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51. Acoustic Scattering from Complex Geometries

Author

Marc Terracol, Stephane Redonnet, Eric Manoha, and Ronan Guenanff

Subjects
Engineering, Computer simulation, business.industry, Scattering, Computation, Acoustics, Computational fluid dynamics, Grid, Physics::Fluid Dynamics, Optics, Flow (mathematics), Mean flow, business, Boundary element method
Abstract

This paper addresses the numerical simulation of the acoustic scattering and propagation through non-uniform mean flows using a high-order, finite-difference, full-conservative Euler solver and, more precisely, the specific problems raised by multi-block structured grids when complex geometries are considered. Two examples of two-dimensional computations of this type are presented. The first case, a benchmark problem from the 4 th CAA Workshop, is the simulation of the acoustic scattering from multiple rigid circular cylinders, without mean flow, of the sound generated by a spatially distributed, axisymmetric source. The proposed solution uses conformal multi-domain grids associating body-fitted grids near solid walls and quasicartesian grids elsewhere. The solutions are favorably compared to analytical data. The second example is the simulation of the acoustic scattering from a high-lift wing section with deployed slat and flap, from a source located in the slat cove region. An acoustic grid is derived from a CFD grid previously used to compute the non-uniform viscous mean flow around the wing. A first acoustic computation, performed with the fluid at rest, is favorably compared to a Boundary Element Method solution. Then a second computation is performed on the non-uniform mean flow. The comparison of both solutions highlights the influence of the flow on the directivity diagram of the sound field.

Published
2004
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55. Nonlinear global modes in hot jets.

Author

LUTZ LESSHAFFT, PATRICK HUERRE, PIERRE SAGAUT, and MARC TERRACOL

Abstract

Since the experiments of Monkewitz et al. (J. Fluid Mech. vol. 213, 1990, p. 611), sufficiently hot circular jets have been known to give rise to self-sustained synchronized oscillations induced by a locally absolutely unstable region. In the present investigation, numerical simulations are carried out in order to determine if such synchronized states correspond to a nonlinear global mode of the underlying base flow, as predicted in the framework of Ginzburg–Landau model equations. Two configurations of slowly developing base flows are considered. In the presence of a pocket of absolute instability embedded within a convectively unstable jet, global oscillations are shown to be generated by a steep nonlinear front located at the upstream station of marginal absolute instability. The global frequency is given, within 10% accuracy, by the absolute frequency at the front location and, as expected on theoretical grounds, the front displays the same slope as a $k^-$-wave. For jet flows displaying absolutely unstable inlet conditions, global instability is observed to arise if the streamwise extent of the absolutely unstable region is sufficiently large: while local absolute instability sets in for ambient-to-jet temperature ratios $S \le 0.453$, global modes only appear for $S \le 0.3125$. In agreement with theoretical predictions, the selected frequency near the onset of global instability coincides with the absolute frequency at the inlet. For lower $S$, it gradually departs from this value. [ABSTRACT FROM AUTHOR]

Published
2006
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