Numerical analysis on the performance characteristics of a new gas journal bearing by using finite difference method

Numerical analysis on the performance characteristics of a new gas journal bearing by using finite difference method

This paper proposes a novel gas journal bearing in which orifices are different in diameter and distribute unevenly. Finite Difference Method (FDM) combined with Linear Perturbation Method (LPM) is used to solve the unsteady-state Reynolds equation of the flow field in the bearing clearance. Moreove...

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Bibliographic Details
Main Authors: Yuntang Li, Ruirui Li, Yueliang Ye, Xiaolu Li, Yuan Chen
Format: Article
Language:English
Published: SAGE Publishing 2021-06-01
Series:Advances in Mechanical Engineering
Online Access:https://doi.org/10.1177/16878140211028056
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spelling doaj-a1dce767bc2346e4ba027cb397d026f82021-06-30T23:04:20ZengSAGE PublishingAdvances in Mechanical Engineering1687-81402021-06-011310.1177/16878140211028056Numerical analysis on the performance characteristics of a new gas journal bearing by using finite difference methodYuntang LiRuirui LiYueliang YeXiaolu LiYuan ChenThis paper proposes a novel gas journal bearing in which orifices are different in diameter and distribute unevenly. Finite Difference Method (FDM) combined with Linear Perturbation Method (LPM) is used to solve the unsteady-state Reynolds equation of the flow field in the bearing clearance. Moreover, four types of bearing structures are used to discuss the effects of orifices different in diameter and uneven distribution on the bearing performance. The results demonstrate that the new bearing has better static and dynamic performances compared with those of traditional bearing in which orifices are equal in diameter and distribute evenly. Moreover, thin gas film thickness, high supply pressure, and large eccentricity ratio are hopeful for improving load capacity of the new bearing. Furthermore, the stability of the novel bearing is improved if eccentricity ratio is 0.25–0.3.https://doi.org/10.1177/16878140211028056
collection DOAJ
language English
format Article
sources DOAJ
author Yuntang Li
Ruirui Li
Yueliang Ye
Xiaolu Li
Yuan Chen
spellingShingle Yuntang Li
Ruirui Li
Yueliang Ye
Xiaolu Li
Yuan Chen
Numerical analysis on the performance characteristics of a new gas journal bearing by using finite difference method
Advances in Mechanical Engineering
author_facet Yuntang Li
Ruirui Li
Yueliang Ye
Xiaolu Li
Yuan Chen
author_sort Yuntang Li
title Numerical analysis on the performance characteristics of a new gas journal bearing by using finite difference method
title_short Numerical analysis on the performance characteristics of a new gas journal bearing by using finite difference method
title_full Numerical analysis on the performance characteristics of a new gas journal bearing by using finite difference method
title_fullStr Numerical analysis on the performance characteristics of a new gas journal bearing by using finite difference method
title_full_unstemmed Numerical analysis on the performance characteristics of a new gas journal bearing by using finite difference method
title_sort numerical analysis on the performance characteristics of a new gas journal bearing by using finite difference method
publisher SAGE Publishing
series Advances in Mechanical Engineering
issn 1687-8140
publishDate 2021-06-01
description This paper proposes a novel gas journal bearing in which orifices are different in diameter and distribute unevenly. Finite Difference Method (FDM) combined with Linear Perturbation Method (LPM) is used to solve the unsteady-state Reynolds equation of the flow field in the bearing clearance. Moreover, four types of bearing structures are used to discuss the effects of orifices different in diameter and uneven distribution on the bearing performance. The results demonstrate that the new bearing has better static and dynamic performances compared with those of traditional bearing in which orifices are equal in diameter and distribute evenly. Moreover, thin gas film thickness, high supply pressure, and large eccentricity ratio are hopeful for improving load capacity of the new bearing. Furthermore, the stability of the novel bearing is improved if eccentricity ratio is 0.25–0.3.
url https://doi.org/10.1177/16878140211028056
work_keys_str_mv AT yuntangli numericalanalysisontheperformancecharacteristicsofanewgasjournalbearingbyusingfinitedifferencemethod
AT ruiruili numericalanalysisontheperformancecharacteristicsofanewgasjournalbearingbyusingfinitedifferencemethod
AT yueliangye numericalanalysisontheperformancecharacteristicsofanewgasjournalbearingbyusingfinitedifferencemethod
AT xiaoluli numericalanalysisontheperformancecharacteristicsofanewgasjournalbearingbyusingfinitedifferencemethod
AT yuanchen numericalanalysisontheperformancecharacteristicsofanewgasjournalbearingbyusingfinitedifferencemethod
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