Influence of slip-flow phenomenon on thermohydrodynamic behaviour of gas foil thrust bearings

Kumar, Jitesh; Khamari, Debanshu S; Behera, Suraj K.; Sahoo, Ranjit Kumar

doi:10.1177/13506501211002962

Cited by 14 publications

(13 citation statements)

References 46 publications

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“…A separate numerical analysis was also conducted which shows forced convection in bump channels is an effective approach for better cooling at high loads. Much recently, Kumar et al 101 investigated the impact of slip flow phenomenon on THD behaviour of GFTB. The model includes the use of first-order slip velocity (equation ( 18)) at the solid-fluid interface and thus modifies Reynold's equation.…”

Section: Gftbmentioning

confidence: 99%

A review of thermohydrodynamic aspects of gas foil bearings

Kumar

Khamari

Behera

et al. 2021

Proceedings of the Institution of Mechanical Engineers, Part J:

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In recent times, gas foil bearings have become popular for commercial use in the aircraft and space industry, turbocompressors, turbine generators and in the more complex fields of turbochargers and turboexpanders. The gain in popularity for gas foil bearings is due to their features such as contamination-free zone, wide temperature range, higher stability and higher reliability characteristics as compared to other types of bearings. However, several challenges have come across while analysing the gas foil bearing behaviour at different working conditions. The current paper presents an overview of the work done in the past few decades for developing numerical models and listing the efforts of several researchers around the world to conduct the experimental investigation for predicting and analysing thermohydrodynamic behaviour of gas foil bearings at different operating conditions. It is expected that the current paper will help readers to thoroughly understand the hydrodynamic and thermal aspects of gas foil bearings.

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Section: Gftbmentioning

confidence: 99%

A review of thermohydrodynamic aspects of gas foil bearings

Kumar

Khamari

Behera

et al. 2021

Proceedings of the Institution of Mechanical Engineers, Part J:

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“…A negligible effect was observed in the parameters like torque and power loss due to the slip flow. Subsequently, Kumar et al [72] incorporated the slip-flow effect in in a GFTB model and presented a modified Reynolds equation with the first-order slip condition. It was observed that the traditional Reynolds equation has a bias towards overestimating the load-carrying capacity of the GFTB.…”

Section: Coupled Fluid-structure Modelmentioning

confidence: 99%

A Review on Modeling and Stability Aspects of Gas Foil Bearing Supported Rotors

Khamari¹,

Kumar²,

Behera³

2023

Tribol. Ind.

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Gas foil bearing rotor (GFBR) systems have received significant interest in the field of rotordynamics and vibration analysis. GFBR systems have a wide range of high-speed turbomachinery applications. Due to the high speed, these machines are susceptible to rigorous vibration and instability. Gas foil bearings instigate large amplitude of vibrations at startup and shut down and severe subsynchronous motions during high-speed operations. Over the years, numerous work has been done in the field of high-speed rotors supported on gas foil bearings. Significant improvement has been observed in the stability and feasibility of the GFBR systems. However, accurate model predictions of gas foil bearing still remain a challenge for its widespread usage in high-speed turbomachinery. A comprehensive review needs to be done to study the previous work and pave the way for future research. The current review is majorly divided into three sections. Firstly, various models used for the performance prediction of gas foil bearings are compiled. After that, major causes of instability that manifest during the experiments and practice with gas foil bearing supported rotors is illustrated. Lastly, the developmental attempts made to inhibit the instability is summarised. This paper presents an overall picture of the current engineering scenario and future prospects of the GFBR systems.

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“…It was found that the thermal expansions of the rotor and bearing structure were the main cause of TEI. Kumar 23 established a model of helium gas lubricated thrust bearing and compared the difference in the gas foil thrust bearing thermal characteristics under slip and no-slip conditions by finite difference method. Liu 24 compared and analyzed the effects of the rotating speed, bearing load and cooling airflow on the thermal distribution of foil gas bearing through experiments and simulations.…”

Section: Introductionmentioning

confidence: 99%

The fluid-thermal-structural interaction analysis of a new multifoil aerodynamic thrust bearings

Xiong,

Xu,

Huang

et al. 2023

Proceedings of the Institution of Mechanical Engineers, Part J:

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In the present study, a multiphysics simulation model was established to evaluate the effects of the fluid-thermal-structural interaction on the performance of multifoil gas lubrication thrust bearing. The thermal and elastic deformation mechanisms of multifoil bearings were studied in detail, and the effects of the preload ratio and foil structural parameters on the bearing performance were analyzed. The results show that the preload ratio determines the performance of the multifoil thrust bearing. A small preload helps the bearing maintain a low lift-off speed, whereas a large preload is helpful in improving the bearing load capacity. The thickness of the foil has a significant effect on the gas film pressure distribution and the down foil thickness plays a leading role in the load capacity.

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Influence of slip-flow phenomenon on thermohydrodynamic behaviour of gas foil thrust bearings

Cited by 14 publications

References 46 publications

A review of thermohydrodynamic aspects of gas foil bearings

A review of thermohydrodynamic aspects of gas foil bearings

A Review on Modeling and Stability Aspects of Gas Foil Bearing Supported Rotors

The fluid-thermal-structural interaction analysis of a new multifoil aerodynamic thrust bearings

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