Page 111 - 摩擦学学报2025年第9期

P. 111

第 9 期谢瑜龙, 等: 基于裂纹损伤楔形体积/截面积的滚动接触疲劳损伤量化评价方法研究 1365

contact fatigue crack of train wheels[J]. Tribology, 2020, 40(3): [29] Zhang Guanzhen, Ren Ruiming, Wu Si, et al. Rolling contact fatigue
305–313 (in Chinese) [刘颍宾, 宫彦华, 王强, 等. 列车车轮滚动接 performance of ER8 wheel steel with non-uniform microstructure[J].
触疲劳裂纹评价研究[J]. 摩擦学学报, 2020, 40(3): 305–313]. doi: Tribology, 2021, 41(4): 553–563 (in Chinese) [张关震, 任瑞铭, 吴
10.16078/j.tribology.2019210. 斯, 等. 不均匀组织ER8车轮滚动接触疲劳性能研究[J]. 摩擦学学
[22] Li Xuecheng. Effect of microstructure on wear and rolling contact 报, 2021, 41(4): 553–563]. doi: 10.16078/j.tribology.2020154.
fatigue properties of rail materials[D]. Chengdu: Southwest Jiaotong [30] Guo Huoming, Wang Wenjian, Liu Tengfei, et al. Analysis of
University, 2021 (in Chinese) [李学成. 微观组织对钢轨材料磨损 damage behavior of heavy-haul railway rails[J]. China Mechanical
与滚动接触疲劳性能影响研究[D]. 成都: 西南交通大学, 2021]. Engineering, 2014, 25(2): 267–272 (in Chinese) [郭火明, 王文健,
[23] Li X C, Ding H H, Wang W J, et al. Investigation on the relationship 刘腾飞, 等. 重载铁路钢轨损伤行为分析[J]. 中国机械工程, 2014,
between microstructure and wear characteristic of rail materials[J]. 25(2): 267–272]. doi: 10.3969/j.issn.1004-132X.2014.02.025.
Tribology International, 2021, 163: 107152. doi: 10.1016/j.triboint. [31] Gao Wenli, Qin Feng, Jin Tan, et al. Analysis of fatigue crack
2021.107152. initiation and propagation on U71MnSteel rail during service[J].
[24] Zhang S Y, Liu Q Y, Wang W J, et al. Implications of water medium Journal of Hunan University (Natural Sciences), 2017, 44(6):
for the evolution of rolling contact fatigue under rail surface defect 25–29,44 (in Chinese) [高文理, 钦凤, 金滩, 等. 服役U71Mn钢轨疲
conditions[J]. Tribology International, 2022, 175: 107870. doi: 10. 劳裂纹萌生及扩展分析[J]. 湖南大学学报(自然科学版), 2017,
1016/j.triboint.2022.107870. 44(6): 25–29,44]. doi: 10.16339/j.cnki.hdxbzkb.2017.06.005.
[25] Tang Ao. Mesoscale deformation characteristics of advanced high [32] Xie Yulong, Wang Wenjian, Guo Jun, et al. Rail rolling contact
strength steel and its correlation with damage nucleation[D]. fatigue response diagram construction and shakedown map
Shanghai: Shanghai Jiao Tong University, 2020 (in Chinese) [唐骜. optimization[J]. Wear, 2023, 528: 204964. doi: 10.1016/j.wear.2023.
先进高强钢的介观尺度变形特征及其与损伤形核的关联研究[D]. 204964.
上海: 上海交通大学, 2020]. [33] Li Shengjie, Li Jiaxin, Wu Bingnan, et al. Influence of lubricating
[26] Garnham J E, Davis C L. The role of deformed rail microstructure materials on wheel-rail wear and rolling contact fatigue[J].
on rolling contact fatigue initiation[J]. Wear, 2008, 265(9-10): Tribology, 2022, 42(5): 935–944 (in Chinese) [李胜杰, 李佳辛, 吴
1363–1372. doi: 10.1016/j.wear.2008.02.042. 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].
[27] Kapoor A. Wear by plastic ratchetting[J]. Wear, 1997, 212: 摩擦学学报 , 2022, 42(5): 935–944]. doi: 10.16078/j.tribology.
119–130. doi: 10.1016/S0043-1648(97)00083-5. 2021118.
[28] Liu Xudong, Liu Pengtao, Zhao Xiujuan, et al. Influence of original [34] Vicente F S, Guillamón M P. Use of the fatigue index to study
microstructure on rolling contact fatigue properties of ER9 wheel rolling contact wear[J]. Wear, 2019, 436: 203036. doi: 10.1016/j.
steel[J]. Tribology, 2021, 41(6): 902–912 (in Chinese) [刘旭东, 刘 wear.2019.203036.
鹏涛, 赵秀娟, 等. 原始组织对ER9车轮钢滚动接触疲劳性能 [35] Bower A F. The influence of crack face friction and trapped fluid on
的影响[J]. 摩擦学学报, 2021, 41(6): 902–912]. doi: 10.16078/j. surface initiated rolling contact fatigue cracks[J]. Journal of
tribology.2020213. Tribology, 1988, 110(4): 704–711. doi: 10.1115/1.3261717.

106 107 108 109 110 111 112 113 114 115 116