Extension of a combined analytical/numerical initial value problem solver for turbulent mixing with combustion

Here, we describe the development of a reacting flow multi-species/combustion methodology, implemented as an extension to the differential reduced ejector analysis (DREA) computer program [Mathematical and computer modeling, vol. 31, 2000, p. 21; Appl. Math. Model. 25 (2001) 427; Comput. Math. Appl....

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Veröffentlicht in:Computers & fluids 2003-12, Vol.32 (10), p.1435-1452
Hauptverfasser: De Chant, Lawrence J., Seidel, Jonathan A., Kline, Teresa R.
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Seidel, Jonathan A.
Kline, Teresa R.
description Here, we describe the development of a reacting flow multi-species/combustion methodology, implemented as an extension to the differential reduced ejector analysis (DREA) computer program [Mathematical and computer modeling, vol. 31, 2000, p. 21; Appl. Math. Model. 25 (2001) 427; Comput. Math. Appl. 43(10–11); NASA Contractor Report, 1998]. Use of the single fluid IVP solver framework that was developed for the original DREA model has been directly coupled into the combustion formulation. With these modifications, the analysis has an elementary single step reaction Fuel+Oxidizer→Product combustion capability. Though approximate in nature, the simplicity and efficiency of the DREA formulation make it suitable for its original niche, namely design and preliminary design environments where more complex and expensive models may be inappropriate.
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subjects Aerodynamic mixing
Applied sciences
Combined analytical/numerical method
Combustion. Flame
Ejector nozzle
Elementary combustion model
Energy
Energy. Thermal use of fuels
Exact sciences and technology
Preliminary design
Theoretical studies
Theoretical studies. Data and constants. Metering
title Extension of a combined analytical/numerical initial value problem solver for turbulent mixing with combustion
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