Adaptive topology optimization for enhancing resistance to brittle fracture using the phase field model
Computational cost is one of the challenges in the field of fracture resistance topology optimization. An efficient topology optimization approach is proposed for enhancing resistance to structural fracture based on the adaptive isogeometric–meshfree method. The mesh can be adaptively refined in the...
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sg-ntu-dr.10356-1807292024-10-22T04:24:50Z Adaptive topology optimization for enhancing resistance to brittle fracture using the phase field model Zhang, Qi Liu, Yang Nguyen-Thanh, Nhon Li, Weidong Li, Shaofan Zhou, Kun School of Mechanical and Aerospace Engineering Engineering Topology optimization Brittle fracture Computational cost is one of the challenges in the field of fracture resistance topology optimization. An efficient topology optimization approach is proposed for enhancing resistance to structural fracture based on the adaptive isogeometric–meshfree method. The mesh can be adaptively refined in the computational and design domains simultaneously to capture the fracture and structural boundary delicately, which significantly reduces the degree of freedom and improves the efficiency of the topology optimization problems related to crack propagation. The proposed approach naturally inherits the advantages of both the computer-aided design and continuity of the higher-order basis functions, where the geometry and the analysis models in the process of topology optimization are integrated. The problem is formulated to maximize the absorbed energy throughout the crack process using the solid isotropic material with penalization method under volume constraints. The phase field method is used for modeling crack propagation, thereby eliminating the need of an explicit representation of the crack surface and complex tracking procedures, while a delicate mesh is still required. With this approach, the external work required during the fracture process is maximized, and the crack growth is delayed remarkably. Several representative examples are demonstrated to verify the effectiveness of the present approach in fracture-resistance-enhanced topology optimization, and the computational cost shows remarkable improvement. This work was supported by the National Research Foundation, Prime Minister’s Office, Singapore under its Medium-Sized Centre funding scheme through the Marine and Offshore Program, and the Singapore Centre for 3D Printing. 2024-10-22T04:24:50Z 2024-10-22T04:24:50Z 2024 Journal Article Zhang, Q., Liu, Y., Nguyen-Thanh, N., Li, W., Li, S. & Zhou, K. (2024). Adaptive topology optimization for enhancing resistance to brittle fracture using the phase field model. Computer Methods in Applied Mechanics and Engineering, 431, 117237-. https://dx.doi.org/10.1016/j.cma.2024.117237 0045-7825 https://hdl.handle.net/10356/180729 10.1016/j.cma.2024.117237 2-s2.0-85200161587 431 117237 en Computer Methods in Applied Mechanics and Engineering © 2024 Elsevier B.V. All rights are reserved, including those for text and data mining, AI training, and similar technologies. |
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Engineering Topology optimization Brittle fracture Zhang, Qi Liu, Yang Nguyen-Thanh, Nhon Li, Weidong Li, Shaofan Zhou, Kun Adaptive topology optimization for enhancing resistance to brittle fracture using the phase field model |
| description |
Computational cost is one of the challenges in the field of fracture resistance topology optimization. An efficient topology optimization approach is proposed for enhancing resistance to structural fracture based on the adaptive isogeometric–meshfree method. The mesh can be adaptively refined in the computational and design domains simultaneously to capture the fracture and structural boundary delicately, which significantly reduces the degree of freedom and improves the efficiency of the topology optimization problems related to crack propagation. The proposed approach naturally inherits the advantages of both the computer-aided design and continuity of the higher-order basis functions, where the geometry and the analysis models in the process of topology optimization are integrated. The problem is formulated to maximize the absorbed energy throughout the crack process using the solid isotropic material with penalization method under volume constraints. The phase field method is used for modeling crack propagation, thereby eliminating the need of an explicit representation of the crack surface and complex tracking procedures, while a delicate mesh is still required. With this approach, the external work required during the fracture process is maximized, and the crack growth is delayed remarkably. Several representative examples are demonstrated to verify the effectiveness of the present approach in fracture-resistance-enhanced topology optimization, and the computational cost shows remarkable improvement. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Zhang, Qi Liu, Yang Nguyen-Thanh, Nhon Li, Weidong Li, Shaofan Zhou, Kun |
| format |
Article |
| author |
Zhang, Qi Liu, Yang Nguyen-Thanh, Nhon Li, Weidong Li, Shaofan Zhou, Kun |
| author_sort |
Zhang, Qi |
| title |
Adaptive topology optimization for enhancing resistance to brittle fracture using the phase field model |
| title_short |
Adaptive topology optimization for enhancing resistance to brittle fracture using the phase field model |
| title_full |
Adaptive topology optimization for enhancing resistance to brittle fracture using the phase field model |
| title_fullStr |
Adaptive topology optimization for enhancing resistance to brittle fracture using the phase field model |
| title_full_unstemmed |
Adaptive topology optimization for enhancing resistance to brittle fracture using the phase field model |
| title_sort |
adaptive topology optimization for enhancing resistance to brittle fracture using the phase field model |
| publishDate |
2024 |
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https://hdl.handle.net/10356/180729 |
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1814777722791002112 |