Abstract
The article presents a numerical study of the large-amplitude, acoustically-driven streaming flow for different frequencies of the acoustic wave and different temperature gradients between hot and cold surfaces. The geometries studied were mainly two-dimensional rectangular resonators of different lengths, but also one three-dimensional rectangular resonator and one long and narrow channel, representative of a typical U-shaped resistance thermometer. The applied numerical model was based on the Navier–Stokes compressible equations, the ideal gas model, and finite volume discretization. The oscillating wall of the considered geometries was modeled as a dynamically moving boundary of the numerical mesh. The length of the resonators was adjusted to one period of the acoustic wave. The research confirmed that baroclinic acoustic streaming flow was largely independent of frequency, and its intensity increased with the temperature gradient between the hot and cold surface. Interestingly, a slight maximum was observed for some oscillation frequencies. In the case of the long and narrow channel, acoustic streaming manifested itself as a long row of counter-rotating vortices that varied slightly along the channel. 3D calculations showed that a three-dimensional pair of streaming vortices had formed in the resonator. Examination of the flow in selected cross-sections showed that the intensity of streaming gradually decreased as it approached the side walls of the resonator creating a quasi-parabolic profile. The future development of the research will focus on fully 3D calculations and precise identification of the influence of the bounding walls on the streaming flow.
Highlights
Steady streaming is a time-averaged flow that emerges in oscillatory driven fluid systems
This thermodynamic model differs from the model in [4], where the dynamic viscosity and the heat transfer coefficient were calculated using an empirical correlation and the Prandtl number was set as a constant value of Pr = 0.67
This work focuses on the numerical study of large-amplitude, acoustically-driven streaming flow for the frequency range of the acoustic wave from 20 kHz to 80 kHz and temperature differences ∆T = (0, 20, 60) K between hot and cold surfaces
Summary
Steady streaming is a time-averaged flow that emerges in oscillatory driven fluid systems. The research was extended to investigate the effect of different frequencies of the acoustic wave and different temperature gradients on the intensity of the streaming and the possible improvement of heat transfer between cold and hot surfaces To our knowledge, such an extensive parameter space has not been previously explored or collected in a single article. The article ends with a numerical study of the possibility of using the acoustic streaming to intensify heat transport and, to shorten the measurement time of a typical U-shaped Pt-100 resistance thermometer In this case, the streaming flow was successfully induced in a relatively long and narrow air-filled channel by oscillation of one of its end vertical walls. This allowed us to observe the acoustic streaming caused by the vibration of one of the distant vertical walls in a long and narrow channel, which, to the best of our knowledge, has not been shown before
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