enrique soriano's Videos (Grasshopper) - Grasshopper2024-04-20T11:38:08Zhttps://www.grasshopper3d.com/video/video/listForContributor?screenName=2n76ebq2amuy7&rss=yes&xn_auth=noChen-Gackstatter minimal surface aproximationtag:www.grasshopper3d.com,2013-09-16:2985220:Video:9155172013-09-16T05:51:39.225Zenrique sorianohttps://www.grasshopper3d.com/profile/enriquesoriano
<a href="https://www.grasshopper3d.com/video/chen-gackstatter-minimal-surface-aproximation"><br />
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</a> <br></br>Minimal surface aproximation by mesh topology reconstruction and relaxation.<br></br>
In order to prove the stability of the system, the elastic tension of the fabric is coupled with the counteracting action of the bending resistance of the flexible and elastic perimeter. After fine tuning, we can easily find an equilibrium beetween membrane stretching and perimeter…
<a href="https://www.grasshopper3d.com/video/chen-gackstatter-minimal-surface-aproximation"><br />
<img src="https://storage.ning.com/topology/rest/1.0/file/get/2778175677?profile=original&width=240&height=180" width="240" height="180" alt="Thumbnail" /><br />
</a><br />Minimal surface aproximation by mesh topology reconstruction and relaxation.<br />
In order to prove the stability of the system, the elastic tension of the fabric is coupled with the counteracting action of the bending resistance of the flexible and elastic perimeter. After fine tuning, we can easily find an equilibrium beetween membrane stretching and perimeter bending.<br />
Final stage include a dual mesh conversion and further relaxation in order to build it, passing from a triangular mesh (valence 6) to a more feasible hex-dominant mesh (valence 3).<br />
<br />
This project was part of the first collective exercise in AP13 undergraduate course at Valles Architecture School, BarcelonaTech. The surface discretization was proudly assembled by students and simply fabricated with spring chord and tirewraps.<br />
<a href="http://www.flickr.com/photos/51678540@N07/sets/72157633254946719/">http://www.flickr.com/photos/51678540@N07/sets/72157633254946719/</a><br />
Digitally built with Rhinoceros Grasshopper and simulated with Kangaroo from Daniel Piker. Oloid developabletag:www.grasshopper3d.com,2012-12-16:2985220:Video:7486032012-12-16T11:24:56.954Zenrique sorianohttps://www.grasshopper3d.com/profile/enriquesoriano
<a href="https://www.grasshopper3d.com/video/oloid-developable"><br />
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</a><br />Developable surface modelling. First parametrically, then by dymanic simulation.<br />
Done with kangaroo
<a href="https://www.grasshopper3d.com/video/oloid-developable"><br />
<img src="https://storage.ning.com/topology/rest/1.0/file/get/2778168643?profile=original&width=240&height=135" width="240" height="135" alt="Thumbnail" /><br />
</a><br />Developable surface modelling. First parametrically, then by dymanic simulation.<br />
Done with kangaroo Topology driven shapetag:www.grasshopper3d.com,2012-09-10:2985220:Video:6807522012-09-10T20:36:22.428Zenrique sorianohttps://www.grasshopper3d.com/profile/enriquesoriano
<a href="https://www.grasshopper3d.com/video/topology-driven-shape"><br />
<img src="https://storage.ning.com/topology/rest/1.0/file/get/2778166695?profile=original&width=240&height=180" width="240" height="180" alt="Thumbnail" /><br />
</a><br />effect of elliptic and hyperbolic points in elastic shells<br />
Based on work from Mathias Gmachl (Loop.ph), Alison Grace Martin, and Daniel Piker.<br />
Simulated with Kangaroo from Daniel Piker
<a href="https://www.grasshopper3d.com/video/topology-driven-shape"><br />
<img src="https://storage.ning.com/topology/rest/1.0/file/get/2778166695?profile=original&width=240&height=180" width="240" height="180" alt="Thumbnail" /><br />
</a><br />effect of elliptic and hyperbolic points in elastic shells<br />
Based on work from Mathias Gmachl (Loop.ph), Alison Grace Martin, and Daniel Piker.<br />
Simulated with Kangaroo from Daniel Piker