Fiber-reinforced composites offer innovative solutions for architectural applications with high strength and low weight. Coreless filament winding extends industrial processes, reduces formwork, and allows for tailoring of fiber layups to specific requirements. A previously developed computational co-design framework for coreless filament winding is extended toward the integration of reciprocal design feedback to maximize design flexibility and inform design decisions throughout the process. A multi-scalar design representation is introduced, representing fiber structures at different levels of detail to generate feedback between computational design, engineering, and fabrication. Design methods for global, component, and material systems are outlined and feedback generation is explained. Structural and fabrication feedback are classified, and their integration is described in detail. This paper demonstrates how reciprocal feedback allows for co-evolution of domains of expertise and extends the existing co-design framework toward design problems. The developed methods are shown in two case studies at a global and component scale.
%0 Journal Article
%1 Kannenberg2024
%A Kannenberg, Fabian
%A Zechmeister, Christoph
%A Gil Pérez, Marta
%A Guo, Yanan
%A Yang, Xiliu
%A Forster, David
%A Hügle, Sebastian
%A Mindermann, Pascal
%A Abdelaal, Moataz
%A Balangé, Laura
%A Schwieger, Volker
%A Weiskopf, Daniel
%A Gresser, Götz T
%A Middendorf, Peter
%A Bischoff, Manfred
%A Knippers, Jan
%A Menges, Achim
%D 2024
%J Journal of Computational Design and Engineering
%K abm bd2 fibre icd iigs myown peer phd rp11 rp12 rp14 rp18 rp4
%N 3
%P 374-394
%R 10.1093/jcde/qwae048
%T Toward reciprocal feedback between computational design, engineering, and fabrication to co-design coreless filament-wound structures
%U https://doi.org/10.1093/jcde/qwae048
%V 11
%X Fiber-reinforced composites offer innovative solutions for architectural applications with high strength and low weight. Coreless filament winding extends industrial processes, reduces formwork, and allows for tailoring of fiber layups to specific requirements. A previously developed computational co-design framework for coreless filament winding is extended toward the integration of reciprocal design feedback to maximize design flexibility and inform design decisions throughout the process. A multi-scalar design representation is introduced, representing fiber structures at different levels of detail to generate feedback between computational design, engineering, and fabrication. Design methods for global, component, and material systems are outlined and feedback generation is explained. Structural and fabrication feedback are classified, and their integration is described in detail. This paper demonstrates how reciprocal feedback allows for co-evolution of domains of expertise and extends the existing co-design framework toward design problems. The developed methods are shown in two case studies at a global and component scale.
@article{Kannenberg2024,
abstract = {{Fiber-reinforced composites offer innovative solutions for architectural applications with high strength and low weight. Coreless filament winding extends industrial processes, reduces formwork, and allows for tailoring of fiber layups to specific requirements. A previously developed computational co-design framework for coreless filament winding is extended toward the integration of reciprocal design feedback to maximize design flexibility and inform design decisions throughout the process. A multi-scalar design representation is introduced, representing fiber structures at different levels of detail to generate feedback between computational design, engineering, and fabrication. Design methods for global, component, and material systems are outlined and feedback generation is explained. Structural and fabrication feedback are classified, and their integration is described in detail. This paper demonstrates how reciprocal feedback allows for co-evolution of domains of expertise and extends the existing co-design framework toward design problems. The developed methods are shown in two case studies at a global and component scale.}},
added-at = {2024-07-03T15:43:44.000+0200},
author = {Kannenberg, Fabian and Zechmeister, Christoph and Gil Pérez, Marta and Guo, Yanan and Yang, Xiliu and Forster, David and Hügle, Sebastian and Mindermann, Pascal and Abdelaal, Moataz and Balangé, Laura and Schwieger, Volker and Weiskopf, Daniel and Gresser, Götz T and Middendorf, Peter and Bischoff, Manfred and Knippers, Jan and Menges, Achim},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/26bcb2902f8caa70463ff4ab9a4d224da/kannenberg},
doi = {10.1093/jcde/qwae048},
eprint = {https://academic.oup.com/jcde/article-pdf/11/3/374/58347694/qwae048.pdf},
interhash = {f3419687997eb8d786e0baa25f5018c7},
intrahash = {6bcb2902f8caa70463ff4ab9a4d224da},
issn = {2288-5048},
journal = {Journal of Computational Design and Engineering},
keywords = {abm bd2 fibre icd iigs myown peer phd rp11 rp12 rp14 rp18 rp4},
month = {05},
number = 3,
pages = {374-394},
timestamp = {2024-08-29T18:02:58.000+0200},
title = {{Toward reciprocal feedback between computational design, engineering, and fabrication to co-design coreless filament-wound structures}},
url = {https://doi.org/10.1093/jcde/qwae048},
volume = 11,
year = 2024
}
