NDT Technology

NDT Technology

Non-destructive determination of side and vertical wear at the surface of railways

Document Type : Original Article

Authors
Iman Ahadi Akhlaghi 1
Hossein Norouzi Sahraei 2
Farzad Akhlaghi Modiri 2
Saeed Kahrobaee 3
1 Associate Professor. Department of Electrical Engineering, Sadjad University
2 Sadjad Center for Nondestructive Evaluation, Sadjad University
3 Associate Professor, Department of Industrial and Mechanical Engineering, Sadjad University
10.30494/jndt.2022.338794.1090
Abstract
In this study a non-destructive system was designed and fabricated to detect wear and measure its parameters on railway tracks. Delayed detection of wear on railway lines can cause critical problems and makes the repair and maintenance process more time and cost-consuming. Even worth, if the wear passes the critical value, it changes the geometry of the line, causing the derailment of the train. In the proposed method for wear detection, a system with a line laser and a camera is applied. The laser lights the surface of the rail, and the camera captures an image from it. By processing the shape of the lit pattern, which is different in worn and unworn areas, we could detect wear and estimate its several parameters. In the proposed method, after applying some preprocessing techniques to extract the shape of the lit pattern, an artificial neural network (ANN) is used to quantify w1, w2, and w3 as the three parameters of the wear. The performance of three artificial neural networks (MLP, GRNN, and RBF) to estimate w1, w2, and w3 was studied. Among all, GRNN had the best performance with the maximum error of 0.27, 0.24, and 0.32 mm, respectively for W1, W2, and W3. It shows the high efficiency of the suggested measurement system. In RDD-S11, which is currently being used in lines one and two of Mashhad Urban Railway Company to detect three common defects, the proposed method is being used to detect and measure the wear on railway tracks.
Keywords
Rail defects
Wear
Laser-camera system
Image processing
GRNN Artificial neural network
[1] I. PovilaitienÄ—, and I. PodagÄ—lis, Research into rail side wearing on curves. Transport, 18 (3), pp. 124-129, 2003.
[2] X. Jin, X. Xiao, Z. Wen, J. Guo, and M. Zhu, An investigation into the effect of train curving on wear and contact stresses of wheel and rail. Tribology International, 42 (3), pp. 475-490, 2009.
[3] F. Braghin, S. Bruni, and G. Diana, Wheel-rail contact: wear effects on vehicle dynamic behaviour. In: 2. World Tribology Congress, pp. 271-276, Vienna, Austria, 2001.
[4] U. Olofsson, and T. Telliskivi, Wear, plastic deformation and friction of two rail steels—a full-scale test and a laboratory study. Wear, 254 (1-2), pp. 80-93, 2003.
[5] Z. Liu, S. Junhua, W. Heng, and Z. Guangjun, Simple and fast rail wear measurement method based on structured light. Optics and Lasers in Engineering, 49 (11), pp. 1343-1351, 2011.
[6] G. Karaduman, K. Mehmet, and A. Erhan, Experimental fuzzy diagnosis algorithm based on image processing for rail profile measurement. in: Proceedings of 15th International Conference Mechatronika, pp. 1-6, Prague, Czech Republic, 2012. 
[7] A. Mirzaee, S. Kahrobaee, and I. A. Akhlaghi, Non-destructive determination of microstructural/mechanical properties and thickness variations in API X65 steel using magnetic hysteresis loop and artificial neural networks. Nondestructive Testing and Evaluation, 35(2), pp. 190-206, 2020.
[8] S. Kahrobaee, S. Ghanei, and M. Kashefi, Using an Artificial Neural Network for Nondestructive Evaluation of the Heat-Treating Processes for D2 Tool Steels. Journal of Materials Engineering and Performance, 28(5), pp. 3001-3011, 2019.
[9] S. Kahrobaee, H. Norouzi Sahraei, and I. A. Akhlaghi, Nondestructive characterization of microstructure and mechanical properties of heat treated H13 tool steel using magnetic hysteresis loop methodology. Research in Nondestructive Evaluation, 30 (5), pp. 303-315, 2019.
[10] S. Kahrobaee, M. S. Haghighi, and I. A. Akhlaghi, Improving nondestructive characterization of dual phase steels using data fusion. Journal of Magnetism and Magnetic Materials, 458, pp. 317-326, 2018.
[11] K. L. Priddy, and E. K. Paul, Artificial neural networks: an introduction. SPIE press, Vol. 68, 2005.
[12] N. Karayiannis, and A. N. Venetsanopoulos, Artificial neural networks: learning algorithms, performance evaluation, and applications. Springer Science & Business Media, Vol. 209, 1992. 

  • Receive Date 22 April 2022
  • Revise Date 30 May 2022
  • Accept Date 11 June 2022