Testing, Analysis, and CFD Modeling of a Profiled Leading Edge Groove Tilting Pad Journal Bearing

Edney, Stephen L.; Heitland, G.; DeCamillo, Scan M.

doi:10.1115/98-gt-409

Cited by 15 publications

(11 citation statements)

References 13 publications

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“…Generally, the bearings operate fully-flooded, with the lubricant filling the full width and circumference of the bearing. Previous studies suggest that bearing friction can be reduced by reducing oil feed pressure [15,16]. The reduction is at least partly explained by observations of the film in a journal bearing with a transparent bush which show that when the oil supply is restricted, cavitation develops and the film area is reduced [17,18,19].…”

Section: A Modified Oil Lubrication System With Flow Control To Reducmentioning

confidence: 81%

A Modified Oil Lubrication System with Flow Control to Reduce Crankshaft Bearing Friction in a Litre 4 Cylinder Diesel Engine

Shayler¹,

Li²,

Li³

et al. 2016

SAE Technical Paper Series

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Section: A Modified Oil Lubrication System With Flow Control To Reducmentioning

confidence: 81%

A Modified Oil Lubrication System with Flow Control to Reduce Crankshaft Bearing Friction in a Litre 4 Cylinder Diesel Engine

Shayler¹,

Li²,

Li³

et al. 2016

SAE Technical Paper Series

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“…Under such configuration, the injection nozzles located in the tilting pad surface are replaced by the leading edge groove, as the method to provide controllable pressurized oil supply to the bearing clearance. The leading edge groove has already been studied in terms of its benefits considering reduced oil consumption and reduced bearing losses, when compared to other lubrication methods [17,18,19,20]. The results obtained from the mathematical model for the proposed active bearing design validated the initial concept.…”

Section: Introductionmentioning

confidence: 78%

Component level study of an actively lubricated LEG Tilting Pad Bearing: Theory and experiment

Varela

Santos

2018

Tribology International

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This article constitutes the second step in a research effort aiming at evaluating the feasibility of introducing active characteristics into standard leading edge groove (LEG) tilting pad journal bearings. The strategy proposed is to control the LEG inlet flow using a servovalve. This work portrays the first experimental study for the"proof of concept" of this configuration, as well as a comparison with theoretical results. A simplified setup, featuring a rigid rotor supported by a single pad arrangement is the subject of study. The obtained results prove the viability of the proposed active bearing design, validate the available simulation tool and exemplify on a conceptual level the operational benefits from introducing this technology into standard LEG Tilting Pad Bearings.

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“…The relative displacement of the fluid-structure interfaces in the fluid domain is consistent with that of the solid domain. The film thickness is defined as the distance between the rotor-lubricant interface and the bearing-lubricant interface, including both rigid and elastic deformations between the two bearing surfaces as: (4) where h is film thickness, C is radial clearance of the bearing system, Δh is relative rigid displacement of the two bearing surfaces and δ is total elastic deformation of the two bearing surfaces.…”

Section: Lubricant Film Thicknessmentioning

confidence: 99%

“…FEM codes were usually used separately to calculate bearing deformations [2,3]. On the other hand, CFD codes were applied to investigate flow phenomena in the lubricating oil and water or in the regions surrounding the bearing, both in journal [4,5] and thrust bearings [6]. Reliable theoretical prediction of bearing properties requires simultaneous consideration of interacting phenomena such as lubricant flow, heat transfer and the distortion of bearing elements.…”

Section: Introductionmentioning

confidence: 99%

Thermoelastohydrodynamic Behavior of a Journal Bearing with Turbulent Flow

Ouadoud¹,

Benmahjoub²

2019

JMEA

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Turbulence is an irregular fluid motion in which the various flow properties such as velocity and pressure show random variations with time and position. A number of authors proposed different solutions e.g. for pressure distribution, temperature prediction and Thermo-Hydrodynamic (THD) analyses. In a fluid film bearing, the pressure in the oil film satisfies the Reynolds equation with a variation in the thickness of the lubricating film. In the presented cases of fluid-structure interaction analyses, all important phenomena accompanying bearing operation are considered, e.g. lubricant flow, structure movements and their deformations as well as heat transfer in case of thrust bearing. In this paper, the authors have developed an empirical relationship to determine the effect of lubrication when considering thermoelastohydrodynamic (TEHD) lubrication with turbulent flow. The critical point of this work is to import the matrix data (the pressure and temperature fields...) from the fluid domain to the internal surface of the bearing with a precision of the mesh especially in the contact surface. The results are presented in the median plane as a function of the bearing angle. A parametric study deals with the influence of rotation speed and the type of turbulence model on the pressure, temperature, deformation and stress intensity fields.

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Testing, Analysis, and CFD Modeling of a Profiled Leading Edge Groove Tilting Pad Journal Bearing

Cited by 15 publications

References 13 publications

A Modified Oil Lubrication System with Flow Control to Reduce Crankshaft Bearing Friction in a Litre 4 Cylinder Diesel Engine

A Modified Oil Lubrication System with Flow Control to Reduce Crankshaft Bearing Friction in a Litre 4 Cylinder Diesel Engine

Component level study of an actively lubricated LEG Tilting Pad Bearing: Theory and experiment

Thermoelastohydrodynamic Behavior of a Journal Bearing with Turbulent Flow

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