Influence of oil flow rate and rotational speed on load-independent power losses in an oil-jet lubricated planetary gear set

Abstract

This paper focuses on the study of the load-independent power losses generated by a complete planetary gearbox having a rotating ring gear and a fixed planet carrier. First, different configurations are studied to characterize the various losses such as those associated to bearings. The power losses generated by the complete gearbox is then measured thanks to a dedicated test bench. Those tests enable to determine a power loss distribution that is then validated using a thermal network analysis. Once the windage and the oil churning losses are estimated, their evolution with rotational speed and oil flow rate is investigated. The study reveals that the windage power losses, generated by the reduced scale planetary gearbox studied, do not increase with the cube of the rotational speed within the tested speed range. The oil churning losses evolve linearly with the oil flow rate and quasi linearly with speed. Finally, the evolution of the power loss distribution with respect to the rotational speed is presented.

Keywords

Planetary gearbox load-independent power loss oil jet lubrication rotational speed oil flow rate

Get full access to this article

View all access options for this article.

References

Handschuh

Rohn

. Efficiency testing of a helicopter transmission planetary reduction stage, 1988.

Krantz

. Experimental and analytical evaluation of efficiency of helicopter planetary stage, 1990.

Anderson

Loewenthal

Black

. An analytical method to predict efficiency of aircraft gearboxes. AIAA Paper 1984;(NASA TM-83716): 84–1500.

ISO/TR 14179-2:2001 Gears - Thermal capacity part 2: Thermal load-carrying capacity.

Benedict

Kelley

. Instantaneous coefficients of gear tooth friction. Tribol Trans 1961; 4: 59–70.

Kelley

Lemanski

. Lubrication of involute gearing. Proc Inst Mech Eng Conf Proc 1967; 182: 173–184.

Johnson

Tevaarwerk

. Shear behaviour of elastohydrodynamic oil films. Proc R Soc Lond A Math Phys Sci 1977; 356: 215–236.

Diab

Ville

Velex

. Prediction of power losses due to tooth friction in gears. Tribol Trans 2006; 49: 260–270.

Anderson

Loewenthal

. Effect of geometry and operating conditions on spur gear system power loss. ASME J Mech Des 1981; 103: 151–159.

10.

Dawson

. Windage loss in larger high-speed gears. Proc Inst Mech Eng Part A Power Process Eng 1984; 198: 51–59.

11.

Diab

Ville

Velex

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

12.

Ariura

Ueno

Sunaga

, et al. The lubricant churning loss in spur gear systems. Bulletin JSME 1973 May; 16: 881–892.

13.

Massini

Fondelli

Facchini

, et al. Windage losses of a meshing gear pair measured at different working conditions. In Proceedings of the ASME Turbo Expo 2018: turbomachinery technical conference and exposition. Volume 5B: heat transfer, 2018.

14.

Mauz

. Hydraulische Verluste von Strinradgetriebe bei Umfangsgeschwindigkeit bis 60m/s. 1987.

15.

Hill

Kunz

Medvitz

, et al. CFD analysis of gear windage losses: Validation and parametric aerodynamic studies. J Fluids Eng Trans ASME 2011; 133: 33–45.

16.

Massini

Fondelli

Facchini

, et al. Experimental investigation on power Losses due to oil jet lubrication in high speed gearing systems. In Proceedings of the ASME Turbo Expo 2017: turbomachinery technical conference and exposition. Volume 5B: heat transfer, 2017.

17.

Ruzek

Ville

Velex

, et al. On windage losses in high-speed pinion-gear pairs. Mech Mach Theory 2019; 132: 123–132.

18.

Seetharaman

Kahraman

. Load-independent spin power losses of a spur gear pair: model formulation. J Tribol 2009; 131: 1–11.

19.

Durand de Gevigney

Changenet

Ville

. Analysis of no-load dependent power losses in a planetary gear train by using thermal network method. In International gear conference, 2014.

20.

Kahraman

Hilty

Singh

. An experimental investigation of spin power losses of a planetary gear set. Mech Mach Theory 2015; 86: 48–61.

21.

Winger

Marchesse

Touret

, et al. Investigations on spin power losses generated in a planetary gear set using thermal network method. Lubricants 2024; 12: 366.

22.

Changenet

Oviedo-Marlot

Velex

. Power loss predictions in geared transmissions using thermal networks-applications to a six-speed manual gearbox. J Mech Des 2006; 128: 618–625.

23.

Durand de Gevigney

Changenet

Ville

, et al. Thermal modelling of a back-to-back gearbox test machine: application to the FZG test rig. Proc Inst Mech Eng Part J J Eng Tribol 2012; 226: 501–515.

24.

Shore

Christodoulias

Kolekar

, et al. Predicting electric vehicle transmission efficiency using thermally coupled lubrication model. In 23rd International colloquium tribology: industrial an automotive lubrication 2022; 453–455.

25.

Pouly

Changenet

Ville

, et al. Investigations on the power losses and thermal behaviour of rolling element bearing. Proc Inst Mech Eng Part J J Eng Tribol 2010; 224: 925–933.

26.

Harris

. Rolling bearing analysis. 3rd ed. NewYork: Wiley, 1991.

27.

Pallas

Marchesse

Changenet

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

28.

Massini

Fondelli

Andreini

, et al. Experimental and numerical investigation on windage power losses in high speed gears. J Eng Gas Turbines Power 2018; 140: 082508.

29.

Holman

. Heat transfer. 7th ed. New York: Mac Graw, 1989.

30.

Becker

. Measurement of convective heat transfer form a horizontal cylinder rotating in a tank of water. J Heat Mass Transfer 1963; 6: 1053–1062.