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Title: System Identification Modeling and Unstable Behavior of the Dynamics of Flows within the Tip Region of an Axial Compressor Blade Passage
Author: Sterbentz, Dane M.1; Prasai, Sujan1; Hofle, Mary M.1; Walters, Thomas1; Lin Feng2; Li Ji-chao2; Bosworth, Ken1; Schoen, Marco P.1
Source: JOURNAL OF THERMAL SCIENCE
Issued Date: 2016-04-01
Volume: 25, Issue:2, Pages:109-116
Keyword: axial compressor ; correlation coefficient ; oscillatory behavior ; system identification
DOI: 10.1007/s11630-016-0840-4
DOC Type: Article
English Abstract: In recent years, the correlation coefficient of pressure data from the same blade passage in an axial compressor unit has been used to characterize the state of flow in the blade passage. In addition, the correlation coefficient has been successfully used as an indicator for active control action using air injection. In this work, the correlation coefficient approach is extended to incorporate system identification algorithms in order to extract a mathematical model of the dynamics of the flows within a blade passage. The dynamics analyzed in this research focus on the flow streams and pressure along the rotor blades as well as on the unsteady tip leakage flow from the rotor tip gaps. The system identification results are used to construct a root locus plot for different flow coefficients, starting far away from stall to near stall conditions. As the compressor moves closer to stall, the poles of the identified models move towards the imaginary axis of the complex plane, indicating an impending instability. System frequency data is captured using the proposed correlation based system identification approach. Additionally, an oscillatory tip leakage flow is observed at a flow coefficient away from stall and how this oscillation changes as the compressor approaches stall is an interesting result of this research. Comparative research is analyzed to determine why the oscillatory flow behavior occurs at a specific sensor location within the tip region of the rotor blade.
WOS Headings: Science & Technology ; Physical Sciences ; Technology
WOS Subject: Thermodynamics ; Engineering, Mechanical
WOS Subject Extended: Thermodynamics ; Engineering
Indexed Type: SCI
Funder: National Natural Science Foundation of China(51306178)
Language: 英语
WOS ID: WOS:000372382600001
Citation statistics:
Content Type: 期刊论文
URI: http://ir.etp.ac.cn/handle/311046/112444
Appears in Collections:中国科学院工程热物理所(论文库)_期刊论文(SCI)

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description.institution: 1.Idaho State Univ, Measurement & Control Engn Res Ctr, 921 South 8th Ave,Stop 8060, Pocatello, ID 83209 USA
2.Chinese Acad Sci, Inst Engn Thermophys, Beijing, Peoples R China
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