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Abstract

In the present study, no-load losses of different splash lubricated spiral bevel gears were measured. The authors used a specific test rig, and a set of gears, to investigate churning losses at higher tangential speeds: up to 60 m/s. An uncommon behavior of the drag torque was highlighted: the torque increased with the rotational speed until a local maximum was reached; then the torque decreased and a local minimum was noticed; at higher rotational speed the torque increased. The torque decrease seems to be linked with a windage phenomenon, which becomes non-negligible at such speeds. In this work, efforts were made to characterize this reduction of gear immersion depth in order to be able to predict no-load losses. It was found that the evolution of oil immersion was linked to a Froude number. Finally a new analytical model of no-load losses was developed for churning losses combined with windage effects. This formulation takes into account several parameters such as rotational speed, gear immersion depth, oil properties, and gear geometrical parameters.

Keywords

Churning splash lubrication spiral bevel gears power losses

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References

Lucy

. A numerical approach to the testing of fission hypothesis. Astron J 1977; 82: 1013–1024.

Concli

Gorla

. Numerical modeling of the power losses in geared transmissions: windage, churning and cavitation simulations with a new integrated approach that drastically reduces the computational effort. Tribol Int 2016; 103: 58–68.

Liu

Arfaoui

Stanic

, et al. Numerical modelling of oil distribution and churning gear power losses of gearboxes by smoothed particle hydrodynamics. Proc IMechE, Part J: J Engineering Tribology 2019; 233: 74–86.

Hirt

Nichols

. Volume of fluid (VOF) method for the dynamics of free boundaries. J Comput Phys 1981; 39: 201–225.

Concli

Gorla

. Computational and experimental analysis of the churning power losses in an industrial planetary speed reducer. WIT Trans Eng Sci 2012; 74: 287–298.

Liu

Jurkschat

Lohner

, et al. Determination of oil distribution and churning power loss of gearboxes by finite volume CFD method. Tribol Int 2017; 109: 346–354.

Jiang

Luo

, et al. Churning power losses of a gearbox with spiral bevel geared transmission. Tribol Int 2018; 129: 398–406.

Coupez

. Metric construction by length distribution tensor and edge based error for anisotropic adaptive meshing. J Comput Phys. 2011; 230: 2391–2405.

Khalloufi

Mesri

Valette

, et al. High fidelity anisotropic adaptive variational multiscale method for multiphase flows with surface tension. Comput Methods Appl Mech Eng. 2016; 307: 44–67.

10.

Seetharaman

Kahraman

. Load-independent spin power losses of a spur gear pair: model formulation. J Tribol 2009; 131: 022201–022201.

11.

Changenet

Velex

. A model for the prediction of churning losses in geared transmissions—preliminary results. J Mech Des. 2007; 129: 128–133.

12.

Changenet

Leprince

Ville

, et al. A note on flow regimes and churning loss modeling. J Mech Des 2011; 133: 121009–121009.

13.

Laruelle

Fossier

Changenet

, et al. Experimental investigations and analysis on churning losses of splash lubricated spiral bevel gears. Mech Ind 2017; 18: 412–412.

14.

Luke

Olver

. A study of churning losses in dip-lubricated spur gears. Proc IMechE, Part G: J Aerospace Engineering 1999; 213: 337–346.

15.

Kolekar

Olver

Sworski

, et al. Windage and churning effects in dipped lubrication. J Tribol. 2014; 136: 021801.

16.

Leprince G, Changenet C, Ville F, et al. Influence of oil aeration on churning losses. In: JSME 2009 international conference on motion and power transmission, Sendai, Japan, May 2009, pp.463–468.

17.

von Karman

. On laminar and turbulent friction. J Appl Math Mech 1921; 1: 233–252.

18.

Terekhov

. Hydraulic losses in gearboxes with oil immersion. Vestn Mashinostroeniya 1975; 55: 13–17.

19.

Boness RJ. Churning losses of disks and gears running partially submerged in oil. In: International power transmission and gearing conference, Chicago, IL, USA, 1989, pp.255–359.

20.

Changenet

Velex

. Housing influence on churning losses in geared transmissions. J Mech Des 2008; 130: 0626031–0626036.

21.

Neurouth

Changenet

Ville

, et al. Experimental investigations to use splash lubrication for high-speed gears. J Tribol. 2017; 139: 061104.

22.

Leprince

Changenet

Ville

, et al. Influence of aerated lubricants on gear churning losses–an engineering model. Tribol Trans. 2011; 54: 929–938.

23.

Polly

Talbot

Kahraman

, et al. An experimental investigation of churning power losses of a gearbox. J Tribol 2017; 140: 031102–031102.

24.

Chen S-W and Matsumoto S. Influence of Relative Position of Gears and Casing Wall Shape of Gear Box on Churning Loss under Splash Lubrication Condition – Some New Ideas. Tribology Transactions 2016; 59: 993–1004.

25.

ISO 14179-1: 2001. Gears – thermal capacity – part 1: rating gear drives with thermal equilibrium at 95 ℃ sump temperature, 14179-1. Geneva: ISO, 2001.

26.

Townsend DP. Dudley’s gear handbook. 2nd ed. 1992.

27.

ISO 14179-2: 2001. Gears – thermal capacity – part 2: thermal load-carrying capacity, 14179-2. 2001.

28.

Jeon S. Improving efficiency in drive lines: an experimental study on churning losses in hypoid axle. Thesis, Imperial College, UK, 2010.

29.

Leprince G, Changenet C, Ville F, et al. Investigations on oil flow rates projected on the casing walls by splashed lubricated gears. Adv Tribol. Epub ahead of print 2012. DOI: 10.1155/2012/365414.

30.

Dawson

. Windage loss in larger high-speed gears. Proc IMechE, Part A: J Power and Energy 1984; 198: 51–59.

31.

Diab

Ville

Velex

, et al. Windage losses in high speed gears—preliminary experimental and theoretical results. J Mech Des. 2004; 126: 903–908.

32.

Pallas

Marchesse

Changenet

, et al. A windage power loss model based on CFD study about the volumetric flow rate expelled by spur gears. Mech Ind 2012; 13: 317–323.

33.

Webb TA. Power losses in spiral bevel gears. Thesis, University of Nottingham, UK, 2010.

34.

Johnson G, Simmons K and Foord C. Experimental investigation into windage power loss from a shrouded spiral bevel gear. In: ASME turbo expo 2007, Montreal, Canada, 2007.

35.

Lauster

Boos

. Zum Wärmehaushalt mechanischer Schaltgetriebe für Nutzfahrzeuge. VDI-Ber 1983; 488: 45–55.

36.

Fossier

Changenet

Barday

, et al. Investigations on drive axle thermal behaviour: power loss and heat-transfer estimations. SAE Int. 2018; 11: 55–66.

37.

Rapley S, Eastwick C and Simmons K. The application of CFD to model windage power loss from a spiral bevel gear. In: ASME turbo expo 2007, Montreal, Canada, 2007.

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Churning losses of spiral bevel gears at high rotational speed

Abstract

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