加速变载工况下燃料电池空压机箔片轴承转子系统轴心运动规律研究

doi:10.3901/JME.2025.23.075

机械工程学报 ›› 2025, Vol. 61 ›› Issue (23): 75-86.doi: 10.3901/JME.2025.23.075

• 机械动力学 • 上一篇

扫码分享

加速变载工况下燃料电池空压机箔片轴承转子系统轴心运动规律研究

熊万里^1,2, 汪剑¹, 薛海南¹, 陈振宇², 薛建²

1. 湖南大学国家高效磨削工程技术研究中心长沙 410082;
2. 广州市昊志机电股份有限公司广州 511356

收稿日期:2024-09-30 修回日期:2025-02-11 发布日期:2026-01-22
作者简介:熊万里(通信作者),男,1971年出生,博士,教授,博士研究生导师。主要研究方向为高速气浮燃料电池空压机、高速轴承理论及应用、超高速超精密电主轴和液体静压主轴技术。E-mail:wan369@vip.sina.com
基金资助:
国家自然科学基金资助项目(52075155)

Research on the Axis Motion of the Foil Bearing Rotor System in Fuel Cell Air Compressors under Acceleration Variable Load Conditions

XIONG Wanli^1,2, WANG Jian¹, XUE Hainan¹, CHEN Zhenyu², XUE Jian²

1. National Engineering Research Center for High Efficiency Grinding, Hunan University, Changsha 410082;
2. Guangzhou Haozhi Industrial Co., Ltd., Guangzhou 511356

Received:2024-09-30 Revised:2025-02-11 Published:2026-01-22

摘要/Abstract

摘要： 箔片气体轴承以无油润滑、高转速、低摩擦功耗以及良好的减振性能等优点，广泛应用于燃料电池空压机和飞机换气系统等领域。在燃料电池空压机实际运行中，转子不仅受到空压机的气动载荷，还需要以不同的工作转速来匹配相应的负载，转子系统在加速变负载工况下表现出复杂的瞬态动力学响应，不匹配的加速度可能导致加速过程振幅增大，进而影响转子系统的动态稳定性。针对上述问题，建立了加速变载工况下箔片气体轴承转子系统动力学模型，提出并开发了相应的数值算法，利用该模型和算法对转子系统加速变负载过渡过程的轴心轨迹等动态性能做出了合理的定量解释。搭建了箔片轴承转子系统的实验台，并开展了相应的实验验证研究。研究发现，随着转速的增加，转子涡动现象愈发明显，动态平衡稳定区域逐渐靠近轴承中心；转子在加速过渡过程中的涡动中心向恒定转速下的稳定位置移动，加速时间越长，涡动攀升过程越平稳，在加速过程的前半段时间，转子加速移动的距离大于后半段；燃料电池空压机气动载荷导致转子加速攀升过程不平滑，轴心位移与气动载荷变化一致，而气膜分力与气动载荷变化相反。实验测得的轴心运动轨迹振动幅值比理论计算值大，但运动趋势相近。

关键词: 燃料电池气悬浮空压机, 箔片气体轴承, 转子系统动力学, 加速工况, 气动载荷

Abstract: The foil gas bearings are widely used in fuel cell air compressors and aircraft ventilation systems due to their advantages of oil-free lubrication, high speed, low friction power consumption, and good vibration reduction performance. In the actual operation of fuel cell air compressors, the rotor is not only subjected to the aerodynamic load of the compressor, but also needs to match the corresponding load at different operating speeds. The rotor system exhibits complex transient response under accelerated variable load conditions. Mismatched acceleration may lead to an increase in amplitude during the acceleration process, thereby affecting the dynamic stability of the rotor system. In response to the above issues, a theoretical model of accelerated rotor dynamics of the foil gas dynamic pressure bearing rotor system is established. Corresponding numerical algorithms are proposed and developed. The model and algorithm are used to provide a reasonable quantitative explanation for the dynamic performance of the rotor system during the transition process of accelerating variable load, such as the axis trajectory. The results of research find that as the rotational speed increases, the phenomenon of rotor vortex becomes more pronounced, and the dynamic equilibrium stable region gradually approaches the center of the bearing; During the acceleration transition process, the vortex center of the rotor moves towards a stable position at a constant speed. The longer the acceleration time, the smoother the vortex climb process. In the first half of the acceleration process, the distance of the rotor moves is greater than in the second half; The aerodynamic load of the fuel cell air compressor causes an uneven acceleration and climb process of the rotor, and the axial displacement is consistent with the changes in aerodynamic load, while the gas film component is opposite to the changes in aerodynamic load.

Key words: fuel cell air compressors, foil gas bearings, rotor system dynamics, accelerated conditions, aerodynamic load

中图分类号:

TH133

熊万里, 汪剑, 薛海南, 陈振宇, 薛建. 加速变载工况下燃料电池空压机箔片轴承转子系统轴心运动规律研究[J]. 机械工程学报, 2025, 61(23): 75-86.

XIONG Wanli, WANG Jian, XUE Hainan, CHEN Zhenyu, XUE Jian. Research on the Axis Motion of the Foil Bearing Rotor System in Fuel Cell Air Compressors under Acceleration Variable Load Conditions[J]. Journal of Mechanical Engineering, 2025, 61(23): 75-86.

参考文献

[1] 熊万里,汪剑,陈振宇,等. 箔片气体动压轴承研究进展综述[J]. 机械工程学报,2022,58(21):92-113. XIONG Wanli,Wang Jian,CHEN Zhenyu. Review of research status and development of foil air bearings[J]. Journal of Mechanical Engineering,2022,58(21):92-113.
[2] YU W,SICHUAN X,NI H. Air compressors for fuel cell vehicles:An systematic review[J]. SAE International Journal of Alternative Powertrains,2015,4(1):115-122.
[3] WAN Y,GUAN J,XU S. Improved empirical parameters design method for centrifugal compressor in PEM fuel cell vehicle application[J]. International Journal of Hydrogen Energy,2017,42(8):5590-5605.
[4] HASSAN M B,BONELLO P. A new modal-based approach for modelling the bump foil structure in the simultaneous solution of foil-air bearing rotor dynamic problems[J]. Journal of Sound and Vibration,2017,396:255-273.
[5] LAI TW,GUO Y,ZHAO Q,et al. Numerical and experimental studies on stability of cryogenic turbo-expander with protuberant foil gas bearings[J]. Cryogenics,2018,96(13):62-74.
[6] GUO ZY,FENG K,LIU TY,et al. Nonlinear dynamic analysis of rigid rotor supported by gas foil bearings:Effects of gas film and foil structure on sub-synchronous vibrations[J]. Mechanical Systems and Signal Processing,2018,107(7):549-566.
[7] 王斌. 动压气体轴承动力学计算与分析[D]. 天津:天津大学,2019. WANG Bin. Calculation and analysis on dynamics of aerodynamic gas-lubricated bearings[D]. Tianjin:Tianjin University,2019.
[8] HELIO F D C,Katia L C,RAINER N. Whirl and whip instabilities in rotor-bearing system considering a nonlinear force model[J]. Journal of Sound and Vibration,2008,317(1-2):273-293.
[9] 刘万辉. 柔性动压气体轴承及其转子系统的理论和实验研究[D]. 长沙:湖南大学,2018. LIU Wanhui. Theoretical and experimental study on flexure hydrodynamic gas bearing-rotor system[D]. Changsha:Hunan University,2018.
[10] 向果. 水润滑轴承系统动态摩擦学与摩擦激励振动机理研究[D]. 重庆:重庆大学,2020. XIANG Guo. Study on dynamic tribology and friction-induced vibration mechanism of water-lubricated bearing system[D]. Chongqing:Chongqing University,2020.
[11] PATTNAYAK M R,DUTT J K,PANDEY R K. Rotordynamics of an accelerating rotor supported on aerodynamic journal bearings[J]. Tribology International,2022,176:107883.
[12] 崔淑慧,闫文民,刘奇,等. 加速方式对径向滑动轴承启停过程的影响[J]. 轴承,2024(2):9-17. CUI Shuhui,YAN Wenmin,LIU Qi,et al. Influence of acceleration modes on start-stop process of plain journal bearings[J]. Bearing,2024(2):9-17.
[13] 顾春兴,戴黎. 考虑不同加速工况的滑动轴承的启停性能分析[J]. 润滑与密封,2022,47(12):25-36. GU Chunxing,DAI Li. Analysis of start-stop performance of journal bearing considering different acceleration conditions[J]. Lubrication Engineering,2022,47(12):25-36.
[14] DWIVEDI V K,CHAND S,PANDEY K N. Effects of turbulence on dynamic performance of accelerated/decelerated hydrodynamic journal bearing system[J]. International Journal of Design Engineering,2014,5(3):256-288.
[15] 刘占生,徐方程,张广辉,等. 基于二维厚板模型的波箔片轴承静特性[J]. 航空动力学报,2012,27(6):1405-1415. LIU Zhansheng,XU Fangcheng,ZHANG Guanghui,et al. static characterization of bump-type gas foil bearing:intergration of top foil 2-D thick plate mode[J]. Journal of Aerospace Power,2012,27(6):1405-1415.
[16] IORDANOFF I. Analysis of an aerodynamic compliant foil thrust bearing:method for a rapid design[J]. Journal of Tribology,1999,121(4):816-822.

加速变载工况下燃料电池空压机箔片轴承转子系统轴心运动规律研究

Research on the Axis Motion of the Foil Bearing Rotor System in Fuel Cell Air Compressors under Acceleration Variable Load Conditions

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 5

编辑推荐

Metrics

本文评价

[1]	熊万里, 汪剑, 陈振宇, 孙文彪, 薛海南, 汤秀清. 箔片气体动压轴承研究进展综述[J]. 机械工程学报, 2022, 58(21): 92-113.
[2]	于梦阁, 张骞, 刘加利, 张继业. 随机风环境下高速列车运行安全评估研究[J]. 机械工程学报, 2018, 54(4): 245-254.
[3]	于梦阁, 刘大维, 张继业, 陈焕明. 二维随机风下高速列车非定常气动载荷研究[J]. 机械工程学报, 2016, 52(6): 108-115.
[4]	于梦阁;张继业;张卫华. 随机风作用下高速列车的非定常气动载荷[J]. , 2012, 48(20): 113-120.
[5]	李德源;刘胜祥;张湘伟. 海上风力机塔架在风波联合作用下的动力响应数值分析[J]. , 2009, 45(12): 46-52.