Experimental study of multiphase flow in a model gearbox

Chernoray, Valery; Jahanmiri, Mohsen

doi:10.2495/mpf110131

Cited by 14 publications

(10 citation statements)

References 15 publications

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“…In between a lubricant foam (air‐lubricant mixture) generates. This foam is also present in the gaps between the teeth as shown experimentally by Chernoray . Figure N shows clearly that when the gears mate, this foam condensates ensuring the separation of the gear flanks through the formation of a lubricant layer.…”

Section: Resultsmentioning

confidence: 55%

“…This foam is also present in the gaps between the teeth as shown experimentally by Chernoray. 34 Figure 15N shows clearly that when the gears mate, this foam condensates ensuring the separation of the gear flanks through the formation of a lubricant layer. This is fundamental to reduce the friction coefficient as well as to prevent damaging like wear and scuffing.…”

Section: Automatic Proceduresmentioning

confidence: 99%

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Numerical modeling of the churning power losses in planetary gearboxes: An innovative partitioning‐based meshing methodology for the application of a computational effort reduction strategy to complex gearbox configurations

Concli

Gorla

2017

Lubrication Science

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Thanks to the recent developments in the computer science, simulations are becoming an increasingly widespread approach that can help the designers in the development of new products. In the specific field of gearboxes, simulations are used mainly for structural evaluations. However, while for the structural design beside the simulations, many analytical methods and international standard are available; for the prediction of the power losses and the efficiency of gears, neither accurate analytical methods nor automated simulation tools are available. The authors work on this topic since years and have developed new methodologies based on computational fluid dynamics. With respect to general purpose commercial software, these techniques allow a significant reduction of the computational effort and have the capability to take into account particular physical phenomena that occurs in gears, such as cavitation, and for which no information are available in literature. The purpose of this paper is to introduce a new automated mesh‐partitioning strategy implemented to extend the applicability of the previously developed computational effort reduction method to complex gearboxes getting over the geometrical limitations adopted in the past. To show the capabilities of this new strategy, we simulated a planetary gearbox that represents at the same time one of the most complicated kinematic arrangements of gears and the configuration for which the numerical fluid dynamics simulation can give the major contribution both with planar simplified models as well as with complete 3D models.

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Section: Resultsmentioning

confidence: 55%

Section: Automatic Proceduresmentioning

confidence: 99%

Numerical modeling of the churning power losses in planetary gearboxes: An innovative partitioning‐based meshing methodology for the application of a computational effort reduction strategy to complex gearbox configurations

Concli

Gorla

2017

Lubrication Science

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“…One may assume that the weakened boundary condition significantly reduces the driving efficiency of the gear compared to a viscous pump of full solid cylinder. This is not the case, as measurements by other authors, like [19] and [20] show that for large speeds, the boundary layer momentum thickness and the driven mass flow does not differ significantly between a gear with teeth and a smooth, solid cylinder which has the same width and diameter as the gear tip diameter. …”

Section: Flash Visualization Of the Typical Boundary Layermentioning

confidence: 60%

“…The authors of [19] used flash flow field visualizations and PIV on a single smooth gear and a mesh gear partially immersed in fluid in a closed large rectangular tank. Apart from the few shown visualizations, the comparison of momentum thickness distributions in the boundary layer around the immersed parts showed that for large Reynolds numbers, the momentum thickness distribution of a gear and a cylinder do not differ significantly.…”

mentioning

confidence: 99%

Mass Flux Distribution Measurements and Visualizations of a Fluid Sheet Generated by a Partially Immersed Dip-Lubricated Gear

Várhegyi

Kristóf

2016

Period. Polytech. Mech. Eng.

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IntroductionInvestigation of the flow in a gearbox of dip-lubricated transmission is a challenging task both numerically and experimentally. Such flows include two or more phases: the lubricant liquid, air and solved and insoluble additives, bubble and drop formation and coalescence, thin films, turbulence, heat and mass transport; viscoelasticity and drastic changes in other transport properties of the lubricant due to heat flash and pressure rise in the vicinity of the contact region.Despite the complex flow phenomena the designer of the transmission may very well be interested only in the power losses due to churning of the oil and the effectiveness of the dip-lubrication by verifying that the splashing oil reaches some specific locations, a gear or a bearing, which was originally not immersed in the oil bath in standstill.Several authors report successful simulations. In [1], singlephase FVM VOF k-ε simulations using dynamic mesh in a twogear transmission gearbox fully immersed in oil are presented. The authors of [2] show a two-phase flow simulation in a jetlubricated bevel gear-pair in auxiliary equipment of a jet engine using FVM, VOF and a dynamic mesh. Two-phase FVM VOF k-ε simulations are presented in [3][4][5][6][7], and CFD simulation of a full 7-speed dual clutch automotive transmission including jet and dip lubrication is presented in [8]. Having such a task as an industrial problem in the early design phase, a great difficulty is encountered when one would like to simulate such complex two-phase flows reliably within realistic time and computational constraints. In [9], the authors use a moving reference frame to obtain a quasi-steady CFD simulation of a single phase flow around a single gear. in order to have a 50-fold reduction in computational demand. In [10], a method of dimensional analysis to determine the dominant heat generation mechanism between contact heating or churning losses and then a computational method for thermohydrodynamic simulation decoupling the time scales for heat conduction in the gear and the unsteady turbulent two phase flow around a single jet lubricated gear are presented.In the above examples, mesh or turbulence or two phase model independence studies are usually not shown. This brings

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“…The reduction of the power loss can be explained looking at the way in which, with the lower static pressure, the air pillow (Figure ) that takes place around the submerged portion of the gear completely covers the teeth while for the environment pressure condition, air is trapped only in the bottom of the teeth gaps and the teeth tips interact with the lubricant (higher viscosity and density and consequent pressure peaks) causing the higher power dissipation. In dip‐lubrication, in fact, the loss is significantly dependent from the distribution of the contact areas between teeth and the lubricant …”

Section: Resultsmentioning

confidence: 99%

Effect of the static pressure on the power dissipation of gearboxes

Concli

Gorla

Rosa

et al. 2019

Lubrication Science

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Many researches were conducted in the past in order to maximise the efficiency of gearboxes, and for many of the sources of power loss, very effective models and tools are already available and can significantly help to optimise the design. Nevertheless, for the load‐independent power losses of gears only in the recent years some progress has been made. Concerning these losses, numerical simulations can help the designers in optimising the internal shape of the casing, thus ensuring the proper lubrication of all the components and reducing the undesired splashing losses. The amount of lubricant plays a fundamental role: A reduction of the lubricant can be critical from the point of view of adequate lubrication and of failures of the system due to wear, scuffing, and pitting but, on the other side, an excessive amount of lubricant leads to additional power dissipation and could even determine an overheating of the system. Another possibility to improve efficiency could be represented by the reduction of the pressure inside the housing: in this paper, the effect of the static pressure on the load‐independent power losses both for complete‐ and dip‐lubrication has been deeply studied. The numerical results, validated by experimental data, show that a reduction up to 15% of the churning losses can be achieved without reducing the amount of lubricant, that is, without increasing the risk of failures related to lubrication. Based on the results obtained, the reduction of the pressure of the housing proves to be a way to improve the efficiency, provided the related engineering issues are also addressed.

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Experimental study of multiphase flow in a model gearbox

Cited by 14 publications

References 15 publications

Numerical modeling of the churning power losses in planetary gearboxes: An innovative partitioning‐based meshing methodology for the application of a computational effort reduction strategy to complex gearbox configurations

Numerical modeling of the churning power losses in planetary gearboxes: An innovative partitioning‐based meshing methodology for the application of a computational effort reduction strategy to complex gearbox configurations

Mass Flux Distribution Measurements and Visualizations of a Fluid Sheet Generated by a Partially Immersed Dip-Lubricated Gear

Effect of the static pressure on the power dissipation of gearboxes

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