A two-stage design optimization framework for multifield origami-inspired structures. (January 2022)
- Record Type:
- Journal Article
- Title:
- A two-stage design optimization framework for multifield origami-inspired structures. (January 2022)
- Main Title:
- A two-stage design optimization framework for multifield origami-inspired structures
- Authors:
- Zhang, Wei
Ahmed, Saad
Hong, Jonathan
Ounaies, Zoubeida
Frecker, Mary - Abstract:
- Different types of active materials have been used to actuate origami-inspired self-folding structures. To model the highly nonlinear deformation and material responses, as well as the coupled field equations and boundary conditions of such structures, high-fidelity models such as finite element (FE) models are needed but usually computationally expensive, which makes optimization intractable. In this paper, a computationally efficient two-stage optimization framework is developed as a systematic method for the multi-objective designs of such multifield self-folding structures where the deformations are concentrated in crease-like areas, active and passive materials are assumed to behave linearly, and low- and high-fidelity models of the structures can be developed. In Stage 1, low-fidelity models are used to determine the topology of the structure. At the end of Stage 1, a distance measureU is applied as the metric to determine the best design, which then serves as the baseline design in Stage 2. In Stage 2, designs are further optimized from the baseline design with greatly reduced computing time compared to a full FEA-based topology optimization. The design framework is first described in a general formulation. To demonstrate its efficacy, this framework is implemented in two case studies, namely, a three-finger soft gripper actuated using a PVDF-based terpolymer, and a 3D multifield example actuated using both the terpolymer and a magneto-active elastomer, where the keyDifferent types of active materials have been used to actuate origami-inspired self-folding structures. To model the highly nonlinear deformation and material responses, as well as the coupled field equations and boundary conditions of such structures, high-fidelity models such as finite element (FE) models are needed but usually computationally expensive, which makes optimization intractable. In this paper, a computationally efficient two-stage optimization framework is developed as a systematic method for the multi-objective designs of such multifield self-folding structures where the deformations are concentrated in crease-like areas, active and passive materials are assumed to behave linearly, and low- and high-fidelity models of the structures can be developed. In Stage 1, low-fidelity models are used to determine the topology of the structure. At the end of Stage 1, a distance measureU is applied as the metric to determine the best design, which then serves as the baseline design in Stage 2. In Stage 2, designs are further optimized from the baseline design with greatly reduced computing time compared to a full FEA-based topology optimization. The design framework is first described in a general formulation. To demonstrate its efficacy, this framework is implemented in two case studies, namely, a three-finger soft gripper actuated using a PVDF-based terpolymer, and a 3D multifield example actuated using both the terpolymer and a magneto-active elastomer, where the key steps are elaborated in detail, including the variable filter, metrics to select the best design, determination of design domains, and material conversion methods from low- to high-fidelity models. In this paper, analytical models and rigid body dynamic models are developed as the low-fidelity models for the terpolymer- and MAE-based actuations, respectively, and the FE model of the MAE-based actuation is generalized from previous work. Additional generalizable techniques to further reduce the computational cost are elaborated. As a result, designs with better overall performance than the baseline design were achieved at the end of Stage 2 with computing times of 15 days for the gripper and 9 days for the multifield example, which would rather be over 3 and 2 months for full FEA-based optimizations, respectively. Tradeoffs between the competing design objectives were achieved. In both case studies, the efficacy and computational efficiency of the two-stage optimization framework are successfully demonstrated. … (more)
- Is Part Of:
- Journal of intelligent material systems and structures. Volume 33:Number 1(2022)
- Journal:
- Journal of intelligent material systems and structures
- Issue:
- Volume 33:Number 1(2022)
- Issue Display:
- Volume 33, Issue 1 (2022)
- Year:
- 2022
- Volume:
- 33
- Issue:
- 1
- Issue Sort Value:
- 2022-0033-0001-0000
- Page Start:
- 46
- Page End:
- 69
- Publication Date:
- 2022-01
- Subjects:
- Structural optimization -- origami -- electroactive polymer -- magnetoactive elastomer -- multifield actuation
Smart materials -- Periodicals
Intelligent control systems -- Periodicals
Artificial intelligence -- Periodicals
Matériaux intelligents -- Périodiques
Commande intelligente -- Périodiques
Intelligence artificielle -- Périodiques
620.11 - Journal URLs:
- http://jim.sagepub.com/ ↗
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http://firstsearch.oclc.org ↗
http://firstsearch.oclc.org/journal=1045-389x;screen=info;ECOIP ↗ - DOI:
- 10.1177/1045389X211011659 ↗
- Languages:
- English
- ISSNs:
- 1045-389X
- Deposit Type:
- Legaldeposit
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