Validation of a Hybrid Nonlinear Approach for Jet Noise Prediction and Characterization

Sassanis, V., Blake, J., Sescu, A., Collins, E. M., Harris, R. E., & Luke, E. (2017). Validation of a Hybrid Nonlinear Approach for Jet Noise Prediction and Characterization. Journal of the Acoustical Society of America. New Orleans, LA: Acoustical Society of America. 142(4), 2491-2492. DOI:10.1121/1.5014095.

Abstract

In this study, a hybrid approach for non-linear jet noise predictions in complex environments is presented and validated. The method differs from traditional approaches in that interactions of the jet with the surrounding structures as well as non-linear disturbances propagating over large distances are taken into consideration in order to quantify their effects on sound generation and propagation. The noise sources founded in the jet plume and the near-field are first computed using the full Navier-Stokes equations. The variables of interest are then interpolated into a second domain. After penalized, they are used as source terms in the non-linear Euler equations to calculate the sound propagation. The interpolation and penalization steps are performed using a buffer region designed by the principles of sponge layers. The effective one-way communication between the two domains and the capabilities of the buffer region to transfer the data from the NS to the Euler domain without any loss of detail is demonstrated. Results from two- and three-dimensional jets both in free space and interacting with solid obstacles are presented. Comparisons with DNC and experimental data in terms of sound pressure level spectra are in good agreement with the ones calculated by our method.