Initiation Cause of Subway Rail Corrugation on Track with Rubber-Booted Short Sleepers
-
摘要:为探明我国某地铁线路弹性短轨枕轨道曲线钢轨短波长波磨萌生原因,采用现场试验和数值仿真方法对其开展了研究. 首先,通过现场试验确定钢轨波磨波长与轨道动态特性对应关系;其次,利用车辆-轨道耦合动力学模型计算轮轨接触参量,通过力锤敲击法获得现场轨道导纳特性;最后,基于轮轨接触参量和轨道导纳结果,建立钢轨波磨频域线性分析的数值模型,模拟弹性短轨枕轨道频域下曲线钢轨磨损率特征,分析了弹性短轨枕轨道萌生特定波长波磨原因. 研究结果表明:地铁弹性短轨枕轨道钢轨波磨主要出现在半径小于等于800 m曲线段,低轨波磨程度更为显著,波长为50~160 mm,通过频率为140~280 Hz;轨道在160~210 Hz频率范围的模态振型表现为钢轨和轨枕一起相对轨道板垂向弯曲振动,在250~300 Hz频率范围的表现为钢轨和轨枕垂向反向振动,波磨通过频率与该轨道的160~300 Hz共振频率相近. 弹性短轨枕轨道特定波长波磨萌生主要与其轨道垂向固有特性相关,其波磨特征为频率固定型,波磨波长随车辆运行速度变化而变化.Abstract:To investigate initiation cause of short-pitch rail corrugations occurred on curved tracks with rubber-booted short sleepers, field measurement and numerical simulation methods were employed. Firstly, establishment of the relationship for wavelength of the rail corrugation and dynamic behaviour of the track was facilitated by the field measurement. Then, wheel-rail contact parameters were calculated by a vehicle-track coupled dynamics model. Receptance of the tracks was measured by an impact excitation technique. At last, a linear model for the rail corrugation was established to analyze characteristic of rail wear based on the wheel-rail contact parameters and the receptance of the tracks. Rail wear rate of the tracks in the frequency domain was calculated during a vehicle running at curves. The initiation cause for rail corrugations with specific wavelengths occurred on the tracks with rubber-booted short sleepers was clarified. The results show that corrugations for the tracks with rubber-booted short sleepers have occurred at curves with radius of less than or equal to 800 m. Main wavelength of the corrugations is about 50−160 mm and level of the corrugations on low rails is higher than that on high rails. Passing frequency of the corrugations is in the range of 140−280 Hz, which is close to resonant frequencies (160−300 Hz) of the track with rail vibrating related to sleepers. Modal shape of the tracks exhibits rails and sleepers vertical vibrating on the slab in same and opposite directions at frequencies of 160−210, 250−300 Hz. Initiation of corrugation on the curved tracks is determined by the dynamic behavior of the tracks. Characteristic of corrugations exhibits the fixed-frequency mechanism, which means wavelength of the corrugations is related to the speed of vehicle.
-
图 2钢轨波磨现场照片(线路A,v= 55 km/h)
Figure 2.Field photos of rail corrugation (line A,v= 55 km/h)
表 1钢轨波磨状态统计
Table 1.Statistical analysis of rail corrugation
线路 扣件形式 轨枕间距/
m轨枕质量/
kg扣件垂向静刚度/
(kN•mm−1)线路状态/
m运营速度/
(km•h−1)主波长/
mm通过频率/
HzA线路 普通扣件 0.585 90 40 R= 350 50~60 60~80 174~278 400 ≤R≤ 700 60~80 80~100 167~278 R= 800 80~100 125~160 139~223 B线路 弹条Ⅱ-1型扣件 0.625 90 20 R> 800 和直线段 70~80 — — R= 350 35~40 50 194~222 
下载:
导出CSV
表 2轮轨接触参数
Table 2.Wheel-rail contact parameters
实际曲线
半径/m超高/
mm运营速度/
(km•h−1)轮轨法
向力/kN轮轨横向
蠕滑率/%接触斑大小/mm 接触位置车轮/钢轨
纵向半径/mm接触位置车轮/钢轨
横向半径/mm长半轴 短半轴 800 140 90 72.87 0.13 6.30 5.00 419.6/∞ ∞/300 600 80 70 67.80 0.14 6.14 4.90 419.5/∞ ∞/300 350 120 55 71.28 0.40 6.24 4.98 419.5/∞ ∞/300 下载:
导出CSV
-
李伟. 地铁钢轨波磨成因及其对车辆/轨道行为的影响研究[D]. 成都: 江南娱乐网页版入口官网下载安装, 2015: 47-50. 李霞,李伟,吴磊,等. 套靴轨枕轨道钢轨波磨初步研究[J]. 铁道学报,2014,36(11): 80-85.doi:10.3969/j.issn.1001-8360.2014.11.016LI Xia, LI Wei, WU Lei, et al. Preliminary study on rail corrugation of rubber booted short sleepers track[J]. Journal of the China Railway Society, 2014, 36(11): 80-85.doi:10.3969/j.issn.1001-8360.2014.11.016 GRASSIE S L, KALOUSEK J. Rail corrugation:characteristics,causes and treatments[J]. Proceedings of the Institution of Mechanical Engineers, Part F: Journal of Rail & Rapid Transit, 1993, 207(1): 57-68.doi:10.1243/PIME_PROC_1993_207_227_02 FREDERICK C O. A rail corrugation theory[C]// Proceedings of the International Symposium on Contact Mechanics and Wear of Rail-Wheel Systems. Waterloo: University of Waterloo Press, 1986: 181-211. HEMPELMANN K, HISS F, KNOTHE K, et al. The formation of wear patterns on rail tread[J]. Wear, 1991, 144(1/2): 179-195.doi:10.1016/0043-1648(91)90014-L HEMPELMANN K, KNOTHE K. An extended linear model for the prediction of short pitch corrugation[J]. Wear, 1996, 191(1/2): 161-169.doi:10.1016/0043-1648(95)06747-7 TASSILLY E, VINCENT N. Rail corrugations:analytical model and field tests[J]. Wear, 1991, 144(1/2): 163-178.doi:10.1016/0043-1648(91)90013-K TASSILLY E, VINCENT N. A linear model for the corrugation of rails[J]. Journal of Sound and Vibration, 1991, 150(1): 25-45.doi:10.1016/0022-460X(91)90400-E KURZECK B. Combined friction induced oscillations of wheelset and track during the curving of metros and their influence on corrugation[J]. Wear, 2011, 271(1): 299-310. AHILBECK D R, DANIELS L E. Investigation of rail corrugations on the Baltimore metro[J]. Wear, 1991, (1/2): 197-210.doi:10.1016/0043-1648(91)90015-M DIANA G, CHELI F, BRUNI S, et al. Experimental and numerical investigation on subway short pitch corrugation[J]. Vehicle System Dynamics, 1998, 29(S): 234-245. VADILLO E G, TARRAGO J A, ZUBIAURRE G G, et al. Effect of sleeper distance on rail corrugation[J]. Wear, 1998, 217(1): 140-146.doi:10.1016/S0043-1648(97)00239-1 LI W, WANG H Y, WEN Z F, et al. Investigation into mechanism of metro rail corrugation using experimental and theoretical methods[J]. Proceedings of the Institution of Mechanical Engineers, Part F: Journal of Rail & Rapid Transit, 2016, 230(4): 1025~1039. 李伟,温泽峰,王衡禹,等. 地铁钢轨波磨演化过程中的特性分析[J]. 机械工程学报,2018,54(4): 70-78.doi:10.3901/JME.2018.04.070LI Wei, WEN Zefeng, WANG Hengyu, et al. Analysis on the evolution characteristics of rail corrugation on a metro[J]. Journal of Mechanical Engineering, 2018, 54(4): 70-78.doi:10.3901/JME.2018.04.070 李伟,杜星,王衡禹,等. 地铁钢轨一种波磨机理的调查分析[J]. 机械工程学报,2013,49(16): 26-31.doi:10.3901/JME.2013.16.026LI Wei, DU Xing, WANG Hengyu, et al. Investigation into the mechanism of type of rail corrugation of metro[J]. Journal of Mechanical Engineering, 2013, 49(16): 26-31.doi:10.3901/JME.2013.16.026 GRASSIE S L, GREGORY R W, HARRISON D, et al. The dynamic response of railway track to high frequency vertical excitation[J]. Journal Mechanical Engineering Science, 1982, 24(2): 77-90.doi:10.1243/JMES_JOUR_1982_024_016_02 KNOTHE K, GROSS-THEBING A. Short wavelength rail corrugation and non-steady state contact mechanics[J]. Vehicle System Dynamics, 2008, 46: 49-66. MULLER S. Linearized wheel-rail dynamics-stability and corrugation[D]. Berlin: Technical University of Berlin, 1998. VINCENT N, THOMPSON D J. Track dynamic behavior at high frequencies. part 2:experimental results and comparisons with theory[J]. Vehicle System Dynamics, 1995, 24(S1): 100-114. GRASSIE S L. Rail corrugation:characteristics,causes,and treatments[J]. Proceedings of the Institution of Mechanical Engineers,Part F:Journal of Rail and Rapid Transit, 1993, 207(16): 57-596.doi:10.1243/09544097JRRT264 GRASSIE S L, EDWARDS J W. Development of corrugation as a result of varying normal load[J]. Wear, 2008, 265(9): 1150-1155.doi:10.1016/j.wear.2008.01.034 JIN X S, WEN Z F. Rail corrugation formation studied with a full-scale test facility and numerical analysis[J]. Proceedings of the Institution of Mechanical Engineers,Part J:Journal of Engineering Tribology, 2007, 221(6): 675-98.doi:10.1243/13506501JET269 -
下载:
点击查看大图
图(10)/
表(2)
计量
- 文章访问数:646
- HTML全文浏览量:449
- PDF下载量:46
- 被引次数:0