%0 Book Section %1 wood2023hygroshell %A Wood, Dylan %A Kiesewetter, Laura %A Körner, Axel %A Takahashi, Kenryo %A Knippers, Jan %A Menges, Achim %B Advances in Architectural Geometry 2023 %D 2023 %E Dörfler, Kathrin %E Knippers, Jan %E Menges, Achim %E Parascho, Stefana %E Pottmann, Helmut %E Wortmann, Thomas %I De Gruyter %K 2023 architecture curved hygroshell itke kiesewetter knippers körner menges self-shaping shell situ takahashi timber wood %P 43-54 %R https://doi.org/10.1515/9783111162683-004 %T HYGROSHELL – In Situ Self-shaping of Curved Timber Shells %X Curved, surface-active, shell structures are known for material efficiency and slenderness but typically require complex manufacturing and formwork in combination with intricate on-site construction processes. The presented research proposes an alternative approach: a self-shaping building system for deploying lightweight, curved surface structures made from timber. The system uses the inherent hygromorphic properties of wood which naturally shrinks through drying. This anisotropic shape change is embedded into large-scale bilayer sheets - produced, machined, and shingle clad in a flat state with their later curved shape and connection detailing physically programmed within the material build-ups. When placed on-site, these sheets actuate through air drying to a final curved and interlocked geometry. Geometrically the structure is integratively designed from variable single curved surfaces using key material parameters (end grain angle and moisture content change) within a material stock, in relation to both the self-shaping and the final structural configuration. Each surface is modeled in the curved state using a board specific algorithmic calculation of curvature potential in parallel to a flat fabrication model. Emphasis is placed on investment in early-stage planning and intelligent material arrangement as a method to produce useful curvature. As a result, the curved shell shapes and interlocks without formwork or external mechanical force, with little onsite work. The outcome is a lightweight, longspan roof structure built from single curved wood surfaces with a thin cross-laminated build up. The project demonstrates a tangible new method of low impact, light touch self-construction and an ecologically effective use of material and geometry. %@ 9783111160115

@inbook{wood2023hygroshell, abstract = {Curved, surface-active, shell structures are known for material efficiency and slenderness but typically require complex manufacturing and formwork in combination with intricate on-site construction processes. The presented research proposes an alternative approach: a self-shaping building system for deploying lightweight, curved surface structures made from timber. The system uses the inherent hygromorphic properties of wood which naturally shrinks through drying. This anisotropic shape change is embedded into large-scale bilayer sheets - produced, machined, and shingle clad in a flat state with their later curved shape and connection detailing physically programmed within the material build-ups. When placed on-site, these sheets actuate through air drying to a final curved and interlocked geometry. Geometrically the structure is integratively designed from variable single curved surfaces using key material parameters (end grain angle and moisture content change) within a material stock, in relation to both the self-shaping and the final structural configuration. Each surface is modeled in the curved state using a board specific algorithmic calculation of curvature potential in parallel to a flat fabrication model. Emphasis is placed on investment in early-stage planning and intelligent material arrangement as a method to produce useful curvature. As a result, the curved shell shapes and interlocks without formwork or external mechanical force, with little onsite work. The outcome is a lightweight, longspan roof structure built from single curved wood surfaces with a thin cross-laminated build up. The project demonstrates a tangible new method of low impact, light touch self-construction and an ecologically effective use of material and geometry.}, added-at = {2023-10-30T15:05:11.000+0100}, author = {Wood, Dylan and Kiesewetter, Laura and Körner, Axel and Takahashi, Kenryo and Knippers, Jan and Menges, Achim}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2b2d16668eeb8b003f3644421f5707020/petraheim}, booktitle = {Advances in Architectural Geometry 2023}, day = 4, doi = {https://doi.org/10.1515/9783111162683-004}, editor = {Dörfler, Kathrin and Knippers, Jan and Menges, Achim and Parascho, Stefana and Pottmann, Helmut and Wortmann, Thomas}, interhash = {7ccfc659b13cd3cb1b2037816e90a07b}, intrahash = {b2d16668eeb8b003f3644421f5707020}, isbn = {9783111160115}, keywords = {2023 architecture curved hygroshell itke kiesewetter knippers körner menges self-shaping shell situ takahashi timber wood}, language = {eng}, month = oct, pages = {43-54}, publisher = {De Gruyter}, series = {De Gruyter STEM}, timestamp = {2023-10-30T15:05:11.000+0100}, title = {HYGROSHELL – In Situ Self-shaping of Curved Timber Shells}, year = 2023 }