Numerical simulation of axial liquid film cooling in rocket combustor

YANG Wei; SUN Bing; ZHENG Li-ming

Numerical simulation of axial liquid film cooling in rocket combustor

School of Astronautics, Beijing University of Aeronautics and Astronautics, Beijing 100191, China

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出版历程
- 收稿日期: 2012-02-16
- 刊出日期: 2013-02-28

Numerical simulation of axial liquid film cooling in rocket combustor

School of Astronautics, Beijing University of Aeronautics and Astronautics, Beijing 100191, China

摘要

摘要: Numerical simulation has been done for liquid film cooling in liquid rocket combustor.Multiple species of axial Navier-Stokes equations have been solved for liquid-film/hot-gas flow field,and k-ε equations have been used for compressible turbulent flow.The results of the model agree well with the results of software FLUENT.The results show that:(1) Liquid film can decrease the wall heat flux and temperature effectively,and the cold border area formed by the film covers the whole combustor and nozzle wall.(2) The turbulent viscosity is higher than the physical viscosity, and its biggest value is in the border area of the convergent area in nozzle.The effect of turbulent flow on the whole simulation field can not be ignored.(3) The mass fraction of kerosene at the film inlet is 1,but it decreases along the nozzle wall and achieves its lowest value at the outlet.However,the mass fraction of kerosene near the wall is the biggest at any axial location.
- liquid rocket engine /
- liquid film cooling /
- heat flux /
- numerical simulation /
- turbulent flow
Abstract: Numerical simulation has been done for liquid film cooling in liquid rocket combustor.Multiple species of axial Navier-Stokes equations have been solved for liquid-film/hot-gas flow field,and k-ε equations have been used for compressible turbulent flow.The results of the model agree well with the results of software FLUENT.The results show that:(1) Liquid film can decrease the wall heat flux and temperature effectively,and the cold border area formed by the film covers the whole combustor and nozzle wall.(2) The turbulent viscosity is higher than the physical viscosity, and its biggest value is in the border area of the convergent area in nozzle.The effect of turbulent flow on the whole simulation field can not be ignored.(3) The mass fraction of kerosene at the film inlet is 1,but it decreases along the nozzle wall and achieves its lowest value at the outlet.However,the mass fraction of kerosene near the wall is the biggest at any axial location.
- liquid rocket engine /
- liquid film cooling /
- heat flux /
- numerical simulation /
- turbulent flow

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参考文献(16)

[1]	Choi D.A Navier-Stokes analysis of film cooling in a turbine blade[R].AIAA-93-0158,1993.
[2]	Matesanz A,Velazquez A,Rodrlguez M.Numerical simulation of slot film cooling in convergent-divergent nozzles[R].AIAA-93-1977,1993.
[3]	James L R,Paul I K.Net heat flux reduction for pulsed film cooling on a turbine blade leading edge[R].AIAA 2009-5103,2009.
[4]	Gerald A,Pitalo P E,Joseph K.Numerical modeling of altitude diffusers[R].AIAA-96-2280,1996.
[5]	Inamura T,Amagasaki S,Yanaoka H.Thickness of liquid film formed by impinging jets on a concave wall[J].Journal of Propulsion and Power,2007,23(3):612-617.
[6]	Kiran H D,Andre W M,Arnaud T,et al.Numerical simulation of subsonic slot-jet film cooling of an adiabatic wall[R].AIAA 2009-1577,2009.
[7]	Zhang H W,Tao W Q,He Y L,et al.Numerical study of liquid film cooling in a rocket combustion chamber[J].International Journal of Heat and Mass Transfer,2006,49(1):349-358.
[8]	Chen Y S,Chen C P,Wei H. Numerical analysis of hypersonic turbulent film cooling flows[R].AIAA-92-2767,1992.
[9]	Ohminami K,Uesugi K T,Ogawa H.Performance prediction of film-cooed bipropellant thruster[R].AIAA 2006-4533,2006.
[10]	Lu Y P,Ekkad S V.Predictions of film cooling from cylindrical holes embedded in trenches[R].AIAA 2006-3401,2006.
[11]	Kumar G N,Duncan B S,Mongia H.Results of a DOE on the film cooing effectiveness of a modern combustor with machined ring liners[R].AIAA 2000-3354,2000.
[12]	Li Y B,Zhou Y,Shock R,et al.Simulation of film cooling flow from one row of inclined cylindrical jets by using Lattice-Boltzmann method[R].AIAA 2007-127,2007.
[13]	Cruz C A, Raffan F,Cadou C,et al.Slot film cooling:LES and heat transfer measurements[R].AIAA 2007-926,2007.
[14]	Sung I K,Ibrahim G H.Unsteady heat transfer analysis of a film cooling flow[R].AIAA 2008-1287,2008.
[15]	Yang H T,Chen H C,Han J C.Film-cooling prediction on turbine blade tip with various film hole configurations[J].Journal of Thermophysics and Heat Transfer,2006,20(3):558-568.
[16]	Thornburg H,Sekar B,Zelina J,et al.Design studies of turbine blade film cooling with unburned fuel in cross stream flow[R].AIAA 2009-510,2009.