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Measuring mechanical resistances of a heavy good vehicle by coastdown test

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EN
Abstrakty
EN
Mechanical resistance consists of rolling tire resistance and power losses of vehicle drive train. Rolling resistance is done by deformation of vehicle tires on road surface. Power losses represent resistances of bearings and wheels rolling and oil wading. This resistance acts continuously during vehicle wheels rotation. The value of this driving resistance is possible to test by different methods. Laboratory tests on rotating drum or dynamometer are usually used. This paper deals about rare method – coastdown exterior driving test. It was done with a casual truck trailer set. Results of this test method show the value of this resistance forces which are converted into a coefficient of mechanical resistance and discussed in the point of view of rolling resistance coefficient values.
Twórcy
  • University of Žilina, Faculty of Operation and Economics of Transport and Communications, Univerzitná 1, 010 26, Žilina, Slovak Republic
  • University of Žilina, Faculty of Operation and Economics of Transport and Communications, Univerzitná 1, 010 26, Žilina, Slovak Republic
  • University of Žilina, Faculty of Operation and Economics of Transport and Communications, Univerzitná 1, 010 26, Žilina, Slovak Republic
  • Silesian University of Technology, Faculty of Transport, 8 Krasinskiego Street, 40-019, Katowice, Poland
autor
  • University of Žilina, Faculty of Operation and Economics of Transport and Communications, Univerzitná 1, 010 26, Žilina, Slovak Republic
Bibliografia
  • 1. Babin M., Buda M. and Majercak J. Terminals for transportation of dangerous goods. Transport means 2012 : proceedings of the 16th international conference : October 25-26, 2012, Kaunas Univer-sity of Technology, Lithuania, 2012, 166-170.
  • 2. Bukova B., Brumercikova E. and Kondek P. Determinants of the EU transport market. ESM 2016 : the 2016 international conference on Engineering science and management : proceedings : August 13- 14, 2016 Zhengzhou, Henan, China, 2016, 249-252.
  • 3. Caban J. et al. Studies on operational wear of glycol-based brake fluid. Przemysl Chemiczny. vol. 94, 10/2015, 1802-1806.
  • 4. Camaj J., Lalinska J. and Masek J. Simulations of continental logistics center from the perspective of technologist. International conference on information, management science and application (ICIMSA) : 28-30 October 2014, Beijing, China. 305-308.
  • 5. Deur J., Skugor B. and Cipek M. Integration of Electric Vehicles into Energy and Transport Systems. Automatika, vol. 56, 4/2015, 395-410.
  • 6. Drozdziel P., Rybicka I., Madlenak R., Andrusiuk A. and Siluch D. The engine set damage assessment in the public transport vehicles. Advances in Science and Technology Research Journal, vol. 11, 1/2017, 117-127.
  • 7. Gasparik J., Luptak V. and Mesko P. New methodology for assessing transport connections depending on the integrated transport network. ICTTE 2016 = international conference on Traffic and transport engineering : November 24-25, 2016, Belgrade, Serbia, 2016, 388-392.
  • 8. Hausberger S., Rexeis M., Blassnegger J. and Silberholz G. Evaluation of fuel efficiency improvements in the Heavy-Duty Vehicle (HDV) sector from improved trailer and tire designs by application of a new test procedure. TU Graz, Graz, 2011.
  • 9. Hudak M. and Madlenak R. The research of driver´s gaze at the traffic signs. Innovations in science and education: CBU international conference proceedings, 4/2016, March 23-25, 2016, Prague, Czech Republic, 896-899.
  • 10. Jazar R. Vehicle Dynamics, Theory and applications. Springer Science + Bussines Media, 2009.
  • 11. Kalasova A., Cernicky L. and Hamar M. A new approach to road safety in Slovakia. Transport Sys-tems Telematics: 12th international conference on Transport systems telematics, TST 2012, Katowice - Ustroń, Poland, October 10-13, 2012, 388-395.
  • 12. Kampf R., Stopka O., Bartuska L. and Zeman K. Circulation of vehicles as an important parameter of public transport efficiency. Transport Means - Proceedings of the 19th International Scientific Con-ference on Transport Means. Kaunas (Lithuania): Kaunas University of Technology, 2015, 143-146.
  • 13. Knez M., Jereb B. and Obrecht M. Factors Influencing the Purchasing Decisions of Low Emission Cars: A Study of Slovenia. Transportation Research, Part D, Transport and Environment, 30/2014, 53-61.
  • 14. Knez M., Muneer T., Jereb B. and Cullinane K. The estimation of a driving cycle for Celje and a comparison to other European cities. Sustainable cities and society, vol. 11, 2/2014, 56-60.
  • 15. Kucera L., Gajdac I. and Mruzek M. Simulation of parameters influencing the electric vehicle range. Communications - scientific letters of UNIZA, vol. 18, 1A/2016, 59-63.
  • 16. Lopez E., Monzon A. and Pfaffenbichler P. C. Assessment of energy efficiency and sustainability scenarios in the transport system. European Transport Research Review, vol. 4, 1/2012, 47-56.
  • 17. Matuszak Z., Jaskiewicz M., Ludwinek K. and Gawecki Z. Special characteristics of reliability for serial mechatronic systems, Selected Problems of Electrical Engineering and Electronics WZEE’2015, Kielce, Poland, 2015.
  • 18. Mruzek M., Gajdac I., Kucera L. and Barta D. Analysis of parameters influencing electric vehicle range. Procedia Engineering, 134/2016, 165-174.
  • 19. Nadolski R., Ludwinek K., Staszak J. and Jaskiewicz M. Utilization of BLDC Motor In Electrical Vehicles, Przegląd Elektrotechniczny (Electrical Review), 2012.
  • 20. Ondrus J. and Hockicko P. Braking deceleration measurement using the video analysis of motions by Sw tracker. Transport and telecommunication, vol. 16, 2/2015, 127-137.
  • 21. Rajamani R. Vehicle dynamics and control. Springer, New York, 2012.
  • 22. Rievaj V. et al. The impact of air resistance on the fuel consumption in real conditions within the transport operation. Communications - scientific letters of UNIZA, vol. 18, 2/2016, 57-61.
  • 23. Skrucany T., Sarkan B. and Gnap J. Influence of Aerodynamic Trailer Devices on Dragreduction Measured in a Wind Tunnel. Eksploatacja i niezawodnosc – Maintenance and reliability, vol. 18, 1/2016, 151–154.
  • 24. Standard STN 30 0554. Road motor vehicles. Coastdown test of road motor vehicles. (Slovakia).
  • 25. Stoilova S. and Kunchev L. Application of the graph theory, AHP method and Cost Benefits Analysis for route selection of a road train. J Balk Tribol Assoc, vol. 22, 2/2016, 1041–1056.
  • 26. Van der Krieke J. and Van Raemdonck G. Analyzing Fuel Savings of an Aerodynamic Drag Reduction Device with the Aid of a Robust Linear Least Squares Method. SAE Int. J. Commer, vol. 7, 2/2014, 675-684.
  • 27. Zvolensky P., Pultznerova A. and Grencik J. The simulation calculation of acoustics energy transfer through the material structure. MATEC web of conferences: 5th international scientific conference “Integration, Partnership and Innovation in Construction Science and Education”, vol. 86, 2016, article num. 04001.
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
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