Characterisation, modelling, and reduction of noise generated by stationary and mobile superchargers Abstract There are more than 2000 air blowers and compressors in Québec and their number is growing rapidly, This pumping device is a necessary piece of equipment for transferring dry bulk materials or for various public works. Called “blowers” or “vacuums”, these machines generate noise levels varying from 90 dB to 105 dB. The traditional solutions for noise reduction could not be applied to these devices. The researchers therefore worked on improving the design of this equipment in collaboration with the manufacturer Hibon. Theoretically, they developed software that used vibration measurements to predict structure-radiated noise. Practically, they developed a hybrid silencer consisting of a dissipative module of original design paired with a standard dissipative module, which absorbs and reduces the port noise by 10 dB(A). A software program and a design guide for booster silencers were also developed. Produced Under this Project Scientific Reports Characterization, modeling and reduction of noise from stationary and mobile superchargers Research Report: R-290 Simplified Articles Bruit : modérez vos transports ! Un logiciel favorise la conception de silencieux plus efficaces pour les systèmes surpresseurs Volume 15, n0 1 Scientific Publications Hybrid tool for quickly estimating the radiated acoustic power from a vibrating structure in a multi-sources environmentBeslin O., Foin O., Nicolas J.Source : Journal of the Acoustic Society of America, vol. 107, no 2, 2000, p. 840-850A new hybrid approach for estimating 'in situ' the acoustic power radiation from vibrating structuresNicolas J., Beslin O., Foin O.Source : 137th Meeting of the Acoustical Society of America (137th : March 14-19, 1999 : Berlin, Germany), 1999 Additional Information Type: Project Number: 0097-0220 Status: Completed Year of completion: 2002 Research Field: Mechanical and Physical Risk Prevention Team: François Charron (Université de Sherbrooke)Jean Nicolas (Université de Sherbrooke)Olivier Beslin (Université de Sherbrooke)Noureddine Atalla (Université de Sherbrooke)