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Volker Kutscher liest aus "RATH"
18.11.2024 um 19:30 Uhr
Quantifying Non-Equilibrium in Hypersonic Flows Using Entropy Generation
von Ryan W. Carr
Verlag: Creative Media Partners, LLC
Taschenbuch
ISBN: 978-1-288-33142-0
Erschienen am 21.11.2012
Sprache: Englisch
Format: 246 mm [H] x 189 mm [B] x 7 mm [T]
Gewicht: 245 Gramm
Umfang: 130 Seiten

Preis: 58,00 €
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Klappentext

The constitutive relations traditionally used for finding shear stress and heat flux in a fluid become invalid in non-equilibrium flow. Their derivation from kinetic theory only demonstrates they are valid only for small deviations from equilibrium. Because it is fundamentally linked to non-equilibrium, entropy generation is used to investigate the limits of the continuum constitutive relations. However, the continuum equations are inherently limited to near equilibrium conditions due to the constitutive relations; thus kinetic theory may be used as a basis for comparison. Direct Simulation Monte Carlo (DSMC), a particle method alternative to continuum methods, is based on kinetic theory and is used to develop a flow solution for benchmark comparison. Solutions were obtained for hypersonic flow over two axi-symmetric geometries using both a continuum solver and DSMC. Formulations for entropy generation are presented for each method, and the two solutions are compared. The continuum solutions fail to capture regions of non-equilibrium as evidenced by thicker shocks in the DSMC solution. To extend the useful range of the continuum constitutive relations, the Lennard-Jones model is offered as an alternative to Sutherland's Law for calculating viscosity and thermal conductivity. The two are compared, and parameters offering a good fit for these flows are suggested for the Lennard-Jones model.