P. Kevin Tucker scite author profile

Computational fluid dynamics (CFD) has the potential to improve the historical rocket injector design process by evaluating the sensitivity of performance and injector-driven thermal environments to the details of the injector geometry and key operational parameters. Methodical verification and validation efforts on a range of coaxial injector elements have shown the current production CFD capability must be improved in order to quantitatively impact the injector design process. This paper documents the status of a focused effort to compare and understand the predictive capabilities and computational requirements of a range of CFD methodologies on a set of single element injector model problems. The steady Reynolds-Average Navier-Stokes (RANS), unsteady Reynolds-Average Navier-Stokes (URANS) and three different approaches using the Large Eddy Simulation (LES) technique were used to simulate the initial model problem, a single element coaxial injector using gaseous oxygen and gaseous hydrogen propellants. While one high-fidelity LES result matches the experimental combustion chamber wall heat flux very well, there is no monotonic convergence to the data with increasing computational tool fidelity. Systematic evaluation of key flow field regions such as the flame zone, the head end recirculation zone and the downstream near wall zone has shed significant, though as of yet incomplete, light on the complex, underlying causes for the performance level of each technique.

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Optimization of linear placements for wirelength minimization with free sites

Kahng¹,

Tucker²,

Zelikovsky³

1999

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A numerical analysis of supersonic flow over an axisymmetric afterbody

Tucker

Shyy

1993

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An Approach to Improved Credibility of CFD Calculations for Rocket Injector Design

Tucker

Menon

Merkle

et al. 2007

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Neural network and response surface methodology for rocket engine component optimization

Vaidyanathan

Papita²,

Shyy³

et al. 2000

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Response Surface and Neural Network Techniques for Rocket Engine Injector Optimization

Shyy

Tucker

Vaidyanathan

2001

Journal of Propulsion and Power

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Response surface and neural network techniques for rocket engine injector optimization

Shyy

Vaidyanathan

Tucker

1999

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P. Kevin Tucker

Surrogate-based analysis and optimization

Validation of High-Fidelity CFD Simulations for Rocket Injector Design

Optimization of linear placements for wirelength minimization with free sites

A numerical analysis of supersonic flow over an axisymmetric afterbody

An Approach to Improved Credibility of CFD Calculations for Rocket Injector Design

Neural network and response surface methodology for rocket engine component optimization

Response Surface and Neural Network Techniques for Rocket Engine Injector Optimization

Response surface and neural network techniques for rocket engine injector optimization

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