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考虑材料塑性变形的高速道岔心轨裂纹萌生预测 被引量:1

Rolling Contact Fatigue Crack Initiation Prediction in Nose Rail of High-speed Railway Turnout Considering Plastic Deformation
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摘要 根据高速铁路18号单开道岔钢轨设计廓形,考虑车轮逆向-侧向通过翼轨-心轨时轮载转移引起的冲击荷载和材料塑性变形,将心轨塑性变形结合到裂纹萌生和磨耗共存发展预测方法中,预测了心轨裂纹萌生。分析发现,心轨顶宽35~40 mm为承受轮载转移的最不利位置;该位置的表面材料在冲击荷载下发生塑性变形,其应力应变明显降低,直至在一定轮载次数下达到稳定状态,这时的最大塑性变形量为0.0875~0.0925 mm,延缓了疲劳裂纹的萌生;心轨疲劳损伤最大值位于轨头亚表面,顶宽35和40 mm处的裂纹萌生区域分别在心轨表面垂直向下1.2和1.5 mm、从轨顶中心水平向工作边一侧4~5 mm和1~2 mm的位置。疲劳裂纹萌生寿命分别为1.63×106t和3.97×106t。 According to the designed profiles of wing and nose rails at the No.18 high-speed single-way turnout,the rolling contact fatigue(RCF)crack initiation in nose rail was predicted by the coexistence prediction method of RCF crack initiation and wear growth considering the impact load and material plastic deformation caused by the wheel load transfer from wing rail to nose rail when the train passes the turnout to side and reverse direction.The analysis shows that the worst position at the nose rail is the part with a top width of 35~40 mm at which the impact load caused by wheel load transferring is the largest.There would be plastic deformation at rail surface of this part under impact load which would reduce the material stress and strain obviously until the plastic deformation reaches a stable state with a certain number of wheel cycles.At that time,the maximum plastic deformation is 0.0875~0.0925 mm,which would prolong the(RCF)crack initiation.The maximum fatigue damage in the nose rail is at the rail subsurface.The RCF crack initiation positions for the nose rail at top width of 35 mm and 40 mm are 1.2 and 1.5 mm below rail surface vertically,4~5 mm and 1~2 mm from rail center towards gauge side horizontally respectively.Moreover,the RCF crack initiation life are 1.63×106 and 3.97×106 tones at these two positions respectively.
作者 周宇 王世烨 李骏鹏 王树国 王璞 ZHOU Yu;WANG Shiye;LI Junpeng;WANG Shuguo;WANG Pu(Key Laboratory of Road and Traffic Engineering of the Ministry of Education,Tongji University,Shanghai 201804,China;Shanghai Key Laboratory of Rail Infrastructure Durability and System Safety,Tongji University,Shanghai 201804,China;Railway Engineering Research Institute,China Academy of Railway Sciences Co.,Ltd.,Beijing 100081,China)
机构地区 同济大学道路与交通工程教育部重点实验室 同济大学上海市轨道交通结构耐久与系统安全重点实验室 中国铁道科学研究院集团有限公司铁道建筑研究所
出处 《同济大学学报(自然科学版)》 EI CAS CSCD 北大核心 2023年第4期598-607,共10页 Journal of Tongji University:Natural Science
基金 国家自然科学基金(51878661) 上海市科委项目(20dz1203100) 中央高校基本科研业务费(2022-5-ZD-04)。
关键词 高速铁路 道岔 心轨 滚动接触疲劳 塑性变形 high-speed railway turnout nose rail rolling contact fatigue plastic deformation
分类号 U213.42 [交通运输工程—道路与铁道工程]
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同济大学学报(自然科学版)
2023年 第4期

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