02089nam a22002297a 4500003000400000005001700004008004100021020001800062040001000080082001500090100004700105245005600152260002800208300001000236365003700246505135800283650002501641700003101666942001201697999001701709952013301726OSt20230925150719.0230921b        |||||||| |||| 00| 0 eng d  a9783035617863  ckrvia  a720.1bKNI1 aKnippers, Jan; Schmid,Ulrich (Ed.)  9522210aBiomimetics for Architecture: Learning from Nature   aBaselbBirkhauserc2019  a208p.  aRs.bRs. 2842cRs.d20eRs. 2274  aPreface  p.6, Why biomimetics? p.8, Everything Moves p.12, Plants in action p.14, Movement without joints: (how) does it work? p.22, No joint ailments: how plants move and inspire technology p.32, From pure research to biomimetic products: the Flectofold facade shading device p.42, Lightweight Versatility: Structure Instead of Mass p.52, Reliably withstanding high loads p.54, Freezing: the right way p.74, Nature as source of ideas for modern manufacturing methods p.84, Rosenstein Pavilion: a lightweight concrete shell based on principles of biological structures p.92, Elegance and Lightness: Bio-Inspired Domes p.102, Building principles and structural design of sea urchins: examples of bio-inspired constructions p.104, Potential applications of segmented shells in architecture p.116, Snails as living 3D printers: free forms for the architecture of tomorrow p.126, Evolutive approaches to explorative design methods in architecture p.134, Branched Load Support Systems p.142, From plant branchings to technical support structures p.144,  New branched loadbearing structures in architecture p.153, The plastid skeleton: a source of ideas in the nano range p. 163, Abstracting instead of copying: in search of the formula for success p.167, Functionalist, organic, and biomimetic architecture p.172, The biomimetic promise p.180, Appendix p.18810aArchitectural Theory1 aSpeck, Thomas (Eds.)95223  2ddccBK  c10176d10176  00102ddc40708NFICaKRVIAbKRVIAd2023-08-30eBurhani Book Centrel4o720.1 KNIp8399r2026-02-23s2026-02-06w2023-09-21yBK