Thermal Analysis of Hypersonic Inlet Flow with Exergy-Based Design Methods

David Moorhouse; Charles Hoke; James Prendergast

Thermal Analysis of Hypersonic Inlet Flow with Exergy-Based Design Methods

Year 2002, Volume: 5 Issue: 4, 161 - 168, 01.12.2002

David Moorhouse Charles Hoke James Prendergast

Abstract

This paper presents results of work that has been done in developing use of the Second Law of Thermodynamics and methods such as exergy and thermoeconomics into a system-level analysis and design methodology. The application of these methods to the design of a complete flight vehicle is illustrated by considering an integrated airframe/propulsion system as a device to do work. This shows how system-level consideration of exergy applies to all vehicle systems in consistent terms. For the hypersonic inlet flow problem, it is shown that a thermal energy exchange with the inlet flow could be used to position the inlet shock in the optimum shock-on-lip position for off-nominal flight conditions. The thermal heat exchange analysis has been done for a full range of Mach numbers both higher and lower than nominal. It is shown that there is a potential benefit in terms of reduced exergy destroyed using thermal energy addition than by the shock at higher Mach numbers. The paper then discusses how a device to accomplish this result would have to be integrated into a complete vehicle design.

Keywords

exergy analysis, thermoeconomics, 2nd Law of Thermodynamics, hypersonic aircraft/vehicles, shock-on-lip positioning, MHD shock control

Year 2002, Volume: 5 Issue: 4, 161 - 168, 01.12.2002

David Moorhouse Charles Hoke James Prendergast

Abstract

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Details

Primary Language	English
Journal Section	Regular Original Research Article
Authors	David Moorhouse This is me Charles Hoke This is me James Prendergast This is me
Publication Date	December 1, 2002
Published in Issue	Year 2002 Volume: 5 Issue: 4

Cite

APA	Moorhouse, D., Hoke, C., & Prendergast, J. (2002). Thermal Analysis of Hypersonic Inlet Flow with Exergy-Based Design Methods. International Journal of Thermodynamics, 5(4), 161-168.
AMA	Moorhouse D, Hoke C, Prendergast J. Thermal Analysis of Hypersonic Inlet Flow with Exergy-Based Design Methods. International Journal of Thermodynamics. December 2002;5(4):161-168.
Chicago	Moorhouse, David, Charles Hoke, and James Prendergast. “Thermal Analysis of Hypersonic Inlet Flow With Exergy-Based Design Methods”. International Journal of Thermodynamics 5, no. 4 (December 2002): 161-68.
EndNote	Moorhouse D, Hoke C, Prendergast J (December 1, 2002) Thermal Analysis of Hypersonic Inlet Flow with Exergy-Based Design Methods. International Journal of Thermodynamics 5 4 161–168.
IEEE	D. Moorhouse, C. Hoke, and J. Prendergast, “Thermal Analysis of Hypersonic Inlet Flow with Exergy-Based Design Methods”, International Journal of Thermodynamics, vol. 5, no. 4, pp. 161–168, 2002.
ISNAD	Moorhouse, David et al. “Thermal Analysis of Hypersonic Inlet Flow With Exergy-Based Design Methods”. International Journal of Thermodynamics 5/4 (December 2002), 161-168.
JAMA	Moorhouse D, Hoke C, Prendergast J. Thermal Analysis of Hypersonic Inlet Flow with Exergy-Based Design Methods. International Journal of Thermodynamics. 2002;5:161–168.
MLA	Moorhouse, David et al. “Thermal Analysis of Hypersonic Inlet Flow With Exergy-Based Design Methods”. International Journal of Thermodynamics, vol. 5, no. 4, 2002, pp. 161-8.
Vancouver	Moorhouse D, Hoke C, Prendergast J. Thermal Analysis of Hypersonic Inlet Flow with Exergy-Based Design Methods. International Journal of Thermodynamics. 2002;5(4):161-8.