Railway wheel failure occurs when metal spalls from the tread to produce flat or out-of-round wheels that cause high dynamic forces. Spalls initiate in brittle martensite formed by the frictional heat produced during wheel slide. The current paper calculates the temperatures developed in the sliding wheel and discusses consequences of the rates of change of temperature on metallurgical means of avoiding spalls.
MagelE.KalousekJ.Identifying and interpreting railway wheel defects. In International Heavy Haul Conference on Freight Car Trucks and Bogies, IHHA, Quebec, 1996, pp. 5.7–21.
2.
MagelE.SawleyK. J.SrobaP.KalousekJ.A practical approach to controlling rolling contact fatigue in railways. In Proceedings 8th International Heavy Haul Association Conference, Rio de Janeiro, June 2005, pp. 447–456.
3.
FecM. C.SehitogluH.A low-cycle fatigue analysis approach to the problem of wheel thermal failure. In Proceedings 8th International Wheelset Congress, Madrid, 1985, vol. 2 (paper V.1), pp. 1–12.
4.
HoffmannD. R. Railway Supply Association Technical Conference, Car Department Officers Association, Chicago, September 15, 1997.
5.
TunnaJ. M.Forces due to wheel irregularities. In Proceedings 9th International Wheelset Congress, Montreal, 1988, paper 6–2, pp. 1–14.
6.
JaegerJ. C.Moving sources of heat and the temperature of sliding contactsProc. R. Soc. New South Wales, 1943, 76, 203–224.
7.
BlokH.The flash temperature conceptWear, 1963, 6, 483–494.
8.
El-SherbinyM.NewcombT. P.The temperature distribution due to frictional heat generated between a stationary cylinder and a rotating cylinderWear, 1977, 42, 23–34.
9.
ArchardJ. F.The temperature of rubbing surfacesWear, 1958/59, 2, 438–455.
10.
ArchardJ. F.RowntreeR. A.Metallurgical phase transformations in the rubbing of steelsProc. R. Soc. Lond. A., 1988, 418, 405–424.
KennedyT. C.Transient heat partition factor for a sliding railcar wheelWear2006, 261, 932–936.
13.
TanvirM. A.Temperature rise due to slip between wheel and rail - an analytical solution for Hertzian contactWear1980, 61, 295–308.
14.
KnotheK.LiebeltS.Determination of temperatures for sliding contact with applications for wheel-rail systemsWear1995, 189, 91–99.
15.
FischerF. DWernerE.YanW.-Y.Thermal stresses for frictional contact in wheel-rail systemsWear1997, 211, 156–163.
16.
JergeusJ.Martensite formation and damage around railway wheel flats. In Proceedings 6th International Heavy Haul Association Conference, Cape Town, June 1997, 889–904.
17.
GuptaV.HahnG.T.BastiasP. C.RubinC. A.Calculations of the frictional heating of a locomotive wheel attending rolling plus slidingWear1996, 191, 237–241.
18.
JergéusJ.Railway wheel flats - martensite formation, residual stresses, and crack propagation. Doctoral Dissertation, Chalmers Solid Mechanics, Gothenburg, January 1998, p. 111.
19.
SawleyK. J.RosserJ. A.Tread damage in discbraked wheels. In Proceedings of 9th International Wheelsets Congress, Montreal, 1988, 5.4.1–5.4.10.
20.
RymuzaZ.Energy concept of the coefficient of frictionWear1996, 199, 187–196.
21.
OosterkampW. J.The heat dissipation in the anode of an X-ray tubePhilips Res. Rep.1948, 3, 49–59.
22.
CarslawH. S.JaegerJ. C.Conduction of heat in solids1959, p. 76 (Oxford University Press, Oxford).
23.
SalzerH. E.Formulas for calculating the error function of a complex variableMath. Tables Aids Comp.1951, 5, 67–70.
24.
CarslawH. S.JaegerJ. C.Conduction of heat in solids1959, p. 75 (Oxford University Press, Oxford).
25.
IwandH. C.StoneD. H.MoyarG. J. A thermal and metallurgical analysis of martensite formation and tread spalling during wheel slip. Rail Transportation-1992, RTD, ASME, New York, 1992, Vol. 5, 105–116.
26.
AtkinsM. Atlas of continuous cooling transformation diagrams for engineering steels. British Steel Corporation, 1977.
27.
RoseV. A.StrassnerW.Kinetik der austenitbildung unlegierter und niedriglegierter untereutektoidischer StähleStahl u. Eisen1956, 7, 6976–983.
28.
HillertM.NilssonK.TorndahlL.-E. Effect of alloying elements on the formation of austenite and dissolution of cementite. JISI, January 1971, 49–66.
29.
KristanJ. V.StoneD. H.Railroad wheel alloy developed to inhibit spall formation as a result of wheel slide. In Proceedings of 14th International Wheelset Congress, Orlando, October 2004, paper 2.3, 1–8.
30.
MalikH. I.The effect of alloying elements on pearlite nucleationArchiv fur das Eisenhuttenwesen1971, 42(4), 287–291.
31.
MehlR. F.HagelW. C.The austenite: pearlite reactionProg. Metal Phys.1956, 6, 74–134.
32.
SunJ.SawleyK. J.StoneD. H.TeterD. F.Progress in the reduction of wheel spalling. In Proceedings of 12th International Wheelset Congress, Qingdao, September 1998, 18–29.
33.
StoneD. H.SawleyK. J.Railway wheels resistant to martensite formation. US Pat. 6,387, 191, 2002.
34.
SawleyK. J.BenyonJ. A.JonesE. G.Bainitic steels for railway wheels. In Proceedings of 9th International Wheelset Congress, Montreal, 2.6.1–2.6.12.
35.
KarlssonT.GhidiniA.GianniA.EkbergA.Innovative bainitic steel grade for solid wheels tested in Arctic heavy haul operations. CM2006: In Proceedings of 7th International Conference on Contact Mechanics of Wear of Rail/Wheel Systems, 2006, vol. 1, 303–308.
