Observation and Prediction of Instability due to RD Fluid Force in Rotating Machinery by Operational Modal Analysis
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Abstract
In recent years, as rotating machinery has become smaller and more efficient, various types of shaft vibration problems have arisen. Failure of rotating machinery may lead to major accidents and infrastructure shutdowns. Therefore, to prevent failures of rotating machinery, there is a growing need for the vibration analysis technology at the design stage and condition monitoring during operation stage. One of causes of the shaft vibration problems in rotating machinery is the rotordynamic (RD) fluid force acting on fluid elements such as journal bearings, seals, turbine blades, and so on. RD fluid force has a significant effect on the stability of rotating machinery and can destabilize the system. In recent years, operational modal analysis (OMA) methods, which identify modal parameters based on the measured data of a machine's operational condition, have been investigated in the condition monitoring. In this paper, the estimation of the modal parameters of rotating machinery using OMA from only the time history response of displacement data and, in particular, the prediction of the destabilization of rotating machinery caused by RD fluid force are investigated. As a result, the modal parameters are well estimated and, in particular, the destabilization of one mode due to RD fluid force is predicted and explained. The results are in good agreement with the results of the eigenvalue analysis of the original system, and the method is validated. Furthermore, the proposed method is applied to experimental data of the system destabilized by fluid force. The change in stability with rotational speed is observed, and the characteristics of the mode toward destabilization are confirmed. The results show the validity of OMA's predictions of destabilization in the experiments.
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Operational Modal Analysis, Rotating machinery, Pseudo-FRF, Stability, Vibration analysis, Condition monitoring
Childs, D. W. (1978). The Space Shuttle Main Engine High-Pressure Fuel Turbopump Rotordynamic Instability Problem. ASME J. Eng. Gas Turbines Power Vol.100 No.1: pp. 48-57. DOI: 10.1115/1.3446326.
Childs, D. W. (1983). Finite Length Solutions for RD Coefficents of Turblent Annular Seals. ASME Journal of Lubricatuion Technology Vol.105 pp437-445.
Childs, D. W. & Moyer, D. S. (1985). Vibration Characteristics of the HPOTP (High-Pressure Oxygen Turbopump) of the SSME (Space Shuttle Main Engine). ASME J. Eng. Gas Turbines Power Vol.107 No.1 : pp. 152-159. DOI: 10.1115/1.3239676.
Childs, D. W. (1993). Turbomachinery rotordynamics: phenomena, modeling, and analysis. John Wiley & Sons.
Chouksey, M., Dutt, J. K. & Modak, S.V. (2012). Modal analysis of rotor-shaft system under the influence of rotor-shaft material damping and fluid film forces. Mechanism and Machine Theory, 48:81-93
Gecgel, O., Dias, J. P., Osire, S. E., Alves, D.S., Macado, T. H., Daniel, G. B., Castro, H. F. & Cavalca, K. L. (2020). Simulation-Driven Deep Learning Approach for Wear Diagnostics in Hydrodynamic Journal Bearings. Journal of Tribology, August 2021, Vol. 143
Kimura, S., Inoue, T., Taura, H., Heya, A. (2023). The influence of differential pressure on stability of vertical rotor-seal system. ASME 2023 International Design Engineering Technical Conferences & Computers and Information in Engineering Conference (IDETC/CIE2023), 114617, (submitted)
Kunori, Y., Inoue, T., & Miyake, K. (2021) Two-Way Coupled Shooting Analysis of Fluid Force in the Annular Plain Seal and Vibration of the Rotor System. Journal of Vibration and Acoustics, Vol.143, Issues.5.
Lund, J. W. (1974). Stability and Damped Critical Speeds of a Flexible Rotor in Fluid-Film Bearings. Journal of Engineering for Industry, 96(2): 509-517
Miyake, K., Inoue, T., Watanabe, Y. (2019). Two-way coupling fluid-structure interaction analysis and tests of shaft vibration and clearance flow across plain annular seal. Journal of Applied Mechanics 86. 101002.
Nagae, N., Watase, M. & Tamaki, T., (2011). Operational modal analysis using cross correlation function. Japan society of civil engineers, Journal of structural engineering, Vol.57A (in Japanese)
Nelson, C. C. (1984). Analysis for Leakage and Rotordynamic Coefficients of Surface-Roughened Tapered Annular Gas Seals. ASME Journal of Engineering for Gas Turbines and Power Vol.106(1984) pp927-934
Nelson, C. C. (1985). RD coefficients for Compressible Flow in Tapered Annular Seals. ASME Journal of Tribology Vol.107 pp318-325
Santos, I. F. & Svendsen, P. K., (2017). Noninvasive Parameter Identification in Rotordynamics Via Fluid Film Bearings- Linking Active Lubrication and Operational Modal Analysis. Journal of Engineering for Gas Turbines and Power, JUNE 2017, Vol. 139
Yang, B. S., Iwatsubo, T. & Kawai, R. (1984). A Study on the Dynamic Characteristics of Pump Seal: 1st Report, In case of Annular Seal with Eccentricity. Bulletin of the JSME Vol.27 No.227: pp. 1047-1057. DOI: 10.1299/jsme1958.27.1047