Dynamic topology optimization for structures exhibiting frequency-dependent material properties with prescribed frequency forbidden band

Dynamic topology optimization for structures exhibiting frequency-dependent material properties with prescribed frequency forbidden band

In dynamic vibration reduction design, the frequency-dependent material properties are crucial for the optimal configuration, especially in the problem of prescribed frequency forbidden band. In this paper, a new dynamic topology optimization method for structures with frequency-dependent material p...

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Bibliographic Details
Published in:Computer methods in applied mechanics and engineering Vol. 432; p. 117439
Main Authors: Wu, Qiangbo, Li, Quhao, Liu, Shutian
Format: Journal Article
Language:English
Published: Elsevier B.V 01-12-2024
Subjects:
Continuous asymptotic numerical method (CANM)
Dynamic isolated structures elimination method
Frequency-dependent material properties
Nonlinear eigenvalue problem
Prescribed frequency forbidden band
Topology optimization
Continuous asymptotic numerical method (CANM)
Topology optimization
Frequency-dependent material properties
Prescribed frequency forbidden band
Dynamic isolated structures elimination method
Nonlinear eigenvalue problem
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Summary:In dynamic vibration reduction design, the frequency-dependent material properties are crucial for the optimal configuration, especially in the problem of prescribed frequency forbidden band. In this paper, a new dynamic topology optimization method for structures with frequency-dependent material properties is proposed to achieve the vibration reduction design in the prescribed frequency forbidden band. First, a dynamic topology optimization model is established for the problem studied in this paper. This model integrates the solution method for frequency-dependent problem, dynamic isolated structures elimination method and the formulation of prescribed frequency forbidden band constraints, which are based on the research results previously developed by the authors. Additionally, different interpolation schemes are used for different number of material designs. The above optimization model is intended to consider nonlinear terms and design several frequency-dependent structures with prescribed frequency forbidden bands that are more in line with practical engineering problems, so that they can accurately avoid the operating frequency range, thus improving the service life of engineering equipment. Finally, to address common numerical problems, the "bound formulation" and "robust formulation" are employed, enhancing the applicability and robustness of the method for the application in topology optimization. The effectiveness of the developed method is supported by two types optimization problems, including single-material and bi-material examples. The cross-check results reveal that when considering frequency-dependent terms, the design results are better and closer to the practical engineering problem compared to linear structures.
ISSN:0045-7825
DOI:10.1016/j.cma.2024.117439