Topology optimization for three-phase materials distribution in a dissipative expansion chamber by unified multiphase modeling approach

Topology optimization for three-phase materials distribution in a dissipative expansion chamber by unified multiphase modeling approach

The sound attenuation performance of a dissipative expansion chamber is a combinational result of reflective and dissipative effects. Although it is well known that the performance can be substantially improved by altering the distribution of constituent materials, the process of finding an optimal...

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Bibliographic Details
Published in:Computer methods in applied mechanics and engineering Vol. 287; pp. 191 - 211
Main Authors: Lee, Joong Seok, Göransson, Peter, Kim, Yoon Young
Format: Journal Article
Language:English
Published: Elsevier B.V 15-04-2015
Subjects:
Biot's equations
Chambers
Design engineering
Dissipation
Expansion chamber design
Mathematical analysis
Mathematical models
Multiphase
Optimization
Poroelastic material
Topology optimization
Unified multiphase modeling
Expansion chamber design
Unified multiphase modeling
Topology optimization
Poroelastic material
Biot’s equations
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Summary:The sound attenuation performance of a dissipative expansion chamber is a combinational result of reflective and dissipative effects. Although it is well known that the performance can be substantially improved by altering the distribution of constituent materials, the process of finding an optimal distribution of the materials still remains a challenge. This work proposes a new design method for interior space of a dissipative expansion chamber by using topology optimization method. Different from the existing topology optimizations for expansion chamber designs based on simplified material modeling, the present design deals with fully-modeled multiphase constituent materials, such as acoustic, poroelastic and elastic one. Difficulties in the optimization formulation for the multiphase material distribution arise from extremely-different acoustic behavior of the materials and the use of various governing equations for different phase materials. To systematically vary the attributes of the chamber interior space, a unified multiphase modeling approach that allows continuous variations between the three-phase materials within the same implementation is employed with an elaborately-derived penalty parameters of material interpolation functions. Various design examples are successfully solved for wide frequency bands and the optimal configurations clearly demonstrate the importance of using specific configurations tuned to different target frequencies. •Topology optimization of dissipative expansion chamber with multiphase materials.•Fully-modeled different constituents—acoustic, poroelastic and elastic materials.•Unified handling of multiphase material states and their interface couplings.•Elaborate penalization scheme for material interpolation.•Optimized designs suitable for practical fabrication.
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ISSN:0045-7825
1879-2138
1879-2138
DOI:10.1016/j.cma.2015.01.011