J. P. Sislian scite author profile

This paper investigates the mixing of hydrogen fuel with air in the mixing duct of a mixed-compression shockinduced combustion ramjet (shcramjet) inlet. Mixing augmentation through the use of cantilevered ramp injector arrays on opposite shcramjet inlet walls is studied and the influence of relative array locations is quantified. Studies were undertaken numerically using the WARP code that solves the Favre-averaged Navier-Stokes equations closed by the Wilcox k-! turbulence model. Air-based mixing efficiencies of up to 0.58-0.68 were achieved with thrust potential losses less than that gained from high-speed fuel injection. Shocks created from the fuel injector structures play a major role in the mixing behavior of the fuel jets on the opposing side of the mixing duct. Chemically reacting studies verified for the correct selection of spanwise displacement of the fuel injectors, an air buffer created between the fuel and walls suppresses premature ignition while still allowing for a mixing efficiency of up to 0.46-0.54. Nomenclature a = speed of sound c = species mass fraction d w = distance from wall to first inner node F pot = thrust potential F pot;ref = reference thrust potential at engine inlet k = turbulence kinetic energy M c = convective Mach number, q 1 q 2 =a 1 a 2 _ m = mass flow rate _ m air;engine = mass flow rate of air in engine p = pressure p ?= effective pressure, p 2=3k Pr t = turbulent Prandtl number q = magnitude of velocity vector r = grid size factor Sc t = turbulent Schmidt number T = temperature x 1 , x 2 , x 3 = Cartesian coordinates y = nondimensional wall distance, d w w p = m = mixing efficiency = viscosity = density w = wall shear stress = equivalence ratio ! = dissipation rate per unit of turbulent kinetic energy Subscripts b = station of interest c = station of interest reversibly expanded to constant pressure at shcramjet exit area Superscripts R = reacting S = stoichiometric

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Numerical Simulation of Hypersonic Shock-Induced Combustion Ramjets

Dudebout

Sislian

Oppitz

1998

Journal of Propulsion and Power

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Analysis of Increased Compression Through Area Constriction on Ejector-Rocket Performance

Etele

Parent

Sislian

2007

Journal of Spacecraft and Rockets

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Condensation of water vapor in rarefaction waves. I - Homogeneous nucleation

Sislian

Glass

1976

AIAA Journal

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J. P. Sislian

Formation and Stability of Near Chapman-Jouguet Standing Oblique Detonation Waves

Hypervelocity Fuel/Air Mixing in Mixed-Compression Inlets of Shcramjets

Numerical Simulation of Hypersonic Shock-Induced Combustion Ramjets

Analysis of Increased Compression Through Area Constriction on Ejector-Rocket Performance

Condensation of water vapor in rarefaction waves. I - Homogeneous nucleation

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