Abstract
The response of orifices to incident acoustic waves, which is important for many engineering applications, is investigated with an approach combining both experimental measurements and numerical simulations. This paper presents experimental data on acoustic impedance of orifices, which is subsequently used for validation of a numerical technique developed for the purpose of predicting the acoustic response of a range of geometries with moderate computational cost. Measurements are conducted for orifices with length to diameter ratios, L/D, of 0.5, 5 and 10. The experimental data is obtained for a range of frequencies using a configuration in which a mean (or bias) flow passes from a duct through the test orifices before issuing into a plenum. Acoustic waves are provided by a sound generator on the upstream side of the orifices. Computational fluid dynamics (CFD) calculations of the same configuration have also been performed. These have been undertaken using an unsteady Reynolds averaged Navier–Stokes (URANS) approach with a pressure based compressible formulation with appropriate characteristic based boundary conditions to simulate the correct acoustic behaviour at the boundaries. The CFD predictions are in very good agreement with the experimental data, predicting the correct trend with both frequency and orifice L/D in a way not seen with analytical models. The CFD was also able to successfully predict a negative resistance, and hence a reflection coefficient greater than unity for the L/D=0.5 case.
Highlights
The response of orifices to incident acoustic waves, which is important for many engineering applications, is investigated with an approach combining both experimental measurements and numerical simulations
This plenum arrangement allows the acoustic response at a range of frequencies to be investigated using both experimental and Computational fluid dynamics (CFD) techniques
The CFD prediction of reactance for all three holes was in good agreement with experimental data, both exhibiting a faster than linear increase in reactance with frequency which the analytical model cannot reproduce
Summary
Lattice-Boltzmann methods have recently been used by da Silva et al [16] to investigate the sound reflection at the open end of a duct issuing a subsonic mean flow, while Ji et al [17] investigated excited flows through a small circular orifice These works were able to find results which compared well with traditional LES techniques in terms of accuracy at a lower computational cost. If the RANS approach is able to successfully model the ‘net result’ of the turbulence on an acoustically forced flow field its relatively low cost (compared to DNS or LES) has the potential to make it useful as an engineering tool to find the acoustic response of geometries where analytical models are not appropriate To this end, its ability to simulate the impedance of orifices of L/D 1⁄4 0.5, 5, 10 is assessed by comparison to experimental data
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