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Meccanica

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01.05.2014

Non-Newtonian mixed elastohydrodynamics of differential hypoid gears at high loads

verfasst von: M. Mohammadpour, S. Theodossiades, H. Rahnejat, T. Saunders

Erschienen in: Meccanica | Ausgabe 5/2014

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Abstract

Prediction of friction and transmission efficiency are design objectives in transmission engineering. Unlike spur and helical involute gears, there is a dearth of numerical analysis in the case of hypoid gear pairs. In particular, it is important to take into account the side leakage of the lubricant from the contact as the result of the lubricant entrainment at an angle to the elliptical contact footprint. In the automobile differential hypoid gears, high loads result in non-Newtonian behaviour of the lubricant, which may exceed its limiting shear stress, a fact which has not been taken into account in the open literature. This results in conditions which deviate from observed experimental tractive behaviour. The paper takes into account these salient practical features of hypoid gear pair analysis under high load. It highlights a non-Newtonian shear model, which limits the lubricant shear behaviour. Prediction of friction and transmission efficiency is in line with those reported in the literature.

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Rahnejat H (2010) Tribology and dynamics of engine and powertrain. Woodhead, Cambridge

Mehdigoli H, Rahnejat H, Gohar R (1990) Vibration response of wavy surfaced disc in elastohydrodynamic rolling contact. Wear 139(1):1–15 CrossRef

Rahnejat H (1998) Multi-body dynamics: vehicles. Machines and mechanisms. PEP (IMechE) and SAE, Bury St Edmund, and Warrandale

Denny CM (1998) Mesh friction in gearing. AGMA, Technical Paper No. 98FTM2

Michlin Y, Myunster V (2002) Determination of power losses in gear transmissions with rolling and sliding friction incorporated. Mech Mach Theory 37:167–174 CrossRefMATH

De la Cruz M, Theodossiades S, Rahnejat H (2010) An investigation of manual transmission drive rattle. Proc Inst Mech Eng, Proc, Part K, J Multi-Body Dyn 224:167–181

De la Cruz M, Chong WWF, Teodorescu M, Theodossiades S, Rahnejat H (2012) Transient mixed thermo-elastohydrodynamic lubrication in multi-speed transmissions. Tribol Int 49:17–29 CrossRef

Misharin YA (1958) Influence of the friction condition on the magnitude of the friction coefficient in the case of rollers with sliding. In: Proc int conf on gearing, IMechE, London, UK, pp 159–164

Benedict GH, Kelly BW (1960) Instantaneous coefficients of gear tooth friction. ASLE Trans 4:59–70 CrossRef

10.

He S, Gunda R, Singh R (2007) Effect of sliding friction on the dynamics of spur gear pair with realistic time-varying stiffness. J Sound Vib 301:927–949 CrossRefADS

11.

Velex P, Cahouet V (2000) Experimental and numerical investigations on the influence of tooth friction in spur and helical gear dynamics. J Mech Des 122:515–522 CrossRef

12.

Velex P, Sainsot P (2002) An analytical study of tooth friction excitations in errorless spur and helical gears. Mech Mach Theory 37:641–658 CrossRefMATH

13.

Kar C, Mohanty AR (2007) An algorithm for determination of time-varying frictional force and torque in a helical gear system. Mech Mach Theory 42:482–496 CrossRefMATH

14.

Karagiannis I, Theodossiades S, Rahnejat H (2012) On the dynamics of lubricated hypoid gears. Mech Mach Theory 48:94–120 CrossRef

15.

Grubin AN (1949) Contact stresses in toothed gears and worm gears. Book 30 CSRI for technology and mechanical engineering. DSRI Trans, Moscow, p 337

16.

Li S, Kahraman A (2010) A transient mixed elastohydrodynamic lubrication model for spur gear pairs. J Tribol 132(1):011501 CrossRef

17.

Litvin FL, Fuentes A, Fan Q, Handschuh RF (2002) Computerized design, simulation of meshing, and contact and stress analysis of face-milled formate generated spiral bevel gears. Mech Mach Theory 37:441–459 CrossRefMATH

18.

Xu H, Kahraman A (2007) Prediction of friction-related power losses of hypoid gear pairs. Proc Inst Mech Eng, Proc, Part K, J Multi-Body Dyn 221:387–400

19.

Kolivand M, Li S, Kahraman A (2010) Prediction of mechanical gear mesh efficiency of hypoid gear pairs. Mech Mach Theory 45:1568–1582 CrossRefMATH

20.

Simon V (2009) Influence of machine tool setting parameters on EHD lubrication in hypoid gears. Mech Mach Theory 44:923–937 CrossRefMATH

21.

Mohammadpour M, Theodossiades S, Rahnejat H (2012) Elastohydrodynamic lubrication of hypoid gears at high loads. Proc Inst Mech Eng, Part J J Eng Tribol 226(3):183–198 CrossRef

22.

Hamrock BJ, Dowson D (1977) Isothermal elastohydrodynamic lubrication of point contacts. Part IV—starvation results. J Lubr Technol 99:15–23 CrossRef

23.

Gabiccini M, Bracci A, Guiggiani M (2010) Robust optimization of the loaded contact pattern in hypoid gears with uncertain misalignments. J Mech Des 132:041010 CrossRef

24.

Lunin SV (2001) New discoveries in WN gear geometries. www.zakgear.com

25.

Gohar R (1971) Oil film thickness and rolling friction in elastohydrodynamic point contact. J Lubr Technol 93:371–382 CrossRef

26.

Jalali-Vahid D, Rahnejat H, Gohar R, Jin ZM (2000) Prediction of oil-film thickness and shape in elliptical point contacts under combined rolling and sliding motion. Proc Inst Mech Eng, Part J J Eng Tribol 214:427–437 CrossRef

27.

Bair S, Winer WO (1979) Shear strength measurements of lubricants at high loads. J Lubr Technol 101:251–257 CrossRef

28.

Greenwood JA, Tripp JH (1970) The contact of two nominally flat rough surfaces. Proc Inst Mech Eng 185:625–633 CrossRef

29.

Vijayakar S (2000) CALYX manual. Advanced Numerical Solutions Inc, Columbus

30.

Johnson KL, Tevaarwerk JL (1977) Shear behaviour of elastohydrodynamic oil films. Proc R Soc Lond Ser A, Math Phys Sci 356:215–236 CrossRefMATHADS

31.

Olver AV, Spikes HS (1998) Prediction of traction in elastohydrodynamic lubrication. Proc Inst Mech Eng, Part J J Eng Tribol 212:321–332 CrossRef

32.

Gohar R, Rahnejat H (2008) Fundamentals of tribology. Imperial College Press, London CrossRefMATH

33.

Eyring H (1936) Viscosity, plasticity and diffusion as examples of absolute reaction rates. J Chem Phys 4:283 CrossRefADS

34.

Hirst W, Moore AJ (1974) Non-Newtonian behaviour in elastohydrodynamic lubrication. Proc R Soc Lond 337:101–121 CrossRefADS

35.

Hamilton GM, Moore SL (1971) Deformation and pressure in an elastohydrodynamic contact. Proc R Soc Lond 322(1550):313–330 CrossRefADS

36.

Evans CR, Johnson KL (1986) Regimes of traction in EHD lubrication. Proc Inst Mech Eng, Part C, J Mech Eng Sci 200:313–324 CrossRef

37.

Hirst W, Moore AJ (1979) Elastohydrodynamic lubrication at high pressures II: non-Newtonian behaviour. Proc R Soc Lond 365:537–565 CrossRefADS

38.

Lee RT, Hamrock BJ (1990) A circular non-Newtonian fluid model, part I, used in elastohydrodynamic lubrication. J Tribol 112:486–496 CrossRef

39.

Crook AW (1961) The lubrication of rollers III: a theoretical discussion of friction and the temperatures in the oil film. Proc R Soc Lond 254(1040):237–258 ADS

40.

Johnson KL, Greenwood JA (1980) Thermal analysis of an Eyring fluid in elastohydrodynamic traction. Wear 61:353–374 CrossRef

41.

Spikes HA, Olver AV, Macpherson PB (1986) Wear in rolling contacts. Wear 112(2):121–144 CrossRef

42.

Conry TF, Wang S, Cusano C (1987) A Reynolds-Eyring equation for elastohydrodynamic lubrication in line contacts. J Tribol 109:648–658 CrossRef

43.

Wang S, Cusano C, Conry TF (1991) Thermal analysis of elastohydrodynamic lubrication of line contacts using the Ree-Eyring fluid model. J Tribol 113:232–244 CrossRef

44.

Kim KH, Sadeghi F (1991) Non-Newtonian elastohydrodynamic lubrication of point contacts. J Tribol 113:703–711 CrossRef

45.

Teodorescu M, Votsios V, Rahnejat H, Taraza D (2006) Jounce and impact in cam-tappet conjunction induced by the elastodynamics of valve train system. Meccanica 41(2):157–171 CrossRefMATH

46.

Ciulli E (2009) Non-steady state non-conformal contacts: friction and film thickness studies. Meccanica 44(4):409–425 CrossRefMATH

47.

Briscoe BJ, Evans DCB (1982) The shear properties of Langmuir-Blodgett layers. Proc R Soc Lond Ser A, Math Phys Sci 380(1779):389–407 CrossRefADS

48.

Patir N, Cheng HS (1978) An average flow model for determining effects of three-dimensional roughness on partial hydrodynamic lubrication. J Lubr Technol 100:12–17 CrossRef

49.

Roeland CJA (1966) Correlation aspect of the viscosity–temperature–pressure relation of lubrication oils. PhD Thesis, Delft University of Technology, The Netherlands

50.

Dowson D, Higginson GR (1959) A numerical solution to the elastohydrodynamic problem. Proc Inst Mech Eng, Part C, J Mech Eng Sci 1:6–15 MATH

51.

Birkhoff J, Hays DF (1963) Free boundaries in partial lubrication. J Math Phys 32:2 MathSciNet

52.

Gohar R (2001) Elastohydrodynamics. Imperial College Press, London

53.

Ali F, Křupka I, Hartl M (2013) Analytical and experimental investigation on friction of non-conformal point contacts under starved lubrication. Meccanica 48(3):545–553 CrossRef

54.

Swift HW (1932) The wetability of lubricating films in journal bearings. Minutes of the proc. J Inst Civ Eng 223:267–288

55.

Stieber W (1933) Das schwimmlager: hydrodynamische theorie des gleitlagers. VDI Verlag, Dusseldorf MATH

56.

Vaishya M, Singh R (2001) Analysis of periodically varying gear mesh systems with Coulomb friction using Floquet theory. J Sound Vib 243:525–545 CrossRefADS

57.

Jalali-Vahid D, Rahnejat H, Jin ZM, Dowson D (2001) Transient analysis of isothermal elastohydrodynamic circular point contacts. Proc Inst Mech Eng, Part C, J Mech Eng Sci 215:1159–1172 CrossRef

58.

Bair S (2001) The variation of viscosity with temperature and pressure for various real lubricants. J Tribol 123:433–436 CrossRef

59.

Akin LS (1974) EHD lubricant film thickness formulae for power transmission gears. J Lubr Technol, 426–431

60.

Simon V (1988) Thermo-EHD analysis of lubrication of helical gears. J Mech Des 110:330–336

61.

Naruse C, Haizuka S, Nemoto R, Umezu T (1986) Limiting loads for scoring and frictional loss of hypoid gear. Bull JSME 29(253):2271–2280 CrossRef

62.

Buckingham E (1963) Efficiencies of gears in analytical mechanics of gears. Dover, New York, pp 395–425

63.

Xu H, Kahraman A, Houser DR (2005) A model to predict friction losses of hypoid gears. AGMA Tech. Pap.: 05FTM06

64.

Hurley JD (2009) An experimental investigation of thermal behaviour of an automotive rear axle. MSc thesis, The Ohio State University

65.

Teodorescu M, Taraza D, Henein NA, Bryzik W (2003) Simplified elasto-hydrodynamic friction model of the cam—tappet contact. Trans SAE, J Engine. doi:10.4271/2003-01-0985

66.

Olver AV (2002) Gear lubrication—a review. Proc Inst Mech Eng, Part J J Eng Tribol 216(5):255–267 CrossRef

67.

Evans HP, Snidle RW (1982) The elastohydrodynamic lubrication of point contacts at heavy loads. Proc R Soc Lond Ser A, Math Phys Sci 382(1782):183–199 CrossRefMATHADS

68.

Evans HP, Snidle RW (1983) Analysis of elastohydrodynamic lubrication of elliptical contacts with rolling along the major axis. J Mech Eng Sci 197(3):209–211 CrossRef

69.

Tipei N (1968) Boundary conditions of a viscous flow between surfaces with rolling and sliding motion. J Lubr Technol 90(1):254–261 CrossRef

Titel: Non-Newtonian mixed elastohydrodynamics of differential hypoid gears at high loads
verfasst von: M. Mohammadpour
S. Theodossiades
H. Rahnejat
T. Saunders
Publikationsdatum: 01.05.2014
Verlag: Springer Netherlands
Erschienen in: Meccanica / Ausgabe 5/2014
Print ISSN: 0025-6455
Elektronische ISSN: 1572-9648
DOI: https://doi.org/10.1007/s11012-013-9857-x

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