Investigations on the power losses and thermal behaviour of rolling element bearings

Pouly, François; Changenet, Christophe; Ville, Fabrice; Velex, Philippe; Damiens, Bruno

doi:10.1243/13506501jet695

Cited by 56 publications

(45 citation statements)

References 20 publications

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“…As previously described, TNM is based on analytical equations solved for a discrete number of nodes that represent the main components, media and mechanisms of heat exchange that characterize a bearing chamber. In accordance with the approach presented in Pouly [3], the following additional assumptions/limitations:…”

Section: Fig 2 Thermocouple Positions Around the Ball Bearing Thermamentioning

confidence: 99%

“…Harris [2] shows a steady-state thermal resistance approach on a roller bearing assembly, highlighting the limitations. Pouly et al [3], again using the TNM, focus on the power losses in high-speed bearings, with emphasis on the rolling friction and drag forces losses, aside from other sources of power losses. The referred study demonstrates that the overall power losses obtained are comparable to other approaches when adjustments are made on the air fraction in the lubricant.…”

Section: Introductionmentioning

confidence: 99%

“…The study also highlights the sensitivity of temperature distribution that is dependent on heat source localisation. This is shown to vary from 70% to 100% and dependent on how the power losses are defined when predicting the heat absorbed by the oil [3].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Transient Thermal Modeling of Ball Bearing Using Finite Element Method

Sibilli

Igie

2017

Journal of Engineering for Gas Turbines and Power

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Gas turbines are fitted with rolling element bearings, which transfer loads and supports the shafts. The interaction between the rotating and stationary parts in the bearing causes a conversion of some of the power into heat, influencing the thermal behavior of the entire bearing chamber. To improve thermal modeling of bearing chambers, this work focused on modeling of the heat generated and dissipated around the bearings, in terms of magnitude and location, and the interaction with the components/systems in the bearing chamber. A thermal network (TN) model and a finite element (FE) model of an experimental high-pressure shaft ball bearing and housing were generated and a comparison to test rig results have been conducted. Nevertheless, the purpose of the thermal matching process that focused on the FE model and experimental data is to provide a template for predicting temperatures and heat transfers for other bearing models. The result of the analysis shows that the predictions of the TN are considerate, despite the simplifications. However, lower relative errors were obtained in the FE model compared to the TN model. For both methods, the highest relative error is seen to occur during transient (acceleration and deceleration). This observation highlights the importance of boundary conditions and definitions: surrounding temperatures, heat split and the oil flow, influencing both the heat transfer and heat generation. These aspects, incorporated in the modeling and benchmarked with experimental data, can help facilitate other related cases where there is limited or no experimental data for validation.

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Section: Fig 2 Thermocouple Positions Around the Ball Bearing Thermamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Transient Thermal Modeling of Ball Bearing Using Finite Element Method

Sibilli

Igie

2017

Journal of Engineering for Gas Turbines and Power

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“…The heat generated in the bearing is dissipated to the surrounding through modes of heat transfer. Most researchers [5,6,8,12,[15][16][17][18] designed thermal resistance network model to calculate the heat transfer through conduction and convection from the bearing. This method comprises of the network of resistances constructed among different components of the test bearing assembly.…”

Section: Introductionmentioning

confidence: 99%

Experimental investigation and thermal analysis of coupler-rocker ball bearing

et al. 2020

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Ball bearings are widely used in many machineries and industrial applications. Thermal behaviour of oscillating ball bearings is unknown due to its complex pendulum-like motion and is discussed in this research. In this research, the effect of operating conditions of the oscillating bearing performing coupler-rocker motion on the heat generation is experimentally investigated and verified using mathematical model. For this purpose, a coupler-rocker bearing testing rig was designed and fabricated and the test bearing is splash-lubricated in an oil sump. The loading of test bearing was done using two extension springs. The applied load on the bearing was varied from 0 to 750 N while the crank rpm was varied from 1200 rpm to 1800 rpm. Three lubricant grades were used namely, SAE30, SAE40 and SAE50. Experimental results showed that the temperature of coupler-rocker bearing approaches steady-state at about 12 minutes for all cases. The steady-state temperatures at variable conditions are observed to follow a linear trend.

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“…There are many researches on the lubrication of rolling bearings, but they are based on the study of the pressure distribution and oil film thickness of single-phase flow [3][4][5]. Coe et al [6][7] through the temperature field analysis and experiment of bearing. Parker [8][9] compares the heat production, temperature and lubricating oil of three kinds of angular contact ball bearings, and presents an empirical formula for oil content: (1) Among them, XCAV is the volume fraction of lubricant in the bearing cavity, which is used to characterize the degree of mixing of oil and gas, W is the oil supply, N is the bearing speed, and d m is the bearing pitch diameter.…”

Section: Introductionmentioning

confidence: 99%

Two Phase Flow Pattern of Injection Lubrication in High Speed Bearings

Li¹,

Zhang²,

Huang³

2017

dtetr

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Abstract. In this paper, the study of Numerical analysis of bearing lubrication flow field is presented. When the lubricating oil flows into the bearing, the fluid distribution in the radial direction assumes a gradient state under the influence of the centrifugal force at high speed. Through the experiment, it is recommended to be more than the angle of 45 0 of the nozzle lubrication. With variable contact radius, the fluid gathered more concentrated, which is not conducive to the rolling lubrication and cooling. When R arc of contactor is not 0mm, the contact wear section is shown the horizontal elliptical shape, and as the radius decreases, the elliptical axis increases, and more requirements of bearing lubrication conditions in this case.

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Investigations on the power losses and thermal behaviour of rolling element bearings

Cited by 56 publications

References 20 publications

Transient Thermal Modeling of Ball Bearing Using Finite Element Method

Transient Thermal Modeling of Ball Bearing Using Finite Element Method

Experimental investigation and thermal analysis of coupler-rocker ball bearing

Two Phase Flow Pattern of Injection Lubrication in High Speed Bearings

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