2024-04-19T12:39:14Z https://www.grasshopper3d.com/video/video/listTagged?tag=triangulation&rss=yes&xn_auth=no tag:www.grasshopper3d.com,2023-09-02:2985220:Video:2299815 2023-09-02T01:40:14.238Z kgm https://www.grasshopper3d.com/profile/kgm

<a href="https://www.grasshopper3d.com/video/computational-design-on-ipad-browser-beegraphy-delaunay-mesh"><br /> <img src="https://storage.ning.com/topology/rest/1.0/file/get/12215436287?profile=original&amp;width=240&amp;height=180" width="240" height="180" alt="Thumbnail" /><br /> </a><br />Computational Design on iPad - BeeGraphy beta<br /> example: Random 3D Delaunay Mesh

<a href="https://www.grasshopper3d.com/video/computational-design-on-ipad-browser-beegraphy-delaunay-mesh"><br /> <img src="https://storage.ning.com/topology/rest/1.0/file/get/12215436287?profile=original&amp;width=240&amp;height=180" width="240" height="180" alt="Thumbnail" /><br /> </a><br />Computational Design on iPad - BeeGraphy beta<br /> example: Random 3D Delaunay Mesh tag:www.grasshopper3d.com,2013-09-27:2985220:Video:921569 2013-09-27T05:54:27.839Z Benjamin Felbrich https://www.grasshopper3d.com/profile/BenjaminFelbrich

<a href="https://www.grasshopper3d.com/video/standardized-surface-triangulation-1-2"><br /> <img alt="Thumbnail" height="135" src="https://storage.ning.com/topology/rest/1.0/file/get/2778176043?profile=original&amp;width=240&amp;height=135" width="240"></img><br /> </a> <br></br>This video shows how to subdivide an arbitrarily shaped curved surface into triangular panels of standardized size.<br></br> More descriptions are given in the video.<br></br> <br></br> The exercise can become useful in massively reducing cost in the production of construction elements for large architectural designs in curved shapes.…<br></br> <br></br>

<a href="https://www.grasshopper3d.com/video/standardized-surface-triangulation-1-2"><br /> <img src="https://storage.ning.com/topology/rest/1.0/file/get/2778176043?profile=original&amp;width=240&amp;height=135" width="240" height="135" alt="Thumbnail" /><br /> </a><br />This video shows how to subdivide an arbitrarily shaped curved surface into triangular panels of standardized size.<br /> More descriptions are given in the video.<br /> <br /> The exercise can become useful in massively reducing cost in the production of construction elements for large architectural designs in curved shapes.<br /> <br /> <br /> felbrich.com tag:www.grasshopper3d.com,2013-09-09:2985220:Video:911365 2013-09-09T08:32:59.149Z Benjamin Felbrich https://www.grasshopper3d.com/profile/BenjaminFelbrich

<a href="https://www.grasshopper3d.com/video/light-weight-roof-surface-triangulation-part-2-3"><br /> <img alt="Thumbnail" height="135" src="https://storage.ning.com/topology/rest/1.0/file/get/2778175645?profile=original&amp;width=240&amp;height=135" width="240"></img><br /> </a> <br></br>turning the previously generated large surface in smaller subsurfaces.<br></br> <br></br> some conditions:<br></br> -each subsurface (the "curved pizza slices") itself should consist of randomly arranged triangular panels<br></br> these panels are supported by a grid of thin steel beams, which themselves rest on larger curved steel pipes (the catenary dome ribs as seen in…

<a href="https://www.grasshopper3d.com/video/light-weight-roof-surface-triangulation-part-2-3"><br /> <img src="https://storage.ning.com/topology/rest/1.0/file/get/2778175645?profile=original&amp;width=240&amp;height=135" width="240" height="135" alt="Thumbnail" /><br /> </a><br />turning the previously generated large surface in smaller subsurfaces.<br /> <br /> some conditions:<br /> -each subsurface (the "curved pizza slices") itself should consist of randomly arranged triangular panels<br /> these panels are supported by a grid of thin steel beams, which themselves rest on larger curved steel pipes (the catenary dome ribs as seen in part 1/2)<br /> - no duplicate ridge pipes<br /> - no duplicate nodes<br /> <br /> the script is executed roundwise (step-by-step) using hoopsnake, to ensure system stability (heavy computation)