priety software). Think Kangaroo with RON 100 fuel (add some nitrous oxide).
Back to domes.
1. Obviously you know the free WinDome Bono thing...but anyway get it (code included).
2. As I said on another thread (http://www.grasshopper3d.com/forum/topics/the-necessity-for-a-data-tree-manager) ... the big thing in AEC (because, for instance, nobody does domes for decoration/artistic stuff etc etc) is how to implement already designed things (see images above) within a smart stuff definition (or many).
3. Goes several steps beyond: these "breps" (to speak GH/Rhino language) are in most cases nested and some parts are "locked" for transformations some other not. That's the big thing when trying to outline real-life AEC solutions in the so called Smart applications. I think that this is not doable in Rhino since there's no way to edit (in place) a nested block.
4. Goes even further: for each custom made thing (truss nodes and the likes) ... there's a bill waiting. Meaning that the less customized a solution is (with regard industrial sourced existed parts) the more is possible for the client to sign the dotted line.
Best, Peter…
ple and/or easy.
I use GH/Rhino (really GH almost exclusively) for design. I find the parametric capabilities of GH simply spectacular. The Autocad apps are all quite good (and free) so I would have no problem recommending any of them. Meshmixer is a common starter for people new to 3D printing; it is targeted at more "free form"/artistic designs that is Tinkercad, which is more oriented for geometric/engineering/architectural designs. Sketchup is also a good place to start with 3D design; it used to be owned by Google but is now owned by a 3rd party company.
For slicers I've tried them all and have settled on Craftware. It's free and available at https://www.craftunique.com/craftware. For backup to that (it is still a beta product) I use Simplify3D (very seldom) but it costs $150.
If anyone cares I have uploaded an updated version of the Stepwell GH file; I tweaked it a bit to make it a little simpler and to make the base thicker so it would be more robust when printed. The dimensions of the part are large so it has to be scaled down to fit a particular printer. This is easily done with any slicer. The STL file from Rhino still has to be fixed; as exported it would print with no bottom - and I haven't figured out why that happens.…
Added by Birk Binnard at 12:36pm on February 14, 2016
subsequently able to retain a higher level of flexibility.
In Rhino however a rectangle is defined as only a plane and two numeric intervals (one for x, one for y). The possible solutions to this would be:
Extend the Rhino SDK Rectangle3d type to include constant radius fillet corners. This can be done, but is a lot of work and will break the SDK.
Create a new type in Grasshopper which is smarter than Rectangle3d. This complicates developing for Grasshopper because now you have to keep two different types in mind whereas before only one was needed.
Remove the Fillet Radius input from Rectangle components. I like this solution because it results in cleaner, simpler code, but it does mean people may need to use two components where before one was sufficient.
Make the Rectangle type smart enough so that it can recognise filleted rectangles and undo the filleting. This is something I can do right now for Grasshopper 1.0 and it in all likelihood would not break actual existing files even though it is technically a behavioural change.
I'll try and get (4) done for Rhino 6 SR1, I might decide to do (3) for Grasshopper 2.0. I sincerely doubt that (1) will ever get done and I dislike (2).…
Added by David Rutten at 4:38am on November 6, 2017
points (which increases the smoothness of the medial axis, and hence the accuracy of the output mesh), spikes appear in the voronoi diagram as shown below.
For reference the point spacing along the input curve is 0.2mm, and the extension of the overlapping cells is about 8mm
I have compared this result with the only other Voronoi implementation i could find in GH which is from SmartForm. SmartForm SMART Voronoi does not produce this error, however it is exponentially slower, taking approx 11 minutes compared to 2.5 seconds for the native component.
Is this a known problem with the accuracy of the GH Voronoi implementation? I have tried this with various Units settings in the RhinoDoc, with no change.
Any ideas?
Are there any other fast + accurate Voronoi implementations out there?
example file is attached. Note that it requires SmartForm, but will show the error without it.
Thanks :)…
ts (other than Kangaroo - if required). Anyway notify if you want some taste of them (but they are a bit "chaotic" : too many parameters etc etc ...). Warning: Almost all are written with MCAD apps in mind: GH is used SOLELY as a graphical editor/topology solver and just makes the simplest instance definitions possible in order to send them (via STEP) to some MCAD (Frank G uses CATIA/Digital Project as you may probably know, CATIA is my favorite toy as well) for actually designing the components and composing the whole.
2. "Equality" in modules (panels/glass/lexan) it's not an issue (other than aesthetics). I mean cost wise since modules are prepared via CNC these days. I wouldn't suggest to waste your time with "equality" puzzles and completely ignoring the big picture (real-life) that is FAR and AWAY from aesthetics. I mean: assume that I of someone else or Daniel can "equalize" things (up to a point): Is this sufficient for designing a similar real-life solution? In plain English: don't get occupied by the tree and ignore the forest.
3. As regards the frame in most of cases some MERO type of modular system is used: either a "flat" dome-like arrangement or a classic spaceframe or a hybrid system [push: tubes, pull: cables]. Hybrids are the most WOW (and costly) for obvious reasons. When properly done (and combined with a planar glazing system) THIS is the star of the show.
4. As regards the skin we use either "hinged" custom stuctural/semi structural aluminum extrusions (they can adapt to different dihedrals up to a point) or classic custom planar SS16L systems that also can adapt to dihedrals. A custom planar glazing solution is hideously expensive, mind (say: 1K Euros per m2).
5. Smart Glass tech (changes light transmission properties under the application of voltage) is gradually penetrating the market especially in future bespoke designs.
So in a nutshell: these are "pro" territory - if I may use the term, thus I don't expect to find ANY similar "turn-key" solution in the very same sense that you can't find a tensile membrane turn-key solution.
Meaning that practices that can do it ... er ... they keep the cookies for themselves. …
le] demo):
1. A transformation Matrix is a 4*4 collection of 16 values that "deform" 3d things according the values in the cells. The orthodox way is to deploy "cells" left to right and top to bottom. Rhino does the opposite (why?) hence we need the transpose method.
2. Since "translate" and "perspective" are "symmetrical" the transpose boolean toggle (within the C#) "flips" rows with columns ... so we get perspective or move.
3. When in perspective "mode" the vanishing points are computed internally within a min/max limit (per X/Y/Z axis) thus avoiding the usual havoc with "extreme" perspective angles (very common "glitz" in pretty much every CAD app - CATIA excluded). Vanishing points (and limits) are oriented with respect the pos/neg value of a given control slider.
Note: slider values are percentages between min/max (mode: perspective) and/or actual values*100 (mode: move).
4.In order to start mastering the whole thing: don't change anything: just play with these 4 sliders selected:
5. The 123 sardine cans challenge: even with DeusExMachine = true (see inside C#: that one redirects the transformation per BrepFace and then joins the breps instead of applying it on a brep basis)... odd things (and/or invalid breps) occur ... thus what is required in order to make things working 100% ??.
he, he
best, Lord of Darkness …
next level.
This Parametric Design course will provide the participants with the necessary knowledge and ability to use Grasshopper, a free visual programming plugin in Rhinoceros; you will be guided through a series of hands-on exercises that highlight NURBS modeling and its concepts. We will introduce Grasshopper as a graphical algorithm editor tightly integrated with Rhino’s 3D modeling tools. You will also learn how Rhino is used to render models for visualization, translate 3D models for prototyping, and export 3D models into 2D CAD or graphics programs.
English is the course main language.
Location: Düsseldorf city center
Registration and buying Tickets
www.digitalparametrics.eventbrite.de
Course Calendar:
4 Days 6 hours each
Total duration 24h
2 weekends
Date:
Sat. 17 - Sun. 18 June
Sat. 24 - Sun. 25 June
10:00 - 17:00
Getting Started in Rhino. 2 days (17 - 18 June)
Getting Started in Grasshopper. 2 days (24 - 25 June)
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Participants will be given a certificate of participation at the end of the course.
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Course fees:
Professionals: 600€ (excl. MwSt.) Students: 500€ (excl. MwSt.) Students need to provide: Copy of current student ID or proof of student enrollment at University/School.
Group discounts:
Group of 3 professionals: 3x500 = 1500€ (excl. MwSt.)
Group of 3 Students: 3x400 = 1200€ (excl. MwSt.)
Participants are kindly asked to bring their own laptops and have pre-installed Rhino + Grasshopper.
Useful Resources:
Rhinoceros Installation (90 days full version trial available): http://www.rhino3d.com/download
Rhinoceros for Mac (includes Grasshopper) http://www.rhino3d.com/download/rhino-for-mac/5/wip
Grasshopper Free Installation: http://www.grasshopper3d.com/page/download-1
Grasshopper Free Plugins: http://www.food4rhino.com/app/lunchbox http://www.giuliopiacentino.com/weaverbird
Main Tutor:
Rihan
M.A. Dipl.Ing. Architect
Architect at RKW Architektur + Düsseldorf
For any questions about the course, please email: info@immersive-studio.com…
logic in the script body. Now it works OK. Feeding all the right data required to Kangaroo is entirely trivial.
Happens now : create some "filters" about if a given cone is a classic one (suspended from a triad of high points == make triads of cables etc etc) or an inverted one (pulled from the ground == do something about that, anyway). This means find some interactive way to alter the cones data tree on a per branch basis (a slider access branches > the offset is altered > cone "type" > ...).
Just checked the P thing : it's all clear now (DeBrep).
That said I work in a smoke build on some MCAD app that does the following : when you hoover over a tool ... the underlying method is exposed and ... you can find what is where in nanoseconds.
Anders: I've looked at the Brep.Trim before posting this ... but .. well I can't get the gist of it (anyway the split loop did the job).
... If the Cutter is closed, then a connected component of the Brep that does not intersect the cutter is kept if and only if it is contained in the inside of cutter....
…