Buckling surrogate-based optimization framework for hierarchical stiffened composite shells by enhanced variance reduction method

Tian, Kuo; Zhang, Jiaxin; Ma, Xiangtao; Li, Yuwei; Sun, Yuwen; Hao, Peng

doi:10.1177/0731684419862350

Cited by 11 publications

(2 citation statements)

References 65 publications

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“…Different from the conventional lattice stiffened cylinders with uniform basic ribs, the hierarchical stiffened cylinders are composed of two kinds of ribs: the primary ribs and the basic ribs. Wang's team found that the hierarchical stiffened cylinders can effectively resist localized deformation, showcasing high load‐bearing capacity and efficiency through theoretical models 11–14 . In practice, researchers have combined the hierarchical design with composite materials to construct lightweight, full‐composite hierarchical gird‐stiffened panels for anti‐blast protective doors 15–19 .…”

Section: Introductionmentioning

confidence: 99%

“…Wang's team found that the hierarchical stiffened cylinders can effectively resist localized deformation, showcasing high load-bearing capacity and efficiency through theoretical models. [11][12][13][14] In practice, researchers have combined the hierarchical design with composite materials to construct lightweight, fullcomposite hierarchical gird-stiffened panels for anti-blast protective doors. [15][16][17][18][19] With advancements in manufacturing technology, carbon fiber-reinforced polymer hierarchical isogrid stiffened cylinders 20 and hierarchical orthogrid stiffened cylinders 21 have been designed, manufactured, and tested.…”

Section: Introductionmentioning

confidence: 99%

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Manufacturing and mechanical properties of adjustable stiffness hierarchical orthogrid stiffened cylinders

Wang,

Chen,

Qin

et al. 2024

Polymer Composites

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Modular spacecraft offer promising prospects in the aerospace industry due to their ability to adapt to complex missions and diverse space environments. Nevertheless, such spacecraft may face load‐bearing structure adaptation issues caused by the changes in load demand when replacing sub‐modules for various missions. This necessitates the re‐design and manufacturing of load‐bearing structures, resulting in significant increases in product cycles and costs. To overcome this challenge, innovative composite hierarchical orthogrid stiffened cylinders (CHOSCs) which offer adjustable stiffness and strength to suit various mission requirements are proposed. To investigate the stiffness and strength adjustability, high‐precision composite orthogrid stiffened cylinder (COSC), CHOSC with three primary ribs (T‐CHOSC), and CHOSC with four primary ribs (F‐CHOSC) were manufactured and tested. The results demonstrate that CHOSCs exhibit stiffness and strength adjustability and significantly improve the cylinder's load‐bearing efficiency. Furthermore, a finite element model based on the Hashin damage criterion was employed to capture the end failure of the primary ribs and the local basic rib fractures near the cylinder end. CHOSCs present a feasible solution to the load‐bearing structure adaptation issues caused by the changes in load demand when replacing sub‐modules for various missions and hold significant potential for advancing the aerospace industry.Highlights Composite hierarchical orthogrid stiffened cylinders (CHOSCs) are proposed. High‐precision CHOSCs are manufactured by combined metal molds. Load‐bearing capacity and failure behavior are investigated. CHOSCs exhibit stiffness adjustability and load‐bearing efficiency. CHOSCs could solve the structure adaptation issues in modular spacecraft.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Manufacturing and mechanical properties of adjustable stiffness hierarchical orthogrid stiffened cylinders

Wang,

Chen,

Qin

et al. 2024

Polymer Composites

View full text Add to dashboard Cite

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Design and optimization of tapered carbon‐fiber‐reinforced polymer rim for carbon/aluminum assembled wheel

Wang

et al. 2020

Polymer Composites

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A multi‐objective integrated optimization framework that considers the manufacturing process in the design of a tapered carbon‐fiber‐reinforced polymer (CFRP) rim structure was established. Firstly, the three‐zone symmetrically stacked CFRP rim structure was proposed and modeled. The bending and radial fatigue and 13° impact of the carbon/aluminum‐assembled wheel composed of CFRP rim and aluminum alloy spoke were analysed. Coupling lay‐up thickness, sequence and angle as design variables, multi‐objective integrated optimization design for the tapered CFRP rim structure was performed through radial basis function neural network surrogate model combined with an elitist non‐dominated sorting genetic algorithm approach. Pareto‐optimal solutions were obtained, and the trade‐off solution was selected through grey relational analysis coupled with entropy weighting method. Finally, the tapered CFRP rim was manufactured through molding and autoclave forming technology. The CFRP rim has a weight saving of 17.2% compared with the previously developed forged magnesium alloy rim of the same size. The bending and radial fatigue and 13° impact performance of the assembled wheel were then validated by corresponding physical test, results of which met GB 36581‐2018 standard.

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AK-GWO: a novel hybrid optimization method for accurate optimum hierarchical stiffened shells

Kolahchi

Tian

Keshtegar

et al. 2020

Engineering with Computers

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Buckling surrogate-based optimization framework for hierarchical stiffened composite shells by enhanced variance reduction method

Cited by 11 publications

References 65 publications

Manufacturing and mechanical properties of adjustable stiffness hierarchical orthogrid stiffened cylinders

Manufacturing and mechanical properties of adjustable stiffness hierarchical orthogrid stiffened cylinders

Design and optimization of tapered carbon‐fiber‐reinforced polymer rim for carbon/aluminum assembled wheel

AK-GWO: a novel hybrid optimization method for accurate optimum hierarchical stiffened shells

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