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Comparison of Reynolds-Averaged Navier-Stokes Turbulence Models Under Condition of Oscillatory Boundary Layer Flow

Author(s): Minwoo Son; Kwansue Jung; Sang Ug Kim; Eun-Sung Chung

Linked Author(s): Kwansue Jung

Keywords: Turbulence model; Oscillatory Boundary layer flow; U-tube experiment

Abstract: This study aims to compare Reynolds-averaged Navier-Stokes equations (RANS) turbulence models (k-ε and k-ω models) under the condition of oscillatory boundary layer flow at high Reynolds number. For the condition of negligible spanwise flow (y-direction in this study), the U-tube experiment is replicated by a one-dimensional vertical (1DV) numerical model. The most reliable conclusion of this study is that a k-ε model and a k-ω model calculate very similar flow condition and turbulent kinetic energy (TKE). This finding is different from previous study. Puleo et al. (2004) also applied a 1DV model incorporated with k-ε and k-ω models to U-tube experiment and calculated TKE. They concluded that the result of k-ω model is more accurate than that of k-ε model. From Wilcox (1993), it is known that a k-ω model has an advantage over k-ε model under the condition of large spanwise pressure gradient. As mentioned, spanwise flow of U-tube experiment is assumed to be negligible. Therefore, it is questionable that the result of k-ε model has less accuracy compared to the result of k-ω model. Pope (2000) insisted that a k-ω model is sensitive to calibration of empirical parameters. Based on results of this study and Pope (2000), it is concluded that a k-ε model does not a disadvantage compared to k-ω model under the condition of negligible spanwise flow. Therefore, it is also concluded that a k-ε model has a capability to calculate turbulent flow and TKE when studying cases such as straight channel flow, estuarine flow and oscillatory flow of which spanwise (or along-shelf) pressure gradient is not significantly large.

DOI:

Year: 2013

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