论文信息 - Unified Navier-Stokes flowfield and performance analysis of liquid rocket engines

Unified Navier-Stokes flowfield and performance analysis of liquid rocket engines

In an effort to improve the current composite solutions in the design and analysis of liquid propulsive engines, a computational fluid dynamics (CFD) model capable of calculating the reacting flows from the combustion chamber, through the nozzle to the external plume, is developed. Flowfields of a conical nozzle and the Space Shuttle main engine (SSME) fired at sea level are investigated. The CFD model, FDNS (finite difference NavierStokes), is a pressure-based, viscous, ideal gas/real gas, reactive flow code. An equilibrium chemistry algorithm is employed using the point implicit method. A conical nozzle with the same expansion ratio as the SSME nozzle is computed to study the shock formation in both the internal and external flowfields. The bell-shaped SSME nozzle is run at 100% power level at various flow conditions. The computed flow solutions and nozzle thrust performance are in good agreement with those of other standard codes and engine hot fire test data.

Ten-See Wang | Yen-Sen Chen | Yi Chen

[1] W. Reynolds. Computation of Turbulent Flows , 1975 .

[2] A. Jameson,et al. Numerical solution of the Euler equations by finite volume methods using Runge Kutta time stepping schemes , 1981 .

[3] R. Maccormack. Current status of numerical solutions of the Navier-Stokes equations , 1985 .

[4] Alexander P. Morgan,et al. Performance of algorithms for calculating the equilibrium composition of a mixture of gases , 1985 .

[5] Y. S. Chen,et al. Viscous flow computations using a second-order upwind differencing scheme , 1988 .

[6] B. York,et al. 3D Navier-Stokes analysis of high-speed propulsive flowfields using the PARCH code , 1989 .

[7] Ten-See Wang,et al. Numerical study of reactive ramjet dump combustor flowfields with a pressure based CFD method , 1989 .

[8] B. Launder,et al. The numerical computation of turbulent flows , 1990 .

[9] S. C. Kim,et al. Performance and flow calculations for a gaseous H2/O2 thruster , 1991 .

[10] C. Angelopoulos. High resolution schemes for hyperbolic conservation laws , 1992 .