Computational and Experimental Study of Supersonic Nozzle Flow and Shock Interactions | Zendy

Melissa B. Carter | Zendy; Alaa Elmiligui | Zendy; Sudheer N. Nayani | Zendy; Raymond Castner | Zendy; Walter E. Bruce | Zendy; Jacob Inskeep | Zendy

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Computational and Experimental Study of Supersonic Nozzle Flow and Shock Interactions

Author(s) -

Melissa B. Carter,

Alaa Elmiligui,

Sudheer N. Nayani,

Raymond Castner,

Walter E. Bruce,

Jacob Inskeep

Publication year - 2015

Publication title -

53rd aiaa aerospace sciences meeting

Language(s) - English

Resource type - Conference proceedings

DOI - 10.2514/6.2015-1044

Subject(s) - sonic boom , supersonic speed , aerospace engineering , shock (circulatory) , computational fluid dynamics , turbulence , aerodynamics , nozzle , nacelle , shock wave , marine engineering , mechanics , meteorology , engineering , physics , turbine , medicine

This study focused on the capability of NASA Tetrahedral Unstructured Software System’s CFD code USM3D capability to predict the interaction between a shock and supersonic plume flow. Previous studies, published in 2004, 2009 and 2013, investigated USM3D’s supersonic plume flow results versus historical experimental data. This current study builds on that research by utilizing the best practices from the early papers for properly capturing the plume flow and then adding a wedge acting as a shock generator. This computational study is in conjunction with experimental tests conducted at the Glenn Research Center 1’x1’ Supersonic Wind Tunnel. The comparison of the computational and experimental data shows good agreement for location and strength of the shocks although there are vertical shifts between the data sets that may be do to the measurement technique.

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