On self-preservation and log-similarity in a slightly heated axisymmetric mixing layer

Thiesset, F.; Schaeffer, V.; Djenidi, L.; Antonia, R. A.

Title: On self-preservation and log-similarity in a slightly heated axisymmetric mixing layer
Creator: Thiesset, F.; Schaeffer, V.; Djenidi, L.; Antonia, R. A.
Relation: ARC
Relation: Physics of Fluids Vol. 26, Issue 7
Publisher Link: http://dx.doi.org/10.1063/1.4890994
Publisher: American Institute of Physics
Resource Type: journal article
Date: 2014
Description: This paper reports an experimental investigation of self-preservation for one- and two-point statistics in a slightly heated axisymmetric mixing layer. Results indicate that the longitudinal velocity fluctuation u seems to approach self-preservation more rapidly than either the transverse velocity fluctuation v or the scalar fluctuation θ. The Reynolds number Re _δ = U ₀δ/ν (U ₀ being the jet inlet velocity and δ the momentum thickness) that ought to be achieved for the one-point statistics to behave in a self-similar fashion is assessed. Second, the relevance of different sets of similarity variables for normalizing the energy spectra and structure functions is explored. In particular, a new set of shear similarity variables, emphasizing the range of scales influenced by the mean velocity and temperature gradient, is derived and tested. Since the Reynolds number based on the Taylor microscale increases with respect to the streamwise distance, complete self-preservation cannot be satisfied; instead, the range of scales over which spectra and structure functions comply with self-preservation depends on the particular choice of similarity variables. A similarity analysis of the two-point transport equation, which features the large scale production term, is performed and confirms this. Log-similarity, which implicitly accounts for the variation of the Reynolds number, is also proposed and appears to provide a reasonable approximation to self-preservation, at least for u and θ.
Subject: Reynolds stress modeling; scalar field theory; isotropic turbulence; statistical analysis; velocity measurement
Identifier: http://hdl.handle.net/1959.13/1062001
Identifier: uon:17030
Identifier: ISSN:1070-6631
Language: eng
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