A fluid connection between Grasshopper and Revit seems to be within reach, and several computational designers in the parametric modeling community have offered powerful plugins to streamline this workflow. This post focuses on the pros and cons of usingÂ adaptive componentsÂ to import Grasshopper geometry into Revit.
ChameleonÂ appeared a few months ago and has proven to be an effective tool for adaptive components. The interface is intuitive on both the GH and Revit sides and we are yet to find any serious bugs with it. Another recent plugin is namedÂ HummingbirdÂ (keep track of all these animals), a similar program which accesses the WhiteFeet Modeler to import adaptive components as well as Revit primitives (this has a lot of potential and will be discussed more in a future post). Take your pick, these are both great plugins.
The test case we are using is a preliminary curtain wall design for a project in our office. This expansive curtain wall plays a crucial role in how the building is perceived and experienced; and while itâ€™s designed to minimize the formal â€˜sculptingâ€™ of the glazing, it has an irregular form due to the building geometry and program requirements. Warped surfaces create a fish-scale pattern which delaminates from a more typical curtain wall. While the early design concepts were studied in Grasshopper, we wanted the file in Revit to provide for material takeoffs and documentation. Dumb geometry wonâ€™t cut it here. We recently completed Design Development and are moving right along into CDs, where Revit/GH coordination becomes increasingly crucial. Chameleon/Hummingbird allow for a smooth transition without losing the intelligence of the model.
The wallâ€™s complexity is defined by its grid and panel edges. Weâ€™re setting this up in grasshopper and then utilizing Revitâ€™s adaptive component to provide detail. The Grasshopper definition remains flexible while the Revit file provides the added documentation and geometry. This is an exciting step towards having the programs complement each other, and one which helps us better understand the complexity and feasibility of our designs.
A perspective view of the design concept
But letâ€™s not get carried away, sometimes the two programs just donâ€™t want to get along. There will inevitably be issues with the first few attempts at importing adaptive components, but these can all be fixed with a better understanding of each programâ€™s data sets and modeling methods. Keeping a proper point order in grasshopper is essential to having the adaptive component construct correctly. Also, adaptive components get even trickier when thickness is added to a family (now youâ€™re dealing with extrusion directions and work planes). Hereâ€™s a quick walk through of steps we used to get the desired results:
First, we put together our curtain panel adaptive component family. This is a double skinned wall and is generated by 4 vertices. The parameters of frame profile, glazing thickness, etc. are all controlled within Revit while panel vertices are controlled within Grasshopper.
Here we are in Rhino, where we have four panels of the curtain wall. Constructed on a curved surface, 3 vertices of each panel are creating a plane while the fourth vertex is projected onto that plane, creating the fish scaling effect.
Using the brep explode battery in Grasshopper, weâ€™ll select specifically the bounding surface on the outside of the wall.
Now that we have this surface, using Grasshopperâ€™s sort along curve component (new to GH .9), we can sort the panel vertices along the bounding box surface. Turning on the point display shows us that we have the vertex order weâ€™re looking for.
By toggling the Chameleon component and connecting to Revit, we have the panels imported. All done!
After getting all of our geometry into Revit, we created a sheet of diagrams for the curtain wall in order to better understand the geometry for detailing. Weâ€™ve set up a scope box to create a drawing at the major intersections of the wall, and if our Grasshopper geometry changes, we just do another import and the sheets will update accordingly.
This process is working great from Grasshopper to Revit, but the reverse could use improvement. To update adaptive component points, weâ€™re deleting the old adaptive families and importing new ones. While Chameleon has a decent Edit Params tool, it would be equally as helpful to see an Edit Vertices tool. That way we could update the same Revit instances without creating new ones. Hummingbird also has potential for updating Revit IDs with WhiteFeet, but the plugin is still under development. Either way, hats off to the developers for putting these tools together. Theyâ€™re really helping to enable our designs.
Here are a few notes which helped us with the process:
The Grasshopper panel here shows that weâ€™re creating a tree branch for each panel and an item for each vertex. The plugins also allow for modifying instance parameters, but we donâ€™t have any instance parameters in this case.
Back to Revit, an important step: since all of the adaptive components are extruding on custom planes, be sure to check that the adaptive componentâ€™s orientation is â€œorthogonal in familyâ€. This will ensure the extrusion direction is normal to its plane.
The columns here are serrated to support he fish-scaled panels. These are constructed as adaptive components with 20 points. Just for proof of concept, the two images above show that the panel family does not need to resemble the final object whatsoever. As long as itâ€™s constructed with the same logic, the adaptive points will shape the geometry while the family editor is strictly used to set up parameters and materials.
via Adaptive Components, GH to Revit | LMNts.