局部堆焊修复U75V钢轨的滚动接触磨损特性
Rolling Contact Wear Characteristics of U75V Rail Repaired by Local Surfacing
摘 要
对未堆焊和局部堆焊U75V钢轨试样进行干态+湿态两阶段连续滚动接触磨损试验,对比分析了2种钢轨试样的滚动接触特性及磨损行为。结果表明:2种钢轨试样的黏着系数在干态磨损阶段都在0.60左右,进入湿态磨损阶段急剧下降至0.25左右;干态磨损阶段局部堆焊钢轨试样的黏着系数略高于未堆焊钢轨试样,湿态磨损阶段则相反。局部堆焊钢轨试样的堆焊层主要由马氏体组成,硬度最高,磨损表面损伤轻微,未发现明显裂纹与塑性变形;热影响区由铁素体、珠光体与马氏体等组织组成,硬度居中,磨损后表面粗糙度最大,塑性变形较大且出现较多大角度扩展的裂纹;无堆焊区主要由珠光体组成,硬度最小,磨损后表面平坦,塑性变形较明显,出现少量裂纹。
堆焊修复
滚动接触磨损
塑性变形
裂纹
rail
surfacing repair
rolling contact wear
plastic deformation
crack
Abstract
The dry and wet two-stage continuous rolling contact wear tests were carried out on U75V rail samples without surfacing and with local surfacing. The rolling contact characteristics and wear behavior of the two rail samples were compared and analyzed.The results show that the adhesion coefficients of the two rail samples were both about 0.60 in the dry wear stage, and decreased sharply to about 0.25 into the wet wear stage; the adhesion coefficient of the local surfacing rail sample in the dry wear stage was slightly higher than the un-surfacing rail sample, and the wet wear stage was the opposite. The surfacing layer of the local surfacing rail sample mainly consisted of martensite and had the highest hardness. The wear surface damage of surfacing layer was slight, and no obvious cracks and plastic deformation were found. The heat affected zone was composed of ferrite, pearlite and martensite and the hardness was in the middle. After wear, the surface roughness of the heat affected zone was the largest, the plastic deformation was large and there were many cracks with large expansion angles. The non-surfacing zone was mainly composed of pearlite and the hardness was the lowest. After wear, the surface of the non-surfacing zone was flat, and obvious plastic deformation and a small amount of cracks were found.
中图分类号 TH117 DOI 10.11973/jxgccl202302012
所属栏目 材料性能及应用
基金项目 国家自然科学基金资助项目(52061012,51805170);江西省自然科学基金资助项目(20212ACB214003,20224ACB204012)
收稿日期 2022/1/6
修改稿日期 2022/12/25
网络出版日期
作者单位点击查看
备注容彬(1997-),男,广西钦州人,硕士研究生
引用该论文: RONG Bin,WANG Yongqiang,ZHAO Huoping,LIU Shaopeng,SHEN Mingxue. Rolling Contact Wear Characteristics of U75V Rail Repaired by Local Surfacing[J]. Materials for mechancial engineering, 2023, 47(2): 67~72
容彬,汪永强,赵火平,刘少鹏,沈明学. 局部堆焊修复U75V钢轨的滚动接触磨损特性[J]. 机械工程材料, 2023, 47(2): 67~72
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【2】高琦.钢轨表面堆焊修复新技术[J].电焊机, 2012, 42(5):71-76. GAO Q.Study on a new technology of rail surfacing repairing[J].Electric Welding Machine, 2012, 42(5):71-76.
【3】陈辉, 曾维德, 车小莉, 等.铁路在线伤损钢轨堆焊修复新技术研究[J].电焊机, 2004, 34(4):14-16. CHEN H, ZENG W D, CHE X L, et al.Research on new technology of repairing rails tracks by surfacing welding[J].Electric Welding Machine, 2004, 34(4):14-16.
【4】朱德稳. 原位焊在核伤钢轨处理中的运用[J]. 铁道运营技术, 2017, 23(3):58-60. ZHU D W. Application of in-situ welding in nuclear damaged rail treatment[J]. Railway Operation Technology, 2017, 23(3):58-60.
【5】梁旭, 周清跃, 张银花, 等.美国钢轨原位修复技术[J].中国铁路, 2019(3):100-108. LIANG X, ZHOU Q Y, ZHANG Y H, et al.In-situ repair technology of rail in the United States[J].China Railway, 2019(3):100-108.
【6】王庆伟, 陈辉, 赵曦.采用药芯焊丝堆焊修复后的钢轨组织性能[J].电焊机, 2010, 40(1):79-82. WANG Q W, CHEN H, ZHAO X.Research on microstructure and property of rail by surfacing welding with self-shielded flux-corded wire[J].Electric Welding Machine, 2010, 40(1):79-82.
【7】陆鑫, 李大东, 王若愚, 等.焊接工艺对钢轨闪光焊接头性能的影响[J].焊接, 2019(12):50-55. LU X, LI D D, WANG R Y, et al.Influence of welding process on performance of rail flash butt welded joint[J].Welding & Joining, 2019(12):50-55.
【8】丁韦, 李力, 高振坤, 等.贝氏体钢轨闪光焊接技术的研究[J].铁道建筑, 2019, 59(12):142-146. DING W, LI L, GAO Z K, et al.Research on bainite rail flash butt welding technology[J].Railway Engineering, 2019, 59(12):142-146.
【9】丁韦, 李力, 邹定强, 等.贝氏体、珠光体钢轨闪光焊接头力学性能研究[J].热加工工艺, 2016, 45(23):70-73. DING W, LI L, ZOU D Q, et al.Study on mechanical properties of flash welding joints of bainite steel and pearlite steel rail[J].Hot Working Technology, 2016, 45(23):70-73.
【10】OSTASH O P, KULYK V V, POZNYAKOV V D, et al.Fatigue crack growth resistance of welded joints simulating the weld-repaired railway wheels metal[J].Archives of Materials Science and Engineering, 2017, 2(86):49-52.
【11】LUCHTENBERG P, DE CAMPOS P T, SOARES P, et al. Effect of welding energy on the corrosion and tribological properties of duplex stainless steel weld overlay deposited by GMAW/CMT process[J].Surface and Coatings Technology, 2019, 375:688-693.
【12】XU J, WANG P, GAO Y, et al. Geometry evolution of rail weld irregularity and the effect on wheel-rail dynamic interaction in heavy haul railways[J].Engineering Failure Analysis, 2017, 81:31-44.
【13】LI W.Plastic deformation of curved rail at rail weld caused by train-track dynamic interaction[J].Wear, 2011, 271(1/2):311-318.
【14】CAI W, WEN Z, JIN X, et al. Dynamic stress analysis of rail joint with height difference defect using finite element method[J].Engineering Failure Analysis, 2007, 14(8):1488-1499.
【15】兖文涛, 李晓延, 孙建通, 等.钢轨轨面堆焊温度场的数值模拟[J].机械工程材料, 2015, 39(8):103-106. YAN W T, LI X Y, SUN J T, et al.Numerical simulation of temperature field of rail steel overlay welding[J].Materials for Mechanical Engineering, 2015, 39(8):103-106.
【16】JUN H K, SEO J W, JEON I S, et al. Fracture and fatigue crack growth analyses on a weld-repaired railway rail[J].Engineering Failure Analysis, 2016, 59:478-492.
【17】LIU R F, WANG J C. Finite element analyses of the effect of weld overlay sizing on residual stresses of the dissimilar metal weld in PWRs[J].Nuclear Engineering and Design, 2021, 372:110959.
【18】高炳易.贝氏体焊条直接堆焊修复铁路钢轨特性研究[J].热加工工艺, 2009, 38(11):138-140. GAO B Y.Study on characteristics of bainitic welding rod for direct built-up welding in rail[J].Hot Working Technology, 2009, 38(11):138-140.
【19】刘园.液体对轮轨滚动接触疲劳作用下的钢轨表面裂纹扩展机理的影响[J].上海海事大学学报, 2011, 32(1):65-69. LIU Y.Effect of liquid penetration on rail crack propagation mechanism under rolling contact fatigue between wheel and rail[J].Journal of Shanghai Maritime University, 2011, 32(1):65-69.
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【21】FOO C T, OMAR B, JALIL A S.A review on recent wheel/rail interface friction management[J].Journal of Physics:Conference Series, 2018, 1049:012009.
【22】王军平, 周宇, 沈钢.钢轨硬度对疲劳裂纹萌生和钢轨磨耗的影响[J].西南交通大学学报, 2021, 56(3):611-618. WANG J P, ZHOU Y, SHEN G.Effect of rail hardness on fatigue cracks initiation and rail wear[J].Journal of Southwest Jiaotong University, 2021, 56(3):611-618.
【23】SU Y.The sensitivity analysis of microstructure and mechanical properties to welding parameters for linear friction welded rail steel joints[J].Materials Science and Engineering:A, 2019, 764:138251.
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