Improving of operating ability of wheels and rail tracks

Tumanishvili, G; Nadiradze, T; Tumanishvili, I

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Tytuł artykułu

Improving of operating ability of wheels and rail tracks

Autorzy

Tumanishvili G , Nadiradze T , Tumanishvili I

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Warianty tytułu

Coversenstvovanie eksplyatacionnyh sposobnostej koles i relsovyh pytej

Języki publikacji

Abstrakty

The high cost of wheels and rails due to wear and rolling contact fatigue is one of the main problems in the railway transport. The values of creepage, sliding distance and wear rate of wheels and rails at rolling of a wheel on the rail greatly depend on geometric characteristics of working profiles of wheels and rails and location of wheels relative to rails. In the present work the functional requirements of various parts of profiles of wheels and rails and dominating kinds of their damage in various operating conditions are considered and a new profile of a wheel and device for fastening of rails are offered.

Высокая стоимость ремонтно-профилактических работ колес, из-за износа и усталостного повреждения является одным из главных проблем на железодорожном транспорте. При качении колеса на рельсе величина относительного скольжения и интенсивность изнашивания колес и рельсов значительно зависят от геометрических особенностей рабочих профилей колес и рельсов и взаимного расположения рельсов относительно колес. В данной работе рассматриваются функциональные требования различных частей профилей колес и рельсов и доминирующие виды их повреждения при различных условиях работы и предложены новые профили колес и устройства закрепления рельсов.

Słowa kluczowe

wheel-rail profile rail fastening rolling sliding wear

profil koła przytwierdzenie kolejowe walcowanie tarcie ślizgowe zużycie

Wydawca

Wydawnictwo Politechniki Śląskiej

Czasopismo

Transport Problems

Rocznik

2014

Tom

T. 9, z. 3

Strony

99--105

Opis fizyczny

Bibliogr. 16 poz.

Twórcy

autor

Tumanishvili G

Georgian Technical University 77 Kostava str. O175 Tbilisi, Georgia

autor

Nadiradze T

Georgian Technical University 77 Kostava str. O175 Tbilisi, Georgia

autor

Tumanishvili I

ge.tumanishvili@gmail.com

Georgian Technical University 77 Kostava str. O175 Tbilisi, Georgia

Bibliografia

1. Iwnicki, S.D. (ed.) A Handbook of railway vehicle dynamics. London: CRC Press. 2006.
2. Gubenko, S. & Sladkowski, A. The influence of the contact stress on the structural changes of railway wheel steel. In: Sladkowski, A. (ed.) Rail vehicle dynamics and associated problems. Gliwice: SUT. 2005. P. 135-160.
3. Lewis, R. & Dwyer-Joyce, R.S. Wear mechanisms and transitions in railway wheel steels. Proceedings of the Institution of Mechanical Engineers. Part J. Journal of Engineering Tribology. 2004. Vol. 218(6). P. 467-478.
4. Enblom, R. On simulation of uniform wheel and rail profile evolution in wheel – rail contact. PhD Thesis. Stockholm: KTH. 2006. 112 p.
5. Dwyer-Joyce, R.S. & Lewis, R. & Gao, N. & Grieve, D.G. Wear and fatigue of railway track caused by contamination, sanding and surface damage. In: 6th International Conference on Contact Mechanics and Wear of Rail/Wheel Systems (CM2003). Gothenburg: CHARMEC. 2003. P. 211-220.
6. Stodolsky, F. Railroad and Locomotive Technology Roadmap. ANL/ESD/02-6. Center for Transportation Research. Energy Systems Division Argonne National Laboratory. 2002. Available at: http://www.transportation.anl.gov/pdfs/RR/616.PDF
7. Cassidy, D. Wrought Materials May Prolong Wheel Life. International Railway Journal. 2001. No. 12. P. 40-42.
8. Collette, C. & Horodinca, M. & Preumont, A. Rotational vibration absorber for the mitigation of rail rutting corrugation. Vehicle System Dynamics. Vol. 47. No. 6. 2009. P. 641-659.
9. Thompson, D.J. & Monk-steel, A.D. & Jones, C.J.C. & Allen, P.D. & Hsu, S.S & Iwnicki. S.D. Railway noise: curve squeal, roughness growth, friction and wear. The universities center for railway system research. Report: RRUK/A3/1. June 2003.
10. Lewis, R., & Olofsson, U. (Eds). Wheel-rail interface handbook. UK: Woodhead Publishing Limited. 2009.
11. Zhu, Y. Adhesion in the wheel−rail contact under contaminated conditions. Licentiate thesis. KTH Machine design. 2011.
12. Müller, B. & Jansen, E. & de Beer, F. UIC Curve Squeal Project WP3. Swiss Federal Railways. Rail Environmental Center. 2003.
13. Chiddick, K.S. & Eadie, D.T. Wheel /rail friction management solutions. In: 14th Int. Conference on Current Problems in Rail Vehicles “PRORAIL 99”. Prague. 1999.
14. Yifei, Mo. & Turner, K.T. & Szlufarska, I. Friction laws at the nanoscale. Nature. 2009. Vol. 457. P. 1116-1119.
15. Magel, E.E. Rolling Contact Fatigue: A Comprehensive Review. NSN 7540-01-280-5500 (Rev. 2-89) Prescribed by ANSI Std. 239-18 298-102 DOT/FRA/ORD-11/24, U.S. Department of Transportation. Office of Railroad Policy and Development Washington. DC 20590. 118 p.
16. Guerrieri, M. & Parla, G. & Ticali, D. A theoretical and experimental approach to reconstructing the transverse profile of worn-out rails. Ingegneria Ferroviaria. 2012. Vol. LXVII. No. 1. P. 23-37.

Typ dokumentu

Bibliografia

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