The applications of fiber-reinforced polymer (FRP) composites extend rapidly along with the development of new manufacturing techniques. However, due to the complexities introduced by the material and fabrication processes, the application of conventional structural design methods for construction members has been significantly challenging. This paper presents an alternative methodology to find optimum fiber layups for a given tube-shape geometry via a graphical optimization strategy based on structural performance requirements. The proposed technique employs simplified shell element models based on classical lamination theory (CLT) to avoid explicit fiber modeling in the FEA simulations. Lamination parameters are utilized to generate the reduced stiffness matrices for continuous multi-layer FRP lamination. The fiber layup of the component is retrieved from the optimal lamination parameters that maximize the structural performance. The case study results demonstrate that the developed method provides compact solutions, linking the structural design requirements with optimal fiber orientations and volumetric proportions. In addition, the determined solutions can be interpreted directly by the winding fabrication settings.
%0 Journal Article
%1 guo2022design
%A Guo, Yanan
%A Gil Pérez, Marta
%A Serhat, Gokhan
%A Knippers, Jan
%D 2022
%I ELSEVIER SCI LTD
%J Structures
%K Finite layup fiber knippers 2022 engineering analysis filament Fiber-reinforced itke serhan from:petraheim winding (FEA) Lamination parameters methodology components guo buckling polymer gil wound design optimization structural (FRP) element Coreless architecture
%P 1125-1136
%R https://doi.org/10.1016/j.istruc.2022.02.048
%T A design methodology for fiber layup optimization of filament wound structural components
%V 38
%X The applications of fiber-reinforced polymer (FRP) composites extend rapidly along with the development of new manufacturing techniques. However, due to the complexities introduced by the material and fabrication processes, the application of conventional structural design methods for construction members has been significantly challenging. This paper presents an alternative methodology to find optimum fiber layups for a given tube-shape geometry via a graphical optimization strategy based on structural performance requirements. The proposed technique employs simplified shell element models based on classical lamination theory (CLT) to avoid explicit fiber modeling in the FEA simulations. Lamination parameters are utilized to generate the reduced stiffness matrices for continuous multi-layer FRP lamination. The fiber layup of the component is retrieved from the optimal lamination parameters that maximize the structural performance. The case study results demonstrate that the developed method provides compact solutions, linking the structural design requirements with optimal fiber orientations and volumetric proportions. In addition, the determined solutions can be interpreted directly by the winding fabrication settings.
@article{guo2022design,
abstract = {The applications of fiber-reinforced polymer (FRP) composites extend rapidly along with the development of new manufacturing techniques. However, due to the complexities introduced by the material and fabrication processes, the application of conventional structural design methods for construction members has been significantly challenging. This paper presents an alternative methodology to find optimum fiber layups for a given tube-shape geometry via a graphical optimization strategy based on structural performance requirements. The proposed technique employs simplified shell element models based on classical lamination theory (CLT) to avoid explicit fiber modeling in the FEA simulations. Lamination parameters are utilized to generate the reduced stiffness matrices for continuous multi-layer FRP lamination. The fiber layup of the component is retrieved from the optimal lamination parameters that maximize the structural performance. The case study results demonstrate that the developed method provides compact solutions, linking the structural design requirements with optimal fiber orientations and volumetric proportions. In addition, the determined solutions can be interpreted directly by the winding fabrication settings.},
added-at = {2022-04-22T12:30:17.000+0200},
author = {Guo, Yanan and Gil Pérez, Marta and Serhat, Gokhan and Knippers, Jan},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/27e2ca5a3aff35c16bb99676c359876b3/itke},
doi = {https://doi.org/10.1016/j.istruc.2022.02.048},
institution = {Institute of Building Structures and Structural Design (ITKE) Haptic Intelligence Department, Max Planck Institute for Intelligent Systems},
interhash = {4f98bbc60a12e811d97756c7daf76b15},
intrahash = {7e2ca5a3aff35c16bb99676c359876b3},
journal = {Structures},
keywords = {Finite layup fiber knippers 2022 engineering analysis filament Fiber-reinforced itke serhan from:petraheim winding (FEA) Lamination parameters methodology components guo buckling polymer gil wound design optimization structural (FRP) element Coreless architecture},
language = {eng},
month = apr,
pages = {1125-1136},
publisher = {ELSEVIER SCI LTD},
school = {University of Stuttgart},
timestamp = {2022-04-22T10:30:17.000+0200},
title = {A design methodology for fiber layup optimization of filament wound structural components},
volume = 38,
year = 2022
}