Abstract
PIV experiments and CFD simulations were carried out on a mimic of a pilot scale Sonolator Model A inline liquid whistle mixer (Sonic Corp. USA) for water in turbulent flow for Reynolds numbers at the orifice between 17,500 and 77,200. Three different sizes of orifice were used. The results from PIV were compared with the CFD simulations, with both global and local validations being performed. The former focusses on the pressure drop across the Sonolator and the latter was carried out by comparison of local values of velocity magnitude, turbulent kinetic energy and local specific turbulent energy dissipation rate. Velocity magnitude values were found to agree within 10% more than fifteen millimetres downstream of the orifice. A similar level of agreement was found at the orifice for lower flow rates and larger orifices. Factors which precluded this level of agreement for higher flow rates and smaller orifices were the appearance of cavitation and a minimum achievable laser pulse separation, limiting the maximum velocity measureable by the PIV. Agreement between PIV and CFD was also poorer for the turbulent parameters, although the PIV and CFD data had similar trends, the magnitudes were different. The reasons for these discrepancies include the fact that the oscillation period for the orifice jet could not be precisely identified and eliminated from the data and errors inherent in the methods used to estimate the local specific turbulent energy dissipation rate from the PIV data.
Highlights
The Sonolator is an inline mixer in the liquid whistle category
During particle image velocimetry (PIV), mass flow rate was fixed for each individual experiment and pressure drop across the Sonolator measured; for corresponding computational fluid dynamics (CFD) simulations, the same mass flow rates were inputted and in each case pressure drops outputted
CFD simulation results for the Sonolator were compared against experimental results from PIV in order to validate the CFD simulations
Summary
The Sonolator is an inline mixer in the liquid whistle category (ex Sonic Corp, USA). There is sparse information in the open literature about any aspect of the Sonolator or of liquid whistles in general; of the works that exist only a few accounts of industrial applications can be found (Clark et al, 2001; Chand et al, 2007). Investigations into the interior workings of the Sonolator to determine the dynamics of the fluid motion, and how these define the performance of the device have not been documented.
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