Innovative Diagnostics of the Railway Track Superstructure

Abstract The physical nature of optical, optometric and photometric materials diagnostics systems in industrial production and in the transport industry is currently undergoing revolutionary changes. There is not enough theoretical and practical information on the scientific market about fundamental changes in this scientific field. Extreme precision and highly efficient materials, which are currently used in the construction of various devices for diagnostics and defectoscopy of materials and their parameters, require new research of phenomena and research derived from various types of optical devices and software tools and electronic software. expert systems. The article describes the basic characteristics of rail grate diagnostics. It brings the output of the solved project “Research of New Phenomena and Observable Facts of New Generation Diagnostic Systems in Industrial Production and in the Transport Industry – Research of the Physical Nature of the Automated Video Inspection System of the Rail Grate” the aim of which is to innovate the diagnostic procedures of the track surface - specifically the track grate.

[1]  Rudolf Kampf,et al.  Optimisation in Transport and Logistic Processes , 2020 .

[2]  Rudolf Kampf,et al.  Optimization of Logistics Processes During the Production of Wood Chips , 2020 .

[3]  Hlatká Martina,et al.  Modelling a production process using a Sankey diagram and Computerized Relative Allocation of Facilities Technique (CRAFT) , 2019, Open Engineering.

[4]  L. Tvrdon,et al.  Usage of Dynamic Simulation in Pressing Shop Production System Design , 2020 .

[5]  Ondrej Stopka,et al.  Proposal of the Inventory Management Automatic Identification System in the Manufacturing Enterprise Applying the Multi-criteria Analysis Methods , 2019 .

[6]  Gabriel Fedorko,et al.  Failure analysis concerning causes of wear for bridge crane rails and wheels , 2020 .

[8]  Borna Abramović,et al.  New Graphical Approach to Railway Infrastructure Capacity Analysis , 2015 .

[9]  Peter Blaho,et al.  Capacity of Main Railway Lines – Analysis of Methodologies for its Calculation , 2018 .

[10]  Tomislav Josip Mlinarić,et al.  METHODS FOR DETERMINING THROUGHPUT CAPACITY OF RAILWAY LINES USING COEFFICIENTS OF ELIMINATION , 2004 .

[11]  Juraj Camaj,et al.  CHARGING RAILWAY INFRASTRUCTURE MODELS AND THEIR IMPACT TO COMPETITIVENESS OF RAILWAY TRANSPORT , 2017 .

[12]  Vladislav Zitrický,et al.  Failure analysis of cyclic damage to a railway rail – A case study , 2020 .

[13]  P. Droździel,et al.  Prospects Of International Freight Transport In The East-West Direction , 2015 .