This study aims to optimize the acoustic performance of a silencer with baffles having extension tubes. It considers the position, the number and the extension geometry of the baffles as design variables and sound transmission loss as the... more
This study aims to optimize the acoustic performance of a silencer with baffles having extension tubes. It considers the position, the number and the extension geometry of the baffles as design variables and sound transmission loss as the response variable to be optimized. The finite element analysis software ABAQUS is used to compute the response values for different combinations of design variables. The statistical design of the experiments provides a mathematical framework for such computer design optimization studies with multiple design variables. Yet, it has not been used for design optimization of silencers in the literature. In this study, simplex centroid mixture designs, a type of response surface method, are used in the statistical design of experiments. They can provide faster convergence on the optimization problem. The design involves one, two and three baffles with different positions and extension tube lengths. The outcome of this study indicates that obtaining ABAQU...
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Ranjbar, Mostafa/0000-0002-9670-7371; Arslan, Hakan/0000-0002-2019-1882WOS: 000495519000003The acoustic attenuation and performance analysis for blast flow field inside a silencer is investigated. In this regard, a silencer system is... more
Ranjbar, Mostafa/0000-0002-9670-7371; Arslan, Hakan/0000-0002-2019-1882WOS: 000495519000003The acoustic attenuation and performance analysis for blast flow field inside a silencer is investigated. In this regard, a silencer system is designed to reduce the exhaust noise. The effect of position and the number of the baffles for each design on sound transmission loss have been investigated using theoretical, numerical and experimental studies. Three prototypes are manufactured for the experimental studies. Using the measured results, insertion loss graphics have been obtained. The silencer performances are dependent on the baffle geometry, number and the positions. The experimental results are in a good agreement with the simulation results. It is observed that by considering the same number of baffle numbers but located at various locations, the model which shows the best sound transmission loss performance has also the best insertion loss performance and has the least value of peak sound pressure level. (C) 2019 Elsevier Ltd. All rights reserved.Mechanical and Chemical Industry Corporation of Turkey; Turkish Ministry of Science, Industry and TechnologyMinistry of Science, Industry & Technology - TurkeyThe authors want to express their appreciation to Mechanical and Chemical Industry Corporation of Turkey and the Turkish Ministry of Science, Industry and Technology for their support in this work