Unlike traditional 3d metal printing, which works by laying down a powder which is then baked in an oven to fully sinter it, this bridge seems to be constructed by directly welding additional metal to the existing structure.
Here's a fun DIY attempt at the same kind of idea: https://www.youtube.com/watch?v=sFXniBbgbw0 (and, if you're into home machining, almost all of the other videos on his channel are very enjoyable too).
We're not quite at the fully consumer-ready stage yet, there is a lot of tinkering and know-how that would be too much for the average consumer. I'd say the current state of 3D printing is at the same level 2D printing was ~40 years ago (comparatively), but I'm confident we'll reach a similar stage within the next few years.
For those interested, the RepRap community is extremely active and there are lots of open-source projects (including hardware) to get involved with.
3D printing is an incredible intersection of software, electronics, machinery, chemistry, and an open, community-driven R&D environment. It is the most fun I’ve had since being a child building RC cars.
Source: own and operate 50 3D printers
1. Basic electricity
2. PWM
3. Battery chemistry and care
4. Transmissions/gear ratios
5. How DC motors work. Winds and turns and brushes, etc.
6. Suspension basics
7. Basic RF (crystals and channels and avoiding interference)
8. Soldering
I didn't realize it at the time (and I don't think my parents did, either), but I learned so much more from that hobby than I did in school, for those areas.
3D printing feels the same way. I only recently got the Monoprice 120mm^2 unit, and it's working great for what I've thrown at it so far.
What are you using for all the non-plastic parts? Do you print slides and bracing as well?
I have started experimenting with printed linear rails, and likely V2 of the printer will have printed rails on the z axis. The bushings are printed nylon that thread directly into the bed, x carriage, etc. I would also like to start experimenting with printed wiring, but most conductive filament is more like resistor wire, so that would take some figuring out.
As far as the frame and all that; yes it’s all printed. You’d be surprised how much the part count starts to fall when you no longer have to attach different parts together and you instead start integrating them into a single, printed part.
My current favorite application is to make holding fixtures for things like breakout boards so that I can fabricate systems out of a bunch of separate boards easily.
How would you recommend a 3D printer operator could learn more about Grasshopper? Are the tutorials good?
EDIT:Yes, it's that grasshopper https://www.rhino3d.com/6/new/grasshopper for a demo reel
You don't need to print up a full-scale prototype anymore than you would do that with a traditional design and construction technique.
I suppose you could do that with FDM as well, but the precision required for smaller prints is much greater.
Before anyone scoffs that this must result in nerdy and ugly shapes, airplanes are beautiful shapes and none of that is for aesthetics or artistic purposes. It's simply the best shape for flying. As manufacturing techniques improve, the airplane shapes get more subtly flowing forms, and get even more beautiful.
In my reading about the history of aircraft, aesthetics have nothing to do with it. Performance and cost are everything.
For example, the elliptical wing of the Spitfire is often mentioned as a big part of the beauty of the design. But the elliptical planform is the most efficient wing design (the Mitsubishi Zero had one, too, for the same reason). Giving your pilots every edge possible is everything in those designs. And yet look at the beauty that resulted.
The downside of the Spitfire shape was it took twice as many hours to produce as the Me-109, which was designed to be easy to manufacture.
I can't think of a single successful airplane design that was designed to be beautiful - from the Wright Flyer to the Sopwith Camel to the Spitfire to the DC-3 to the Concorde to the Blackbird. Not one. Yet they're all beauties.
Art makes us think about what could be - and imagine a future of solutions that are utilitarian in new ways, or address needs we didn't know we had.
There is beauty in engineering. There is also beauty in pure imagination.
There's a great deal of point to it - saving money in material and fabrication costs.
This is a technology demonstration, not an example of super high efficiency. It also took much longer to make than it would have taken to make it in a more traditional way.
That said it still came in rather competitive compared to the alternatives, which says quite a bit about how manufacturers of such structures normally charge.
https://www.tudelft.nl/en/2015/io/the-first-3d-printed-bridg...
Ah, it is the same project only a bit delayed and they've redesigned the bridge itself and moved the project indoors during the printing phase (which makes good sense).
Great work!
It's 1000 km of welding wire welded together. It counts as a new "type" of steel depending on how flexible you are with what counts as different "types".