.XU Yi,ZHANG Baosen,XU Binshi,et al.Mater Sci Eng Powder Metall(in Chinese),2011,16(3):349–354.
    [31]赖建华,黄武彪.金属减摩修复技术在铁路机车柴油机上的应用[J].润滑与密封,2010,35(12):127–129.LAI Jianhua,HUANG Wubiao.Lubr Eng(in Chinese),2010,35(12):127–129.
    [32]杨鹤,金元生,山下一彦.Mg6Si4O10(OH)8修复剂应用于滑动轴承的模拟试验研究[J].润滑与密封,2006(7):144–146.YANG He,JIN Yuansheng,SHANXIA Yiyan.Lubr Eng(in Chinese),2006(7):144–146.
    [33]史佩京,于鹤龙,赵阳,等.原位摩擦化学处理对45钢力学性能及摩擦学特性的影响[J].材料热处理学报,2007,28(2):113–117.SHI Peijing,YU Helong,ZHAO Yang,et al.Trans Mater Heat Treat(in Chinese),2007,28(2):113–117.
    [34]肖舟,侯根良,苏勋家,等.蛇纹石对不同粗糙度45#钢表面的减摩行为[J].硅酸盐学报,2012,40(8):1190–1196.XIAO Zhou,HOU Genliang,SU Xunjia,et al.J Chin Ceram Soc,2012,40(8):1190–1196.
    [35]ZHANG B,XU B S,XU Y et al.Tribological characteristics and self-repairing effect of hydroxy-magnesium silicate on various surface roughness friction pairs[J].J Cent South Univ,2011,18(5):1326–1333.
    [36]GAO Y Z,CHEN W G,ZHANG H C.Superlubricity Characteristics Using Ceramic Composite Mineral Powder as Lubricating Oil Additive[C]//.Advanced Tribology.Springer Berlin Heidelberg,2009:329–332.
    [37]李桂金,赵平,白志民.蛇纹石表面特性[J].硅酸盐学报,2017,45(8):1204-1210.LI Guijin,ZHAO Ping,BAI Zhimin.J Chin Ceram Soc,2017,45(8):1204-1210.
    [38]杨鹤,张正业,李生华,等.金属磨损自修复层的X光电子能谱研究[J].光谱学与光谱分析,2005,25(6):945–948.YANG He,ZHANG Zhengye,LI Shenghua,et al.Spectrosc Spect Anal,2005,25(6):945–948.
    [39]陈文刚,高玉周,张会臣,等.超细羟基硅酸镁粉体在磨损后钢表面的自修复特性[J].硅酸盐学报,2010,38(4):762–767.CHEN Wengang,GAO Yuzhou,ZHANG Huichen,et al.J Chin Ceram Soc,2010,38(4):762–767.
    [40]张保森,徐滨士,许一,等.蛇纹石微粉对球墨铸铁摩擦副的减摩抗磨作用机理[J].硅酸盐学报,2009,37(12):2037–2042.ZHANG Baosen,XU Binshi,XU Yi,et al.J Chin Ceram Soc,2009,37(12):2037–2042.
    [41]于鹤龙,许一,史佩京,等.蛇纹石润滑油添加剂摩擦反应膜的力学特征与摩擦学性能[J].摩擦学学报,2012,32(5):500–506.YU Helong,XU Yi,SHI Peijing,et al.Tribology(in Chinese),2012,32(5):500–506.
    [42]许一,徐滨士,史佩京,等.微纳米减摩自修复技术的研究进展及关键问题[J].中国表面工程,2009,22(2):7–14.XU Yi,XU Binshi,SHI Peijin,et al.Chin Surf Eng(in Chinese),2009,22(2):7–14.
    [43]杨鹤,李生华,金元生.修复剂羟基硅酸镁存在时钢摩擦副的摩擦磨损特性研究[J].摩擦学学报,2005,25(4):308–311.YANG He,LI Shenghua,JIN Yuansheng.Tribology(in Chinese),2005,25(4):308–311.
    [44]黄书林,杨屹,杨刚,等.机械诱导金属表面再生层性能分析[J].中国表面工程,2016,29(6):129–135.HUANG Shulin,YANG Yi,YANG Gang,etal.Chin Surf Eng(in Chinese),2016,29(6):129–135.
    [45]WANG F.Research on microstructure of the auto-restoration layer of worn surface of metals[J].Mater Sci Eng A,2005,399(1/2):271–275.
    [46]张保森,徐滨士,许一,等.蛇纹石微粉对类轴–轴瓦摩擦副的自修复效应及作用机理[J].粉末冶金材料科学与工程,2013(3):346–352.ZHANG Baosen,XU Binshi,XU Yi,et al.Mater Sci Eng Powder Metall(in Chinese),2013(3):346–352.
    [47]ZHANG B S,Xu B S,Xu Y,et al.An amorphous Si-O film tribo-induced by natural hydrosilicate powders on ferrous surface[J].Appl Surf Sci,2013,285(Part B):759–765.
    [48]ZHANG J,GU Y H,LIU J J.Advanced silicate-based lubricant additive induced diamond-like carbon structured restoration layer[J].Tribol Int,2015,90:263–269.
    [49]QI X W,LU L,JIA Z N,et al.Comparative tribological properties of magnesium hexasilicate and serpentine powder as lubricating oil additives under High temperature[J].Tribol Int,2012,49(11):53–57.