Journal of computational fluids engineering (한국전산유체공학회지)

Korean Society of Computational Fluids Engineering (한국전산유체공학회)
권호 표지

Analysis of Flow and Heat Transfer in Swirl Chamber for Cooling in Hot Section

고온부 냉각을 위한 스월챔버내의 유동 및 열전달 해석

  • 이강엽 (한국항공우주연구원 추진성능시험그룹) ;
  • 김형모 (한국항공우주연구원 추진성능시험그룹) ;
  • 한영민 (한국항공우주연구원 추진성능시험그룹) ;
  • 이수용 (한국항공우주연구원 추진성능시험그룹)
  • Published : 2002.09.01
Download PDF
⟨ Previous Next ⟩

Abstract

Most of modem aerospace gas turbines must be operated at a gas temperature which is several hundreds of degrees higher than the melting temperatures of the materials used in their construction. Complicated cooling schemes need to be employed in the combustor walls and in the high pressure turbine stages. Internal passages are cast or machined into the hot sections of aero-gas turbine engines and air from the compressor is used for cooling. In many cases, the cooling system is engineered to utilize jets of high velocity air, which impinge on the internal surfaces of the components. They are categorized as 'Impinging Cooling Method' and 'Vortex Cooling Method'. Specially, research of new cooling system(Vortex Cooling Method) that overcomes inefficiency of film cooling and limitation of space. The focus of new cooling system that improves greatly cooling efficiency using less amount of cooling air on surface heat transfer elevation. Therefore, in this study, a numerical analysis has been peformed for characteristics of flow and heat transfer in the swirl chamber and compared with the flow measurements by LDV. Especially, for understanding high heat transfer efficiency in the vicinity of wall, we considered flow structure, vortex mechanism and heat transfer characteristics with variation of the Reynolds number.

Keywords

References

  1. Gardon, R. and Akfirate, J., 'Heat Transfer Charactehstics of Impinging Two-Dimensional Air Jet,' ASME J. of Heat Transfer, (1966), pp.101~108
  2. Giralt, F. and Chia, C.J., 'Charactehzation of the Impingement Region in Axisymmetry Turbulent Jet,' Ind. Eng. Chem. Fundam., Vo1.16, (1977), pp.21~28
  3. Amano, R.S. and Brandt, H., 'Numerical Study of Turbukent Axisymmetric Jets Impinging on a Plate and flowing into Axisymmertric cavity,' ASME J. of Fluid Engineehng, Vo1.106, (1984), pp.410~417
  4. Tabakoff, W. and Clevenger, W., 'Gas Turbine Blade Heat Transfer Augmentation by Impingement of Air Jets Having Various Configurations,'ASME J. of Engineering for Power, (1972), pp.51~60
  5. Gau, C. and Chung, C.M., 'Surface Curvature Effect on Slot-Air-Jet Impingement Cooling Flow and Heat Transfer Process,' ASME J. of Heat Transfer, Vol.ll3, (1991), pp.858~864
  6. Bunker, R.S. and Metzger, D.E., 'Local Heat Transsfer in Inernally Cooled Turbine AirFoil Leading Edge Region: Part I-Impingement Cooling without Film Cooling Extraction,' ASME J. of Turbomachinery, Vo1.112, (1990), pp.451-458
  7. Qian, C., and Flannery, K., 'Innovative Vortex Cooling Concept and Its Application to Turbine Airfoil Trailing Edge Cooling Desig,' AIAA, (1997)
  8. Ogawa, A., Vortex Flow, CRC Press,(1993)
  9. Kerrebrok, J.L. and Meghreblian, R.V., 'Vortex Containment for the Gaseous Fission Rocket,' J.Aerospace Sci.,Vo1.28,(1961), pp710
  10. Lagani, P.M., 'Flow Visualization of Deau Vortices in a Curled Channel with 40 to 1 Aspect Ratio,' J. Physics of Fluids, Vol.Sl, (1988), pp3605~3612
  11. 'Fluent 5 User's Guide,' Vol.l, Vo1.2, Fluent Inc., (1998)
  12. D. Choudhury, 'Introduction to the Renomalization Group Method and Turbulence Modeling,' Fluent Inc Technical Memorandum TM-107, (1993)
  13. J.E. Baradina, P.G. Huang, and T.J. Coakley, 'Turbulence Modeling Validation, Testing, and Development,'NASA Technical Memorandum 110446,(1997)