Datenbestand vom 15. November 2024

Warenkorb Datenschutzhinweis Dissertationsdruck Dissertationsverlag Institutsreihen     Preisrechner

aktualisiert am 15. November 2024

ISBN 978-3-8439-3311-7

72,00 € inkl. MwSt, zzgl. Versand


978-3-8439-3311-7, Reihe Ingenieurwissenschaften

Hannes Frank
High Order Large Eddy Simulation for the Analysis of Tonal Noise Generation via Aeroacoustic Feedback Effects at a Side Mirror

153 Seiten, Dissertation Universität Stuttgart (2017), Softcover, A5

Zusammenfassung / Abstract

In this work, the flow around a side mirror and the resulting tonal noise generation are investigated using highly accurate large eddy simulations. Avoiding tonal noise, which can be perceived as disturbing whistling sound, is a crucial target in automotive aeroacoustics. The underlying mechanisms are not completely understood and can typically not be captured with state of the art computational aeroacoustics solvers. Acoustic feedback effects known from tonal airfoil self-noise are a possible cause at smooth mirror housings that exhibit laminar separation upstream of the trailing edge.

Since this application demands high accuracy, a simulation code based on the discontinuous Galerkin spectral element method is employed. To enhance geometrical flexibility, it is augmented with non-conforming curved elements in three dimensions.

Adopting the corresponding experimental configuration, the study considers an isolated side mirror mounted on the wind tunnel floor. The computational flow field is shown to agree remarkably well with the experimental one based on comparisons with static wall pressure, hotwire and PIV measurements. Discrete peaks are obtained in the computational acoustic spectrum, originating at the trailing edge downstream of laminar separation. The identified tonal noise source regions match the experimental ones and quantitative agreement is achieved for one of the tonal peak frequencies. Perturbation simulations reveal global acoustic feedback instabilities selecting the same discrete frequencies observed in the developed flow. The feedback loop comprises convective disturbance growth in the separated shear layer, scattering at the trailing edge and reinforcement through receptivity to the emitted sound in the upstream boundary layer.

In a second step, this mechanism is studied using a simplified two-dimensional model. Simulations of a range of free-stream velocities exhibit tonal frequencies varying similarly to the experimentally observed so-called 'ladder structure'. The tone frequencies evolve according to a theoretical feedback model. Finally, various modifications to the mirror contour to eliminate tonal noise generation are evaluated.

The present work contributes to the understanding of tonal noise generation mechanisms and can guide future designs. It corroborates the capacity of the present discontinuous Galerkin framework to accurately capture relevant but delicate aeroacoustic effects at complex geometries.