Multi-field coupling dynamic characteristics and data fitting based on Kriging model

被引：0

作者：

Yang W.-J. ^{[1
]}

Yuan H.-Q. ^{[2
]}

Zhao T.-Y. ^{[1
]}

机构：

[1] School of Mechanical Engineering & Automation, Northeastern University, Shenyang

[2] School of Sciences, Northeastern University, Shenyang

来源：

Dongbei Daxue Xuebao/Journal of Northeastern University | 2016年 / 37卷 / 06期

关键词：

Compressor rotor; Cyclic symmetric method; Dynamic characteristics; Kriging model; Multi-field coupling;

D O I：

10.3969/j.issn.1005-3026.2016.06.016

中图分类号：

学科分类号：

摘要：

Aero-engine is increasingly to face the trend of higher load, efficiency and reliability, so that multi-field coupling problems are taken more and more attention. This research took the semal system of an aero-engine compressor as the research object, 3D flow field in the single sector and structural models were established by the method of cyclic symmetric. Considering the influence of former stator wakes, compressor flow field was simulated. Based on the Kriging model, load transfer of aerodynamic pressure and temperature achieved from flow field to blade structure. Then the coupling effects of aerodynamic pressure, temperature and centrifugal stress on compressor fatigue life were discussed. The results show that the load transfer with the Kriging model can meet the requirement of multi-field coupling dynamic calculation. In the low pressure compressor, centrifugal force plays a major role on deformation and stress of semal system, and bending stress induced by aerodynamic pressure and temperature can counteract part of bending stress induced by centrifugal force. However, temperature load makes the maximal deformation of blade-disc system increase. © 2016, Science Press. All right reserved.

引用

页码：834 / 838

页数：4

共 10 条

[1] Forsching H.W., Grundlagen Der Aeroelastik, (1974)
[2] Eckert E.R.G., Low G.M., Temperature distribution in internally heated walls of heat exchangers composed of nonnuclear flow passages, (1951)
[3] Dechaumphai P., Wieting A.R., Thornton E.A., Flow-thermal-structural study of aerodynamically heated leading edges, Journal of Spacecraft and Rockets, 26, 4, pp. 201-209, (1989)
[4] Giles M.B., Stability analysis of numerical interface conditions in fluid-structure thermal analysis, International Journal for Numerical Methods in Fluids, 25, 4, pp. 421-436, (1997)
[5] Tran D.M., Liauzun C., Labaste C., Methods of fluid-structure coupling in frequency and time domains using linearized aerodynamics for turbo machinery, Journal of Fluids and Structures, 17, 8, pp. 1161-1180, (2003)
[6] Gottfried D.A., Fleeter S., Aerodynamic damping predictions in turbo machines using a coupled fluid-structure model, Journal of Propulsion and Power, 21, 2, pp. 327-334, (2005)
[7] Wang Z., Wu H., Shi Y.-F., Et al., Fluid-structure interaction and flutter analysis of compressor blade based on CFD/CSD, Journal of Aerospace Power, 26, 5, pp. 1077-1084, (2011)
[8] Fan X.-L., Liu Y.-F., Guo R., Et al., The research and application on coupled fluid-structure simulation of compressor rotor, Journal of Engineering Thermophysics, 33, 2, pp. 218-221, (2012)
[9] Yuan H.-Q., Zhang L.-X., Zhu X.-Z., Et al., Study on thermal bending response of high pressure rotor system, Journal of Vibration and Shock, 27, pp. 23-25, (2008)
[10] Adamczyk J.J., Aerodynamic analysis of multistage turbomachinery flows in support of aerodynamic design, Journal of Turbomachinery, 122, 2, pp. 189-217, (1999)

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