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Supersonic retro-propulsion experimental design for computational fluid dynamics model validation | IEEE Conference Publication | IEEE Xplore
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Supersonic retro-propulsion experimental design for computational fluid dynamics model validation

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Scott A. Berry; Christopher T. Laws; William L. Kleb; Matthew N. Rhode; Courtney Spells; Andrew C. Mccrea
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Abstract:

The development of supersonic retro-propulsion, an enabling technology for heavy payload exploration missions to Mars, is the primary focus for the present paper. A new e...Show More

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Abstract:

The development of supersonic retro-propulsion, an enabling technology for heavy payload exploration missions to Mars, is the primary focus for the present paper. A new experimental model, intended to provide computational fluid dynamics model validation data, was recently designed for the Langley Research Center Unitary Plan Wind Tunnel Test Section 2. Pre-test computations were instrumental for sizing and refining the model, over the Mach number range of 2.4 to 4.6, such that tunnel blockage and internal flow separation issues would be minimized. A 5-in diameter 70-deg sphere-cone forebody, which accommodates up to four 4:1 area ratio nozzles, followed by a 10-in long cylindrical aftbody was developed for this study based on the computational results. The model was designed to allow for a large number of surface pressure measurements on the forebody and aftbody. Supplemental data included high-speed Schlieren video and internal pressures and temperatures. The run matrix was developed to allow for the quantification of various sources of experimental uncertainty, such as random errors due to run-to-run variations and bias errors due to flow field or model misalignments. Some preliminary results and observations from the test are presented, although detailed analyses of the data and uncertainties are still on going.
Published in: 2011 Aerospace Conference
Date of Conference: 05-12 March 2011
Date Added to IEEE Xplore: 11 April 2011
ISBN Information:

ISSN Information:

DOI: 10.1109/AERO.2011.5747240
Conference Location: Big Sky, MT, USA
Citations are not available for this document.
Contents

1. Introduction

Present capability for entry, descent, and landing (EDL) of small robotic missions to Mars, typified by a landed mass less than a metric ton, is predicated on the use of parachutes for a significant portion of the deceleration required to safely reach the surface. Practically speaking, this approach is not scalable to larger payloads due to physical limits with parachute size, materials, and testing capabilities. A proposed alternate approach is to use propulsive deceleration early in the trajectory, even during supersonic flight (instead of just at the terminal-landing phase). Thus, supersonic retro-propulsion (SRP), or the use of engine thrust directed into the oncoming supersonic freestream flow, is deemed a potentially enabling technology for future large payload missions to Mars. For a manned mission to Mars, the payload would be on the order of 10s of metric tons. SRP is currently one of the focus areas of the EDL project. For further discussions of SRP from a systems analysis and performance perspective, see [1] – [5]. A broader survey of the literature is provided in [6].

Cites in Papers - |

Cites in Papers - IEEE (3)

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1.
Daniel G. Schauerhamer, Kerry A. Zarchi, William L. Kleb, Karl T. Edquist, "Supersonic retropropulsion CFD validation with Ames Unitary Plan Wind Tunnel test data", 2013 IEEE Aerospace Conference, pp.1-14, 2013.
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2.
Michael J. Wright, Paul W. Krasa, Helen H. Hwang, Robin A. Beck, Charles H. Campbell, Karl T. Edquist, "Overview of Entry Descent and landing investments in the NASA Exploration Technology Development Program", 2011 Aerospace Conference, pp.1-14, 2011.
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3.
Kerry A. Trumble, Daniel G. Schauerhamer, William L. Kleb, Jan-Renee Carlson, Karl T. Edquist, "Analysis of Navier-Stokes codes applied to Supersonic Retro-Propulsion wind tunnel test", 2011 Aerospace Conference, pp.1-13, 2011.
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Cites in Papers - Other Publishers (15)

1.
Benedikt Danquah, Stefan Riedmaier, Markus Lienkamp, "Potential of statistical model verification, validation and uncertainty quantification in automotive vehicle dynamics simulations: a review", Vehicle System Dynamics, pp.1, 2020.
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4.
Scott A. Berry, Matthew N. Rhode, Karl T. Edquist, "Supersonic Retropropulsion Experimental Results from NASA Ames 9?7 Foot Supersonic Wind Tunnel", Journal of Spacecraft and Rockets, vol.51, no.3, pp.724, 2014.
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9.
Scott Berry, Matthew Rhode, Karl Edquist, "Supersonic Retropropulsion Experimental Results from the NASA Ames 9- x 7-Foot Supersonic Wind Tunnel", 42nd AIAA Fluid Dynamics Conference and Exhibit, 2012.
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10.
Joshua Codoni, Scott Berry, "Analysis of Dynamic Data from Supersonic Retropropulsion Experiments in NASA Langley's Unitary Plan Wind Tunnel", 42nd AIAA Fluid Dynamics Conference and Exhibit, 2012.
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11.
Hicham Alkandry, Iain Boyd, Joshua Codoni, Erin Reed, James McDaniel, "Numerical Investigation of Multi-Nozzle Propulsive Deceleration Jets for Mars Entry Aeroshells", 42nd AIAA Thermophysics Conference, 2011.
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12.
Noel Bakhtian, Michael Aftosmis, "Analysis of Inviscid Simulations for the Study of Supersonic Retropropulsion", 29th AIAA Applied Aerodynamics Conference, 2011.
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13.
Scott Berry, Matthew Rhode, Karl Edquist, Charles Player, "Supersonic Retropropulsion Experimental Results from the NASA Langley Unitary Plan Wind Tunnel", 42nd AIAA Thermophysics Conference, 2011.
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14.
William Kleb, Daniel Schauerhamer, Kerry Trumble, Emre Sozer, Michael Barnhardt, Jan-renee Carlson, Karl Edquist, "Toward Supersonic Retropropulsion CFD Validation", 42nd AIAA Thermophysics Conference, 2011.
CrossRef Google Scholar
15.
Ashley Korzun, Ian Clark, Robert Braun, "Application of a Reynolds-Averaged Navier-Stokes Approach to Supersonic Retropropulsion Flowfields", 29th AIAA Applied Aerodynamics Conference, 2011.
CrossRef Google Scholar
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