Application of an Analytical Method to Locate a Mixing Plane in a Supersonic Compressor
Application of an Analytical Method to Locate a Mixing Plane in a Supersonic Compressor
摘要
In order to achieve greater pressure ratios, compressor designers have the opportunity to use transonic configurations. In the supersonic part of the incoming flow, shock waves appear in the front part of the blades and propagate in the upstream direction. In case of multiple blade rows, steady simulations have to impose an azimuthal averaging (mixing plane) which prevents these shock waves to extend upstream. In the present paper, several mixing plane locations are numerically tested and compared in a supersonic configuration. An analytical method is used to describe the shock pattern. It enables to take a critical look at the CFD (computational fluid dynamics) steady results. Based on this method, the shock losses are also evaluated. The good agreement between analytical and numerical values shows that this method can be useful to wisely forecast the mixing plane location and to evaluate the shift in performances due to the presence of the mixing plane.
参考文献14
-
1Lichtfuss, J. J., and Starken, H. 1974. "Supersonic Cascade Flow." Progress in Aerospace Sciences IS: 37-149.
-
2Kantrowitz, A. 1946. The Supersonic Axial-Flow Compressor. NACA technical report.
-
3Chauvin, J. 1970. Supersonic Turbo-Jet Propulsion Systems and Components. AGARD report No. 120.
-
4Trebinjac, I., Ottavy, X., Rochuon, N., and Bulot, N. 2009. "On the Validity of Steady Calculations with Shock-Blade Row Interaction in Compressors." In Proceedings of the 9th International Symposium on Experimental and Computational Aerothermodynamics of Internal Flows, ISAIF9-062.
-
5Cam bier, L., and Gazaix, M. 2002. "elsA: An Efficient Object-Oriented Solution to CFD Complexity." Presented at 2002 the 40th AIAA Aerospace Science Meeting and Exhibit, Reno, USA.
-
6Smith, B. R. 1995. "Prediction of Hypersonic Shock Wave Turbulent Boundary Layer Interactions with k-l Two-Equations Turbulence Model." Presented at 1995 the 33rd AIAA Aerospace Sciences Meeting and Exhibition, Reno, USA.
-
7Rochuon, N. 2007. "Analysis of the Three-Dimensional Unsteady Flow in a High Pressure Ratio Centrifugal Compressor." PhD. thesis, Ecole centrale de Lyon.
-
8Moeckel, W. E. 1942. Approximate Method for Predicting Form and Location of Detached Shock Waves. NACA technical report.
-
9Burguburu, S., Toussaint, C., Bonhomme, C., and Leroy, G. 2004. "Numerical Optimization of Turbomachinery Bladings." Journal of Turbomachinery 126 (I): 91-100.
-
10Konig, W. M., Hennecke, D. K., and Fottner, L. 1996. "Improved Blade Profile Loss and Deviation Angle Models for Advanced Transonic Compressor Bladings: Part II-A Model for Supersonic Flow." Journal of Turbomachinery 118 (I): 81-7.
-
1朱岗崑.太阳风基础[J].国外科技新书评介,2008(2):17-18.
-
2欧阳光中.假如你到月亮里去(节选)[J].小作家选刊(小学生版),2011(5):34-35.
-
3林鹰.发动机,压缩机和冷凝器[J].鱼雷技术,1993,1(3):16-19.
-
4太阳系中的超音速“冰雹”[J].大自然探索,2007(11):7-7.
-
5行星上的超音速“飓风”[J].大自然探索,2009(1):7-7.
-
6高凌云.自我膨胀的热木星[J].现代物理知识,2011(2):45-45. 被引量:2
-
7长尾飘飘的鲸鱼怪星[J].天文爱好者,2007(9):25-25.
-
8孙文德.“迷你月亮”上的丰富矿藏[J].飞碟探索,2013(5):38-39.
-
9王斌,赵颖.A New Approach to Data Assimilation[J].Acta meteorologica Sinica,2006,20(3):275-282. 被引量:1
-
10天文学家拍到太阳表面的超音速喷流[J].科学24小时,2011(1):52-52.
