超静定转子系统不对中动力学的理论与实验研究

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摘要不对中是多支承转子系统最常见的故障之一，超静定转子系统（SIRS）由于结构的特殊性而对支点的不对中表现得更加敏感。航空发动机低压转子经常采用三支点支承的方式，当套齿连接结构径向定位间隙较小时，就会构成了一个含有3个弹性支承的超静定转子系统。结合力法和达朗贝尔虚功原理，推导了尾部支承不对中情况下超静定转子系统的动力学方程和解析解，计算获得了其振动响应。以航空发动机超静定转子系统为研究对象，对其完全对中和尾部支点不对中状态展开解析模型推导和实验验证工作。理论和实验结果均表明，该系统由于支点的不对中不仅会对转子的转子产生动态附加激励，还会引起系统2X振动响应和内“8”字形响应轴心轨迹，理论和实验结果吻合良好。该研究对超静定转子系统动力学不对中情况下的响应计算及实验研究有较强的指导价值。

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	赵广
	王亭月
	李盛翔
	李方忠
	马文生

关键词 ：超静定转子系统（SIRS）, 不对中, 解析模型, 动力学

Abstract：Misalignment of a multi-support rotor system is one of the most common fault conditions.A low-pressure rotor system of aero-engine uses spline joint for connecting, which constitutes statically an indeterminate rotor system (SIRS) with three elastic supports.The inherent defect of SIRS is extremely sensitive to misalignment.In this paper, an analytical dynamic model of SIRS was derived using a combination of the force method and the virtual work principle about the D’Alembert principle under alignment and misalignment of turbine back support conditions, and misalignment dynamic loads were detailed derived to determine the natural frequency and vibration responses.In this paper, the aeroengine hyperstatic rotor system was taken as the research object, and the analytical model derivation and experimental verification were carried out for its complete alignment and tail fulcrum misalignment and both theoretical and experimental results agree well.As a result, with the increase of misalignment, frequency multiplication components occur, 2X component and increase linearly, the orbits change from ellipse to inside “8” shape.Due to the structural particularity of SIRS, the appearance of TBS misalignment which generates the dynamic external excitations，makes the response of low-pressure turbine more severely.

Key words： statically indeterminate rotor system(SIRS) misalignment analytical model dynamics

收稿日期: 2020-05-28 出版日期: 2021-08-28

引用本文:

赵广，王亭月，李盛翔，李方忠，马文生. 超静定转子系统不对中动力学的理论与实验研究[J]. 振动与冲击, 2021, 40(16): 159-165.
ZHAO Guang,WANG Tingyue,LI Shengxiang,LI Fangzhong,MA Wensheng3. Theoretical and experimental study on dynamics of a statically indeterminate rotor system with misalignment. JOURNAL OF VIBRATION AND SHOCK, 2021, 40(16): 159-165.

链接本文:

http://jvs.sjtu.edu.cn/CN/ 或 http://jvs.sjtu.edu.cn/CN/Y2021/V40/I16/159

［1］VANCE J M.Rotordynamics of turbomachinery［M］.New York: Wiley-Interscience, 1988.

［2］GIBBONS C B.Coupling misalignment forces［C］∥ 5th Turbomachinery Symposium.Texas: Gas Turbine Laboratories, 1976.

［3］SEKHAR A S, PRABHU B S.Effects of coupling misalignment on vibrations of rotating machinery［J］.Journal of Sound and Vibration, 1995, 185(4): 655-671.

［4］RAO A S, SEKHAR A S.Vibration analysis of rotor-coupling-bearing system with misaligned shafts［C］∥ International Gas Turbine and Aeroengine Congress and Exhibition.Birmingham: ASME, 1996.

［5］PRABHAKAR S, SEKHAR A S, MOHANTY A R.Vibration analysis of a misaligned rotor-coupling-bearing system passing through the critical speed［J］.Journal of Mechanical Engineering Science, 2001, 215(12): 1417-1428.

［6］PRABHAKAR S, SEKHAR A S, MOHANTY A R.Crack versus coupling misalignment in a transient rotor system［J］.Journal of Sound and Vibration, 2002, 256(4): 773-786.

［7］DEWELL D L, MITCHELL L D.Detection of a misaligned disk coupling using spectrum analysis［J］.Journal of Vibration and Acoustics, 1984, 106(1): 9-16.

［8］XU M, MARANGONI R D.Vibration analysis of a motor-flexible coupling-rotor system subject to misalignment and unbalance, part I: theoretical model and analysis［J］.Journal of Sound and Vibration, 1994, 176(5): 663-679.

［9］徐梅鹏,侯磊,李洪亮,等.外转子支点不同心的双转子系统振动特性［J］.振动与冲击,2019,38(4):1-6.
XU Meipeng, HOU Lei, LI Hongliang, et al.Dynamic characteristics of a dual-rotor system with outer-rotor misalignment［J］.Journal of Vibration and Shock,2019, 38(4):1-6.

［10］FENG N S, HAHN E J.Vibration analysis of statically indeterminate rotors with hydrodynamic bearings［J］.Journal of Tribology, 1998, 120(4):781-788.

［11］FENG N S, HAHN E J.Effect of bearing profile on the stability of statically indeterminate rotor bearing systems［C］∥ASME/STLE 2007 International Joint Tribology Conference.San Diego: ASME, 2007.

［12］HU W, MIAH H, FENG N S, et al.A rig for testing lateral misalignment effects in a flexible rotor supported on three or more hydrodynamic journal bearings［J］.Tribology International, 2000, 33(3/4):197-204.

［13］HU W, FENG N S, HAHN E J.A comparison of techniques for identifying the configuration state of statically indeterminate rotor bearing systems［J］.Tribology International, 2004, 37(2):149-157.

［14］刘永泉, 肖森, 洪杰,等.三支点柔性转子系统支承不同心激励特征及振动响应分析［J］.航空学报, 2017, 38(3):179-188.
LIU Yongquan, XIAO Sen, HONG Jie, et al.Excitation characteristic and dynamic response of misalignment of flexible rotor system with three supportings［J］.
Acta Aeronauticaet Astronautica Sinica, 2017, 38(3): 179-188.

［15］ZHAO G, LI S X, ZHANG Y Q, et al.Analytical dynamic model of statically indeterminate rotor system and misalignment［C］∥ASME Turbo Expo 2017:Turbomachinery Technical Conference and Exposition.Charlotte: ASME, 2017.