Detection of Track Static Regularities Based on a Laser Tracker
Publication: Journal of Surveying Engineering
Volume 143, Issue 2
Abstract
This study proposes a method for detecting track static regularities based on a laser tracker. Given the laser tracker’s advantages of high tracking-measuring accuracy and high sampling rate, the proposed method integrates static and dynamic measurements and is simultaneously applicable to both fine-adjustment measurement in the construction stage and detection in the operation-maintenance stage. In this paper, the design and implementation of the hardware-integration scheme, software development, and data processing are discussed. To verify the detection and data-processing methods for track static regularity, a case study was conducted on part of the Shanghai Metro Line 13 at Nature Museum Station. An SGJ-T-CEC-I passenger-dedicated line track geometric state measurement device of China Railway Engineering Consulting Group Co., Ltd., was used for comparative analysis. The feasibility and high accuracy of the proposed method were verified by using this device.
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Acknowledgments
This work was supported by the China Special Fund for Surveying, Mapping and Geoinformation Research in the Public Interest (Grant HY14122136) and the Planned Scientific Programs of Shanghai (Grant 15ZR1443700).
References
Alippi, C., Casagrande, E., ScottiScotti, F., and Piuri, V. (2000). “Composite real-time image processing for railways track profile measurement.” IEEE Trans. Instrum. Meas., 49(3), 559–564.
API Services. (2010). “T3 product specifications.” ⟨http://apitechnical.com/Downloads/2012/T3-Product-Specifications.pdf⟩ (Dec. 1, 2014).
Chen, Q., Liu, L.-Y., Yang, Y.-H., and Li, Y.-N. (2012). “Track regularity determination model by two-way close-range photogrammetry.” J. China Railway Soc., 34(12), 83–89 (in Chinese).
Chen, Y., Shen, Y. Z., and Liu, D. J. (2004). “A simple model applies to three-dimensional datum transformation with a large angle.” Geomatics Inf. Sci. Wuhan Univ., 29(12), 1101–1105 (in Chinese).
Guangzhou South High-Speed Railway Surveying Technology. (2011). “Instruction of south high-speed railway track inspection trolley adjustment system.” ⟨http://wenku.baidu.com/view/6cb4c28884868762caaed5cb.html⟩ (Oct. 25, 2015).
Hao, Y., Zhao, J., and Fan, T. (2013). “Study of non-ballasted track fine-tuning measurement based on GRP1000.” Bull. Surv. Mapp., 4, 52–55.
Jin, X.-S., and Wen, Z.-F. (2008). “Effect of discrete track support by sleepers on rail corrugation at a curved track.” J. Sound Vib., 315(1), 279–300.
Li, Q.-X. (2006). “The direct and inverse solution in route survey and its application.” Bull. Surv. Mapp., 2, 36–47 (in Chinese).
Liu, C., Li, N., Wu, H., and Meng, X. (2014). “Detection of high-speed railway subsidence and geometry irregularity using terrestrial laser scanning.” J. Surv. Eng., 04014009.
Liu, L.-Y. (2012). “Accuracy assessment of measuring track geometric state for high speed railway with close-range photogrammetry.” M.S. thesis, Southwest Jiaotong Univ., Chengdu, China (in Chinese).
Luo, L. (2000). “High smoothness, a must for the high-speed railway track.” Chin. Railways, 10, 8–11 (in Chinese).
Luo, L., Zhang, G. M., Wu, W. Q., and Chai, X. S. (2006). Control of track regularity of wheel rail system, China Railway Publishing House, Beijing (in Chinese).
MATLAB [Computer software]. MathWorks, Natick, MA.
Meng, X., Liu, C., Li, N., and Ryding, J. (2014). “Precise determination of mini railway track with ground based laser scanning.” Surv. Rev., 46(336), 213–218.
Ministry of Railways of China. (2008). Tentative technical specifications of the measuring instrument for the geometric state of the PDL track, Chinese Railway Publishing House, Beijing (in Chinese).
Ministry of Railways of China. (2009a). Code for engineering survey of high-speed railway, Chinese Railway Publishing House, Beijing (in Chinese).
Ministry of Railways of China. (2009b). High-speed railway ballastless track engineering construction fine tuning, Chinese Railway Publishing House, Beijing (in Chinese).
Ministry of Railways of China. (2014). Code for design of high-speed railway, Chinese Railway Publishing House, Beijing (in Chinese).
Quan, S. X., Wang, P., and Chen, R. (2012). “Study on calculation methods of lateral and vertical profile irregularity of ballastless track.” J. China Railway Soc., 34(5), 81–85 (in Chinese).
RuiBang Machinery. (2013) “GJY-T-4 track detection device.” ⟨http://www.railhelper.com/?action-viewnews-itemid-99⟩ (Apr. 28, 2015).
Sichuan Tuo Tu Wei Ye Mapping Apparatus. (2009). “Leica TCA1800/TCA2003/TC2003 precision monitor total station.” ⟨http://www.scttwy.com/quanzhanyi/laika-81.html⟩ (Mar. 3, 2016).
Steenbergen, M. J. (2008). “Quantification of dynamic wheel–rail contact forces at short rail irregularities and application to measured rail welds.” J. Sound Vib., 312(4), 606–629.
Su, R. M., Zhu, M. D., and Zhu, M. H. (2012). “Application of INS+GPS integrated navigation technology in railway track regularity detection.” Bull. Surv. Mapp., supplement, 18–28 (in Chinese).
Suarez, B., Felez, J., Antonio Lozano, J., and Rodriguez, P. (2013). “Influence of the track quality and of the properties of the wheel–rail rolling contact on vehicle dynamics.” Veh. Syst. Dyn., 51(2), 301–320.
Sun, H., Yao, L., Wang, X., Zhou, Y. (2015). “Study on data processing method of track static regularities based on 3D linear coordinate system.” Railway Invest. Surv., 6, 20–25 (in Chinese).
Wang, L., Liu, C.-L., Yang, X.-F., Chen, H. (2011). “Three-dimensional adjustment calculation for free station and its precision evaluation in high-sped railway.” J. Geomatics Sci. Technol., 28(4), 258–261 (in Chinese).
Wang, Z. Y., Wei, H., Zhu, H. T., Li, L., and Qian, J. M. (2013). “Study on key algorithm of track long wave detection based on laser alignment.” Railway Standard Design, 7, 12–15 (in Chinese).
Xu, Q. R., Xu, J. M., and Li, G. Q. (2005). “Development and application of the technology of track inspection car.” Chinese Railways, 9, 37–39 (in Chinese).
Yang, C.-K. (2009). “Application of GEDO CE track detection system in slab track construction.” J. Railway Eng. Soc., 3, 57–61.
Yao, L., Sun, H., and Sun, P. (2014). “Design and accuracy test of connection device of SMR target sphere and track control point.” J. Geod. Geodynam., 34(2), 41–44 (in Chinese).
Yao, L., Sun, H., Zhou, Y., Li, N., and Sun, P. (2015). “Detection of high-speed railway track static regularity with laser trackers.” Surv. Rev., 47(343), 279–285.
Zhai, W. M. (2007). The vehicle track coupling dynamics, 3rd Ed., Science Press, Beijing (in Chinese).
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© 2016 American Society of Civil Engineers.
History
Received: Dec 30, 2015
Accepted: Jun 8, 2016
Published online: Aug 17, 2016
Discussion open until: Jan 17, 2017
Published in print: May 1, 2017
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