A Digital Approach to the Aeroacoustic Evaluation of HVAC Blowers

July 2017, Volume 119, Issue 7–8, pp 50–53 | Cite as

Development Simulation and Testing

First Online: 28 June 2017

This is a preview of subscription content, to check access.

References

[1]
Le Goff, V.; Le Henaff, B.; Piellard, M.; Pihet, D.; Coutty, B.: Towards a Full Digital Approach for Aeroacoustics Evaluation of Automotive Engine Cooling Fans and HVAC Blowers. Fan 2015, Lyon, France, 2015Google Scholar
[2]
ISO 3744: Acoustics — Determination of sound power levels and sound energy levels of noise sources using sound pressure — Engineering methods for an essentially free field over a reflecting plane. Dissertation, 2010Google Scholar
[3]
Piellard, M.; Coutty, B.; Le Goff, V.; Pérot, F.; Vidal, V: Direct aeroacoustics simulation of automotive engine cooling fan system: effect of upstream geometry on broadband noise. 20^th AIAA/CEAS Aeroacoustics Conference, Atlanta, GA, 2014Google Scholar
[4]
Brès, G. A.; Pérot, F.; Freed, D.: Properties of the Lattice Boltzmann Method for Acoustics. 15^th AIAA/CEAS Aeroacoustics Conference, Miami, Florida, USA, 2009Google Scholar
[5]
Brès, G. A.; Pérot, F.; Freed, D.: A Ffowcs Williams-Hawkings Solver for Lattice Boltzmann Based Computational Aeroacoustics. AIAA Paper 2010-3711, of the 16^th AIAA/CEAS Aeroacoustics Conference, Stockholm, 2010Google Scholar
[6]
Mann, A.; Pérot, F.; Meskine, M.; Kim, M. S.: Designing quieter HVAC systems coupling LBM and flow-induced noise source identification methods. 10^th FKFS Conference, Stuttgart, Germany, 2015Google Scholar