Form-finding of aluminum alloy reticulated structures considering joint rigidity

•Joint gap index is proposed for describing assembling convenience of aluminum alloy structures;•A form-finding method is proposed for aluminum alloy reticulated structures.•The proposed method is effective in providing a wide set of solutions with trade-off relations for engineers to choose.•Actual...

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Bibliographic Details
Published in:Engineering structures 2021-09, Vol.242, p.112618, Article 112618
Main Authors: Zhu, Shaojun, Ohsaki, Makoto, Zeng, Qiang, Guo, Xiaonong
Format: Article
Language:English
Subjects:
Algorithms
Aluminum
Aluminum alloy
Aluminum alloys
Aluminum base alloys
Force distribution
Form-finding
Free form
Internal forces
Joint rigidity
Mechanical properties
Multi-objective optimization
Multiple objective analysis
Optimization
Pareto optimization
Reticulated structures
Rigidity
Safety factors
Snow loads
Stress concentration
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Summary:•Joint gap index is proposed for describing assembling convenience of aluminum alloy structures;•A form-finding method is proposed for aluminum alloy reticulated structures.•The proposed method is effective in providing a wide set of solutions with trade-off relations for engineers to choose.•Actual joint rigidity should always be considered since it influences the form-finding result. This paper proposes a form-finding method of free-form aluminum alloy reticulated structures with semi-rigid gusset joints. The vertical coordinates of the control points of the B-spline surface are selected to be the design variables adjusting the shape of the structure. The joint gap index, which is proposed for characterizing the manufacturing and assembling convenience of aluminum alloy structures, the strain energy, and the safety factor under short-term snow load, are chosen as the objective functions of the multi-objective optimization problem. The Pareto optimal solutions of the numerical example indicate that slight differences in the structural shape can result in quite different mechanical behavior, and the NSGA-II algorithm is effective in providing a wide range of optimal structures as compromise solutions of the multi-objective problem. Finally, the same optimization problem is solved for rigid jointed structures to study the influence of the joint rigidity on the form-finding result. By comparison of the internal force distribution, it is found that the joint semi-rigidity will influence the optimal structural shape due to the difference in the load-bearing mechanism. Therefore, it is suggested that the actual joint rigidity should be considered in the structural optimization process of reticulated structures.
ISSN:0141-0296
1873-7323
DOI:10.1016/j.engstruct.2021.112618