On the effects of non-homogeneity on small scale turbulence

Kamruzzaman, Md

Title: On the effects of non-homogeneity on small scale turbulence
Creator: Kamruzzaman, Md
Relation: University of Newcastle Research Higher Degree Thesis
Resource Type: thesis
Date: 2016
Description: Research Doctorate - Doctor of Philosophy (PhD)
Description: The experimental results presented in this thesis were obtained by using hot-wire anemometry with single- and X-wire probes. The experiments were carried out at low to moderate Reynolds numbers (6 ≤ R_λ ≤ 100) in grid turbulence and turbulent boundary layers to investigate the effects of non-homogeneities on small scale turbulence. Four different flows were extensively investigated: the homogeneous and isotropic turbulence (HIT), the turbulent shearless mixing layer (TSLML), and the turbulent shear mixing layer (TSML), all three flows generated by the three different classical and two different composite grids. The fourth flow was a turbulent boundary layer over a rough wall. Classical grid turbulence measurements were made with the aim of ascertaining whether the decay of q² follows a power law. It was found that the conventional turbulence power law decay (q² ∼ xⁿ, with n is constant) does not describe the entire decay period (the initial to final period of decay, including the transition period). A family of the power law of the form xⁿⁱ, where nⁱ is a different constant over a restrained portion of decay is more appropriate. It was also found that the Kolmogorov scaling holds down to R_λ ≃ 25; below this value, it breaks down. The effects of R_λ on the energy distribution across the different scales of motion and the validity of the local isotropy, were investigated. It also was found that the assumption of self-preservation (SP) in the classical grid turbulence was not valid. The grid generated turbulent shearless mixing layer (TSLML) was investigated with the aim of studying the turbulence decay with non-homogeneous turbulence,and in particular whether or not SP could be satisfied. The SP analysis was carried out using the transport equation of the second-order velocity structure function or the scale-by-scale (SBS) energy budget equation. It was observed that the SBS energy budget on the centreline of the grid is similar to that found in the decaying HIT. Moreover, the measurements on the centreline showed that the complete SP was achieved at all scales of motion. This mean that the Taylor microscale Reynolds number (R_λ = u′λ/ν) is constant and decay power law exponent n is equal to - 1. A grid generated turbulent with a mean shear (TSML) was used to study the effect of a mean shear on the turbulence decay. The one-point statistics showed that the distribution of the mean velocity and the Reynolds stresses u^′2, v^′2, w^′2 and uv across the shear layer collapsed when x/M_L ≥ 50, suggesting SP is approximated for one-point statistics. The power law decay exponent n was about zero on the centreline of the grid, but differed from zero outside the shear layer region. The SBS energy budget equation was shown that the TSML flow did not conform to SP conditions (e.g., R_λ is not constant). For the turbulent boundary layer over a rough wall, particular attention was given to the accurate measurement of the skin friction velocity U_τ in order to assess adequately the effect of roughness on the boundary layer. The momentum integral equation and the pressure distribution around the one roughness element gave the same value of U_τ. Furthermore this later was found to be constant, i.e., independent of the Reynolds numbers and the streamwise positions x. We also studied an approximated SBS energy budget and the results showed that R_λ is constant in the region 0.2 ≥ y/δ ≥ 0.6, which is consistent with a SP conditions. This is confirmed by the collapse of the Kolmogorov normalized velocity spectra at all wave-numbers. SP is also observed for the mean velocity across the entire boundary layer thickness.
Subject: grid turbulence; turbulent shear and shearless mixing layer; turbulent boundary layer
Identifier: http://hdl.handle.net/1959.13/1316847
Identifier: uon:23279
Language: eng
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