第 5 期                    吴柄男, 等: 不同施用条件下轨顶摩擦调节剂的减摩性能研究                                       757

            [19]   Mu  Xinpeng,  Wang  Wenjian,  Zhu  Yi,  et  al.  Effects  of  two  laser  composition on adhesion and rheological behaviour[J]. Engineering
                 cladding  coatings  on  wear  and  damage  properties  of  wheel/rail  Science and Technology, an International Journal, 2022, 35: 101100.
                 materials[J]. Tribology, 2020, 40(2): 225–233 (in Chinese) [慕鑫鹏,  doi: 10.1016/j.jestch.2022.101100.
                 王文健, 祝毅, 等. 两种激光熔覆涂层对轮轨材料磨损与损伤性能              [24]   Li  Qun,  Ding  Haohao,  Shi  Lubing,  et  al.  Recovery  Process  of
                 的影响[J]. 摩擦学学报, 2020, 40(2): 225–233]. doi: 10.16078/j.  wheel/rail  adhesion  under  the  action  of  water-based  friction
                 tribology.2019105.                                modifier[J].  China  Surface  Engineering,  2022,  35(1):  107–115  (in
            [20]   Hu Y, Zhou L, Ding H H, et al. Microstructure evolution of railway  Chinese) [李群, 丁昊昊, 师陆冰, 等. 水基摩擦调节剂作用下轮轨
                 pearlitic  wheel  steels  under  rolling-sliding  contact  loading[J].  黏着恢复过程[J]. 中国表面工程, 2022, 35(1): 107–115]. doi: 10.
                 Tribology International, 2021, 154: 106685. doi: 10.1016/j.triboint.  11933/j.issn.1007−9289.20210909002.
                 2020.106685.                                  [25]   Li J X, Wu B N, Ding H H, et al. Wear and damage behaviours of
            [21]   Masjedi  M,  Khonsari  M  M.  Film  thickness  and  asperity  load  wheel  and  rail  materials:  effects  of  friction  modifier  and
                 formulas  for  line-contact  elastohydrodynamic  lubrication  with  environmental  temperature[J].  Wear,  2023,  523:  204796.  doi:  10.
                 provision  for  surface  roughness[J].  Journal  of  Tribology,  2012,  1016/j.wear.2023.204796.
                 134(1): 1. doi: 10.1115/1.4005514.            [26]   Rahmani  H,  Gutsulyak  D,  Stanlake  L,  et  al.  Carrydown  of  liquid
            [22]   Li Shengjie, Li Jiaxin, Wu Bingnan, et al. Influence of lubricating  friction  modifier[J].  Proceedings  of  the  Institution  of  Mechanical
                 materials  on  wheel-rail  wear  and  rolling  contact  fatigue[J].  Engineers, Part F: Journal of Rail and Rapid Transit, 2022, 236(9):
                 Tribology, 2022, 42(5): 935–944 (in Chinese) [李胜杰, 李佳辛, 吴  1124–1134. doi: 10.1177/09544097221076258.
                 柄男, 等. 不同润滑材料对轮轨磨损与滚动接触疲劳的影响[J]. 摩            [27]   Eadie D T, Elvidge D, Oldknow K, et al. The effects of top of rail
                 擦 学 学 报 ,  2022,  42(5):  935–944].  doi:  10.16078/j.tribology.  friction  modifier  on  wear  and  rolling  contact  fatigue:  full-scale
                 2021118.                                          rail–wheel  test  rig  evaluation,  analysis  and  modelling[J].  Wear,
            [23]   Kvarda D, Skurka S, Galas R, et al. The effect of top of rail lubricant  2008, 265(9-10): 1222–1230. doi: 10.1016/j.wear.2008.02.029.