S. Paul Pao scite author profile

S. Paul Pao

5Publications

142Citation Statements Received

32Citation Statements Given

How they've been cited

217

137

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Affiliations

Langley Research Center, Wyle (United States), University of Alabama in Huntsville

Publications

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Computational analysis of a pylon-chevron core nozzle interaction

Thomas

Kinzie

Pao

2001

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In typical engine installations, the pylon of an engine creates a flow disturbance that interacts with the engine exhaust flow. This interaction of the pylon with the exhaust flow from a dual stream nozzle was studied computationally. The dual stream nozzle simulates an engine with a bypass ratio of five. A total of five configurations were simulated all at the take-off operating point. All computations were performed using the structured PAB3D code which solves the steady, compressible, Reynolds-averaged NavierStokes equations.These configurations included a core nozzle with eight chevron noise reduction devices built into the nozzle trailing edge. Baseline cases had no chevron devices and were run with a pylon and without a pylon. Cases with the chevron were also studied with and without the pylon. Another case was run with the chevron rotated relative to the pylon. The fan nozzle did not have chevron devices attached. Solutions showed that the effect of the pylon is to distort the round jet plume and to destroy the symmetrical lobed pattern created by the core chevrons.Several overall flow field quantities were calculated that might be used in extensions of this work to find flow field parameters that correlate with changes in noise.

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A numerical study of two-dimensional shock vortex interaction

Pao

Salas

1981

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Temperature Corrected Turbulence Model for High Temperature Jet Flow

Abdol-Hamid

Pao

Massey³

et al. 2004

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It is well known that the two-equation turbulence models under-predict mixing in the shear layer for high temperature jet flows. These turbulence models were developed and calibrated for room temperature, low Mach number, and plane mixing layer flows. In the present study, four existing modifications to the two-equation turbulence model are implemented in PAB3D and their effect is assessed for high temperature jet flows. In addition, a new temperature gradient correction to the eddy viscosity term is tested and calibrated. The new model was found to be in the best agreement with experimental data for subsonic and supersonic jet flows at both low and high temperatures.

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Biologically inspired technologies in NASA's morphing project

McGowan

Cox

Lazos

et al. 2003

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Numerical Study of Flow Past a Circular Cylinder Using RANS, Hybrid RANS /LES and PANS Formulations

Elmiligui

Abdol-Hamid

Massey³

et al. 2004

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S. Paul Pao

Computational analysis of a pylon-chevron core nozzle interaction

A numerical study of two-dimensional shock vortex interaction

Temperature Corrected Turbulence Model for High Temperature Jet Flow

Biologically inspired technologies in NASA's morphing project

Numerical Study of Flow Past a Circular Cylinder Using RANS, Hybrid RANS /LES and PANS Formulations

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