Abstract
In compression systems, instability has long been an important issue. However, compared to axial machines, relatively little work has been done on the stability of centrifugal machines. Especially, many analytical models of stabilities have been developed to predict and control rotating stall, using compressor characteristic. However, stability models for centrifugal compressors are not scarce. Much research on compressor stability has focused on stalling flow coefficient and rotating stall phenomenon at the stalling flow coefficient. Given this situation, this paper presents a stability analysis of centrifugal compressors to predict rotating stall inception as well as the speed and number of cells. This analysis involves the use of compressor geometries, a steady compressor characteristic, and threedimensional flow analysis in the diffuser. The flow field perturbations at the axial inlet duct, impeller, and radial exit duct are determined via an eigenvalue analysis. The predictions are validated against experimental results from compressors with three different diffuser widths. The model accurately predicts the rotating stall inception flow coefficient. As the compressor characteristic becomes less steep with increasing diffuser width, the stalling flow coefficient increases. Also, experiment validates the model prediction that, depending on the dominant mode of flow perturbation, the number of rotating stall cells can be changed from three to two cells in the tested configurations. Furthermore, the cell speed increases as the flow coefficient decreases for a given number of stall cells. However, when the stall cell number is reduced, the cell speed decreases.
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References
E. M. Greitzer, Surge and rotating stall in axial flow compressors — 1. Theoretical compression system model, Journal of Engineering Power, Transactions ASME, 98(2) (1976) 190–198.
E. M. Greitzer, Surge and rotating stall in axial flow compressors — 2. Experimental results and comparison with theory, Journal of Engineering Power, Transactions ASME, 98(2) (1976) 199–217.
F. K. Moore and E. M. Greitzer, A theory of post-stall transients in axial compressors: Part I — Development of the equations, Journal of Engineering for Gas Turbines and Power, Transactions ASME, 108(1) (1986) 68–76.
T. P. Hynes and E. M. Greitzer, A method for assessing effects of circumferential flow distortion on compressor stability, Journal of Turbomachinery, Transactions ASME, 109(3) (1987) 371–379.
M. B. Graf, T. S. Wong, E. M. Greitzer, C. S. Tan, H.-W. Shin and D. C. Wisler, Effects of nonaxisymmetric tip clearance on axial compressor performance and stability, Journal of Turbomachinery, Transactions ASME, 120(4) (1998) 648–661.
K. Gordon, Three-dimensional rotating stall inception and effects of rotating tip clearance asymmetry in axial compressors, Ph D thesis, Department of Aeronautics and Astronautics, MIT. (1999).
T. R. Camp and I. J. Day, A study of spike and modal stall phenomena in a low-speed axial compressor, Journal of Turbomachinery, Transactions ASME, 120(3) (1998) 393–401.
Z. S. Spakovszky, Applications of axial and radial compressor dynamic system modeling, Ph.D. thesis, Department of Aeronautics and Astronautics, MIT. (2001).
Z. S. Spakovszky, Backward traveling rotating stall waves in centrifugal compressors, Journal of Turbomachinery, Transactions ASME, 126(1) (2004) 1–12.
J. D. Paduano, A. H. Epstein, L. Valavani, J. P. Longley, E. M. Greitzer and G. R. Guenette, Active control of rotating stall in a low-speed axial compressor, Journal of Turbomachinery, Transactions ASME, 115(1) (1993) 48–56.
D. L. Gysling, Dynamic control of rotating stall in axial flow compressors using aeromechanical feedback, Ph.D. thesis, Department of Aeronautics and Astronautics, MIT. (1993).
N. Kaemmer and M. Rautenberg, A distinction between different types of stall in a centrifugal compressor stage, Journal of Engineering for Gas Turbines and Power, 108(1) (1986) 83–92.
U. Haupt, A. N. Abdelhamid, N. Kaemmer and M. Rautenberg, Excitation of blade vibration by flow instability in centrifugal compressors, ASME Paper No. 86-GT-283.
Y. S. Yoon, Shin. H. Kang and S. J. Song, Clearance effects on centrifugal compressor characteristic and stability, ASME Paper No. 2007-GT-27566.
V. H. Garnier, A. H. Epstein and E. M. Greitzer, Rotating waves as a stall inception indication in axial compressors, Journal of Turbomachinery, Transactions ASME, 113(2) (1991) 290–302.
M. Tryfonidis, O. Etchevers, J. D. Paduano, A. H. Epstein and G. J. Hendricks, Prestall behavior of several high-speed compressors, Journal of Turbomachinery, Transactions ASME, 117(1) (1995) 62–80.
J. Kang and S. Kang, Stall inception in a high-speed centrifugal compressor, ASME Paper No. 2001-GT-0301 (2001).
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Recommended by Associate Editor Donghyun You
Yong-Sang Yoon received his Ph.D at Mechanical and aerospace engineering from Seoul National University in 2006. He had worked at LG Electronics(from 2006 to 2011) and Whittle Laboratory at University of Cambridge(from 2011 to 2013). He is now a senior research engineer in Samsung Techwin, Korea.
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Yoon, YS., Song, S.J. Analysis and measurement of the impact of diffuser width on rotating stall in centrifugal compressors. J Mech Sci Technol 28, 895–905 (2014). https://doi.org/10.1007/s12206-013-1157-9
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DOI: https://doi.org/10.1007/s12206-013-1157-9