基于激光多普勒频移的钢轨缺陷监测
邢博, 余祖俊, 许西宁, 朱力强. 基于激光多普勒频移的钢轨缺陷监测[J]. 中国光学, 2018, 11(6): 991.
XING Bo, YU Zu-jun, XU Xi-ning, ZHU Li-qiang. Rail defect monitoring based on laser Doppler frequency shift theory[J]. Chinese Optics, 2018, 11(6): 991.
[1] 田贵云,高斌,高运来,等.铁路钢轨缺陷伤损巡检与监测技术综述[J].仪器仪表学报,2016,37(8): 1763-1780.
TIAN G Y,GAO B,GAO Y L,et al.. Review of railway rail defect non-destructive testing and monitoring[J]. Chinese Journal of Scientific Instrument,2016,37(8): 1763-1780.(in Chinese)
[2] 王时丽.基于机器视觉的钢轨表面缺陷检测技术研究[D].西南科技大学,2016.
WANG SH L. Research on flaw detection technology of rail surface based on machine vision[D]. Southwest University of Science and Technology,2016.(in Chinese)
[3] 杨国涛.钢轨探伤车探伤作业系统自主化研究[J].铁道建筑,2016(9): 124-126.
YANG G T. Study on the autonomy of inspection system for rail flaw detection vehicle[J]. Railway Construction,2016(9): 124-126.(in Chinese)
[4] 冯超,黎双周,范中原.基于轨道电路原理的断轨检测方法研究[J].兰州工业学院学报,2015,22(4): 75-77.
FENG CH,LI SH ZH,FAN ZH Y. Research on track fault detection method based on the principle of track circuit[J]. Journal of Lanzhou Institute of Industry,2015,22(4): 75-77.(in Chinese)
[5] 李文超,张丕状.超声波检测钢轨缺陷及定位的研究[J].核电子学与探测技术,2012,32(9): 1062-1065.
LI W CH,ZHANG P ZH. Research on ultrasonic inspection of rail defects and positioning[J]. Nuclear Electronics & Detection Technology,2012,32(9): 1062-1065.(in Chinese)
[6] MAZZOTTI M,MARZANI A,BARTOLI I,et al.. Guided waves dispersion analysis for prestressed viscoelastic waveguides by means of the SAFE method[J]. International Journal of Solids and Structures,2012,49: 2359-2372.
[7] 吴斌,符浩,何存富.超声导波虚拟相控聚焦方法研究[J].仪器仪表学报,2013,34(3): 509-516.
WU B, FU H, HE C F. Ultrasonic guided wave inspection based on synthetic phase control method[J]. Chinese Journal of Scientific Instrument,2013,34(3): 509-516.(in Chinese)
[8] 李秀明,黄战华,李翔宇,等.二维点列式激光多普勒法测量物体速度[J].光学 精密工程,2014,22(10): 2627-2632.
[9] 李一博,靳世久,孙立.超声导波在管道中的传播特性的研究[J].电子测量与仪器学报,2005,19(5): 63-66.
LI Y B,JIN SH J,SUN L. Study on propagation characteristics of ultrasonic guided wave in pipeline[J]. Journal of Electronic Measurement and Instrument,2005,19(5): 63-66.(in Chinese)
[10] 雷正,涂君,邱公喆,等.外加应力下超声导波传播特性仿真研究[J].仪表技术与传感器,2017(6): 125-128.
LEI ZH,TU J,QIU G ZH,et al.. Simulation study on transmitting characteristics of ultrasonic guided wave under external stress[J]. Instrument Technique and Sensor,2017(6): 125-128.(in Chinese)
[11] LOVEDAY P W. Semi-analytical finite element analysis of elastic waveguides subjected to axial loads[J]. Ultrasonics,2009,49(3): 298-300.
[12] ALESSANDRO MARZANI. Time-transient response for ultrasonic guided waves propagating in damped cylinders[J]. International Journal of Solids and Structures,2008,45: 6347-6368.
[13] HAYASHI T,SONG W J,ROSE J L. Guided wave dispersion curves for a bar with an arbitrary cross-section, a rod and rail example[J]. Ultrasonics,2003,41: 175-183.
[14] 许西宁, 郭保青, 余祖俊, 等.半解析有限元法求解钢轨中超声导波频散曲线[J].仪器仪表学报,2014,35(10): 2392-2398.
XU X N,GUO B Q,YU Z J,et al.. Semi-analytical finite elements method for calculating dispersion curves of ultrasonic guided waves in a rail[J]. Chinese Journal of Scientific Instrument,2014,35(10): 2392-2398.(in Chinese)
[15] 卢耀荣.无缝线路研究与应用[M].北京: 中国铁道出版社,2010: 47-48.
LU Y R. Research and Application of Continuous Welded Rail Track[M]. Beijing: China Railway Publishing House,2010: 47-48.(in Chinese)
[16] ROSE J L,AVIOLI M J,MUDGE P,et al. Guided wave inspection potential of defects in rail[J]. NDT&E International,2004(37): 153-161.
[17] 朱力强,许西宁,余祖俊,等.基于超声导波的钢轨完整性检测方法研究[J].仪器仪表学报,2016,37(7): 1603-1609.
ZHU L Q,XU X N,YU Z J,et al.. Study on the method for monitoring railway integrity based on ultrasonic guided waves[J]. Chinese Journal of Scientific Instrument,2016,37(7): 1603-1609.(in Chinese)
[18] 李翔,陈实.时频结合的失真度测量方法研究[J].国外电子测量技术,2017,36(1): 27-30.
LI X,CHEN SH. Research on time-frequency conjoined scheme for distortion measurement[J]. Foreign Electronic Measurement Technology,2017,36(1): 27-30.(in Chinese)
邢博, 余祖俊, 许西宁, 朱力强. 基于激光多普勒频移的钢轨缺陷监测[J]. 中国光学, 2018, 11(6): 991. XING Bo, YU Zu-jun, XU Xi-ning, ZHU Li-qiang. Rail defect monitoring based on laser Doppler frequency shift theory[J]. Chinese Optics, 2018, 11(6): 991.