Internal gravity waves in flow past a bluff body under different levels of stratification

TL;DR

This study uses large eddy simulations to analyze internal gravity waves generated by a bluff body in stratified flow, revealing how wave characteristics depend on stratification levels and flow parameters.

Contribution

It provides a detailed comparison between LES results and linear theory, highlighting the influence of separation zones and flow parameters on wave behavior.

Findings

Excellent agreement between LES and linear theory for wave wavelengths and amplitudes.

Wake wave wavelength increases with Froude number, showing self-similar envelope behavior.

Wake wave potential energy becomes dominant at higher Froude numbers, indicating energetic significance.

Abstract

The flow field of a bluff body, a circular disk, that moves horizontally in a stratified environment is studied using large eddy simulations (LES). Five levels of stratification (body Froude numbers of Fr = 0.5, 1, 1.5, 2 and 5) are simulated at Reynolds number of Re = 5000 and Prandtl number of Pr = 1. A higher Re = 50, 000 database at Fr = 2, 10 and Pr = 1 is also examined for comparison. The wavelength and amplitude of steady lee waves are compared with a linear-theory analysis. Excellent agreement is found over the entire range of Fr if an equivalent body that includes the separation region is employed for the linear theory. For asymptotically large distance, the velocity amplitude varies theoretically as Fr raised to negative 1 but a correction owing to dependence of the separation zone on Fr is needed. The wake waves propagate in a narrow band of angles with the vertical and have a wavelength that increases with increasing Fr. The envelope of wake waves, demarcated using buoyancy variance, exhibits self-similar behavior. The higher Re results are consistent with the buoyancy effects exhibited at the lower Re. The wake wave energy is larger at Re = 50000. Nevertheless, independent of Fr and Re, the ratio of the wake wave potential energy to the wake turbulent energy increases to approximately 0.6 to 0.7 in the nonequilibrium (NEQ) stage showing their energetic importance besides suggesting universality in this statistic. There is a crossover of energetic dominance of lee waves at Fr less than 2 to wake-wave dominance at Fr approximately equal to 5.