Aeroacoustic Flow Phenomena Accurately Captured by New Computational Fluid Dynamics Method

Author: Blech, Richard A.
Published: March 2002.
Physical Description: 1 electronic document

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Summary

One of the challenges in the computational fluid dynamics area is the accurate calculation of aeroacoustic phenomena, especially in the presence of shock waves. One such phenomenon is "transonic resonance," where an unsteady shock wave at the throat of a convergent-divergent nozzle results in the emission of acoustic tones. The space-time Conservation-Element and Solution-Element (CE/SE) method developed at the NASA Glenn Research Center can faithfully capture the shock waves, their unsteady motion, and the generated acoustic tones. The CE/SE method is a revolutionary new approach to the numerical modeling of physical phenomena where features with steep gradients (e.g., shock waves, phase transition, etc.) must coexist with those having weaker variations. The CE/SE method does not require the complex interpolation procedures (that allow for the possibility of a shock between grid cells) used by many other methods to transfer information between grid cells. These interpolation procedures can add too much numerical dissipation to the solution process. Thus, while shocks are resolved, weaker waves, such as acoustic waves, are washed out.

Other Subject(s)

Acoustics

Collection

NASA Technical Reports Server (NTRS) Collection.

Note

Document ID: 20050203876.
Research and Technology 2001; NASA/TM-2002-211333.

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