Computational Analysis of a Multiple-Nozzle Supersonic Retropropulsion Configuration
Computational Analysis of a Multiple-Nozzle Supersonic Retropropulsion Configuration
- New search for: J. A. Shafner
- New search for: A. M. Korzun
- New search for: J. A. Shafner
- New search for: A. M. Korzun
Supersonic retropropulsion is an enabling capability to land large payloads on the surface of Mars. The retropropulsion flowfield is a highly dynamic environment with strong shocks, free shear layers, and plumes opposing high-speed flow. For flight vehicles with large aerodynamic surface area, such as NASA concepts for human Mars exploration, retropropulsion can induce significant aerodynamic interference forces and moments on the vehicle during powered flight. A multiple-nozzle configuration from upcoming, inert gas, sub-scale, supersonic wind tunnel testing is simulated at Mach 2.4 conditions for angles of attack of 0 and 10 degrees and thrust coefficients of 0.5, 1.0, and 2.5. This paper examines changes in the resulting flowfield, surface pressures, and integrated forces with thrust force coefficient and angle of attack using a Detached Eddy Simulation approach.
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Computational Analysis of a Multiple-Nozzle Supersonic Retropropulsion Configuration
2021
19 pages
Report
No indication
English
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