%0 Journal Article %1 Mindermann2024 %A Mindermann, Pascal %A Acker, Denis %A Wegner, Robert %A Fasoulas, Stefanos %A Gresser, Götz T. %D 2024 %J Scientific Reports %K Aerospace Characterization Composites Coreless Fiber Planetary analytical and composite engineering filament gresser itft mindermann structure sunshade techniques truss wegner winding %N 1 %P 8190 %R 10.1038/s41598-024-58513-w %T Long-span fiber composite truss made by coreless filament winding for large-scale satellite structural systems demonstrated on a planetary sunshade concept %U https://www.sciencedirect.com/science/article/pii/S266616592400053X %V 14 %X Climate change necessitates exploring innovative geoengineering solutions to mitigate its effects---one such solution is deploying planetary sunshade satellites at Sun--Earth Lagrange point 1 to regulate solar radiation on Earth directly. However, such long-span space structures present unique technical challenges, particularly structural scalability, on-orbit manufacturing, and in-situ resource utilization. This paper proposes a structural concept for the sunshade's foil support system and derives from that a component-level modular system for long-span fiber composite lightweight trusses using coreless filament winding. Within a laboratory-scale case study, the component scalability, as well as the manufacturing and material impacts, were experimentally investigated by bending deflection testing. Based on these experimental results, FE models of the proposed structural concept were calibrated to estimate the maximum displacement and mass of the foil support structure, while comparing the influences of foil edge length, orbital load case, and material selection.

@article{Mindermann2024, abstract = {Climate change necessitates exploring innovative geoengineering solutions to mitigate its effects---one such solution is deploying planetary sunshade satellites at Sun--Earth Lagrange point 1 to regulate solar radiation on Earth directly. However, such long-span space structures present unique technical challenges, particularly structural scalability, on-orbit manufacturing, and in-situ resource utilization. This paper proposes a structural concept for the sunshade's foil support system and derives from that a component-level modular system for long-span fiber composite lightweight trusses using coreless filament winding. Within a laboratory-scale case study, the component scalability, as well as the manufacturing and material impacts, were experimentally investigated by bending deflection testing. Based on these experimental results, FE models of the proposed structural concept were calibrated to estimate the maximum displacement and mass of the foil support structure, while comparing the influences of foil edge length, orbital load case, and material selection.}, added-at = {2024-04-17T14:35:40.000+0200}, author = {Mindermann, Pascal and Acker, Denis and Wegner, Robert and Fasoulas, Stefanos and Gresser, Götz T.}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2bec998b43dba4ea7bb81ccffabb01d44/itft-puma}, day = 08, doi = {10.1038/s41598-024-58513-w}, interhash = {11cacca053e90a302e1f78d756a37322}, intrahash = {bec998b43dba4ea7bb81ccffabb01d44}, issn = {2045-2322}, journal = {Scientific Reports}, keywords = {Aerospace Characterization Composites Coreless Fiber Planetary analytical and composite engineering filament gresser itft mindermann structure sunshade techniques truss wegner winding}, language = {eng}, month = {april}, number = 1, pages = 8190, timestamp = {2024-04-17T14:35:40.000+0200}, title = {Long-span fiber composite truss made by coreless filament winding for large-scale satellite structural systems demonstrated on a planetary sunshade concept}, url = {https://www.sciencedirect.com/science/article/pii/S266616592400053X}, volume = 14, year = 2024 }