The First 3D-Printed Steel Bridge

The First 3D-Printed Steel Bridge(gizmodo.com)

131 points by odabaxok 8 years ago | 51 comments

jstanley 8 years ago |

I recommend the video, it includes some footage of the printing process: https://www.youtube.com/watch?v=STAHy6hTP14

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).

joshu 8 years ago | |

I knew this was gonna be Tony before I even clicked.

grownseed 8 years ago |

Commenting on this while my 3D printer is making parts for my new 3D printer, with parts I designed from the comfort of my own home. 3D printing and the RepRap movement have managed to get me truly excited about something for the first time since I took up programming 20 something years ago.

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.

mikenew 8 years ago | |

Same experience for me. I bought a cheap printer from eBay and slowly started re-designing and replacing existing parts by printing them out on the printer itself. Nearly 100% of the printer has been replaced, and I’m finalizing the design for a second printer. I’ve started making contributions to the firmware, slicers, and host software to get features I want, learned to model in Blender, learned about programming micro-controllers, started researching thermoplastics, material science, and the list goes on.

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.

mdorazio 8 years ago | | |

I want to offer additional context for other people who read this and may not be familiar with how 3D printers work. The core components of a 3D printer are not currently printable. These components are: power supply, control board, steppers, rails, bearings, belts, hotend, and the bed. When people talk about printing parts for their printer, they are almost always referring to the secondary parts like the carriage assembly, extruder gears, fan shrouds, and frame components that can be made from a large variety of cheap materials (acrylic, MDF, ABS, etc.). We are a very long way from a printer being able to actually replicate itself.

Source: own and operate 50 3D printers

function_seven 8 years ago | | |

Things I learned from RC cars as a kid:

    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

And all sorts of hard-to-list mechanics and know-how.

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?

ChuckMcM 8 years ago | | |

Agreed. One of the reasons I've enjoyed robotics so much is that it presses on all three of mechanics, software, and electronics. Since there is rarely someone who is good enough at all three it gets a huge boost by community involvement by folks with complementary skill sets. The problem with robotics was that once you did the basics, obstacle avoidance, line following, balancing perhaps. You Were sort of stuck on the next thing to work on. But 3D printers are robots that can make more interesting things so they are useful in their own right.

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.

opencl 8 years ago | |

I'm also really excited that SLA prices have absolutely plummeted in the last year or so as well. The level of quality you can get from a ~$500 machine now is stunning, but of course it comes with its own set of problems so it's not going to dethrone FDM anytime soon. I hope we get more open-source SLA development soon though.

eloff 8 years ago |

Just beautiful. The ability of 3D printing, not just to automate a traditional construction process, but to enable radically different designs is going to create a whole new style of architecture. Many of the old constraints don't apply and the human imagination is given a freer reign. There's still that pesky law of gravity that must be respected, but otherwise this offers a remarkable freedom.

wheelie_boy 8 years ago | |

An interesting thing that's happening alongside 3d printing is the emergence of visual programming languages specialized for geometry, the most popular being Grasshopper.

opencl 8 years ago | | |

Is it really the most popular? It's a plugin for a $1000 CAD program which seems to dramatically limit who can use it.

hathawsh 8 years ago | | |

This is the first time I've heard of Grasshopper. Are you referring to this?

http://www.grasshopper3d.com/

How would you recommend a 3D printer operator could learn more about Grasshopper? Are the tutorials good?

delecti 8 years ago | |

I suspect that the time and cost involved in non-trivial structures will limit any real experimentation with non-traditional designs. It might be trivial to throw away a kilogram of plastic on a failed prototype, but the same doesn't extrapolate up to experiments with bridges.

eloff 8 years ago | | |

But that's just the thing, you aren't limited so much by time and cost. The time is proportional to the size of what you're printing, and the cost to the amount of materials and time involved. None of which says much about what the design must look like. You design it on the computer, look at in 3D on the screen as much as you like, and print a scaled model, if you must.

You don't need to print up a full-scale prototype anymore than you would do that with a traditional design and construction technique.

jstanley 8 years ago | | |

I assume the printing of this bridge didn't go smoothly in one pass, but one advantage of larger-scale metal printing is if something goes wrong you can grind off the failure, reposition the print head (extruder? welder???), and try again.

I suppose you could do that with FDM as well, but the precision required for smaller prints is much greater.

matte_black 8 years ago | | |

You could sample the projects in VR to get a feel for them.

opencl 8 years ago |

The article is light on technical details but they apparently converted a normal industrial welding robot into a giant FDM machine that deposits 1-3 KG per hour per nozzle. Really interesting. From the photos it looks like the layers don't even have to be parallel to each other.

skookumchuck 8 years ago |

While an amazing new technique, I'm a bit disappointed that it was used to create an "art" bridge. As an engineer, I'd be more interested in what a bridge would look like if it was pure utilitarian - the only material on it is what must be on it, not what is required by machining costs and stock material shapes.

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.

reneherse 8 years ago | |

Hard to look at the history of aircraft and think aesthetics have nothing to do with the shapes designers choose. Aesthetics may not be the driver, but it's definitely an input in the process, to varying degrees.

skookumchuck 8 years ago | | |

> Hard to look at the history of aircraft and think aesthetics have nothing to do with the shapes designers choose.

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.

jacquesm 8 years ago | |

I actually think that the organic look shows off the fact that it was 3D printed in a very original way. If it ended up being a utilitarian 'boring' construction then there would be no point in 3D printing it in the first place. But there is no other way that I'm aware of short of a huge cast (and that's a big if given the hollow spaces) to make this bridge in any other way.

skookumchuck 8 years ago | | |

> If it ended up being a utilitarian 'boring' construction then there would be no point in 3D printing it in the first place.

There's a great deal of point to it - saving money in material and fabrication costs.

jacquesm 8 years ago |

Wasn't this the first?

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).

pasta 8 years ago |

At first I was a little shocked it took 6 months to print (weld if you like). But thinking about it, it doesn't seem that long for such a complicated design.

Great work!

yetihehe 8 years ago | |

It doesn't matter if it's complicated. Probably they can't do it faster because they have to melt so much steel.

fudged71 8 years ago |

There was a section of this bridge on display at the Autodesk Gallery in San Francisco. Very heavy :)

LifeLiverTransp 8 years ago |

Such beauty, such aery reduction to the basics...

karmicthreat 8 years ago |

What was the new type of steel they used?

jstanley 8 years ago | |

I took that to mean that it is not hot-rolled steel, cold-rolled steel, cast iron, or any other traditional method of converting a lump of iron ore into a usable piece of steel.

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".

karmicthreat 8 years ago | | |

That is a good point though. Since its just mig wire you could change out the wire at various points to change the properties of the steel.