It occurs to me that we seem to keep thinking about an inkjet type of 3d printing.Another approach would be more of an extrusion method where a wire or bar of metal is heated in a vacuum to a nearly moltant level, then extruded onto a platform, (which is also used to start the cooling process) in a continiously layered pattern, building up the particular part that one is trying to print. Using a nearly moltant metal, extruded like toothpaste in a vacuum allows the metal to not only adhear to itself, but to also do so without contamination. As this is not being reduced to a vapor, or being used in a sintering technique, the energy costs should be far lower than most other 3d metal printing techniques.
Quote from: JasonAW3 on 06/18/2014 12:28 pmIt occurs to me that we seem to keep thinking about an inkjet type of 3d printing.Another approach would be more of an extrusion method where a wire or bar of metal is heated in a vacuum to a nearly moltant level, then extruded onto a platform, (which is also used to start the cooling process) in a continiously layered pattern, building up the particular part that one is trying to print. Using a nearly moltant metal, extruded like toothpaste in a vacuum allows the metal to not only adhear to itself, but to also do so without contamination. As this is not being reduced to a vapor, or being used in a sintering technique, the energy costs should be fa6r lower than most other 3d metal printing techniques.Heat transfer would be the critical issue. The cold plate would need some serious cooling loop. And the speed would be constrained by the cooling of the metal. And you'd need a very efficient airlock. Each vacuum cycling is pretty expensive, as I understand it. Both in actual gas and wear and tear.
It occurs to me that we seem to keep thinking about an inkjet type of 3d printing.Another approach would be more of an extrusion method where a wire or bar of metal is heated in a vacuum to a nearly moltant level, then extruded onto a platform, (which is also used to start the cooling process) in a continiously layered pattern, building up the particular part that one is trying to print. Using a nearly moltant metal, extruded like toothpaste in a vacuum allows the metal to not only adhear to itself, but to also do so without contamination. As this is not being reduced to a vapor, or being used in a sintering technique, the energy costs should be fa6r lower than most other 3d metal printing techniques.
Interesting. Microgravity has the advantage on making cantilever features. But at the same time, on direct deposition methods, you sort of depend on gravity to keep it smoothly over a layer. And un even PLA surface is no problem to a 140C hot metallic print head. But metal to ceramics is a different matter. If you didn't left a smooth surface, once you try the next pass your head might interfere with excess material. And it's very difficult to assure flow will make a practically continuous surface.Then you have the thermal issues. Air does carry heat away. Once in vacuum your only cooling methods are radiation, which is excruciatingly slow, or implementing a cold plate into the printer bed. In which case your cooling is a gradient in the z axis. What are the consequences for material deposition? I'm pretty sure a lot of thought will have to go into the G-Code regarding metal cooling, smoothing and plasticity.
You're forgetting to account for thermal expansion. Once you cool it contracts and stops being "stick" to the cool plate. And the contraction might curve the piece, separating the center of the plate, for example.
Nanfang Ventilator Co. of China has one that can print a diameter of 2.1 x 6.0 meters up to a mass of 300 tonnes. Mainly steels, including stainless, but it seems size is becoming less of a factor almost weekly.
For instance, it will never compete in mass-production in the same way as traditional manufacturing. The per-part build time is several orders of magnitude greater.
Quote from: Robotbeat on 06/19/2014 12:54 amFor instance, it will never compete in mass-production in the same way as traditional manufacturing. The per-part build time is several orders of magnitude greater.While I mostly agree with your post, in science and technology, never is a very very long time.
It's important to understand that Robobeat has correctly stated about single piece output per machine. Scalability, that's a whole different issue. Would 10,000 3D printers cost (acquisition and operation) than a big traditional factory? Today most certainly, in the future, probably on a case by cases basis.
Living things are basically self replicators as you describe, but 9 women can't make a baby in 1 month.
Quote from: Robotbeat on 06/19/2014 01:03 pmLiving things are basically self replicators as you describe, but 9 women can't make a baby in 1 month. Yes but a printer with 9 printheads may make a baby in 1 month instead of nine, depending on the geometry of the baby.Say the baby has the shape of a rocket nozzle. 9 printheads can work at the diameter of the nozzle for most of the time until towards the top the available space cannot accomodate that number of printheads.