Quote from: docmordrid on 03/20/2015 11:53 pmhttp://www.mmsonline.com/blog/post/metal-additive-manufacturing-for-parts-up-to-7-feet-tallQuote>One of the constraints on additive manufacturing machines that make metal parts from powder has been the relatively small build envelope of these machines. Rapid City, South Dakota-based RPM Innovations is now prepared to challenge that constraint with laser deposition additive manufacturing machines that have a build envelope of 5 ×5 ×7 feet. An 83-inch-tall rocket-like part made from Inconel 625 that was grown in one of this company’s machines will be on display in the Advanced Manufacturing Center at IMTS.>Nearly 80 percent of its applications have been related to aerospace or defense, including aircraft engine components and aircraft structural components for “companies whose names you’d recognize,” he says. Inconel 625, Inconel 718 and titanium 6-4 are among the alloys that the machines apply routinely.The rocket-like part took around 340 hours to build is approximately 7,000 layers, he says. And to the RPM staff, that is not all that long. “We have had big parts—not as tall as this, but broader and a lot more complex—that took us 1,800 hours to build,” Mr. Mudge says.>That's impressive given these are high temperature Nickel based alloys but the one I'm thinking of is another electron beam in a vacuum system outfit.Can't for the life of me think who they are.
http://www.mmsonline.com/blog/post/metal-additive-manufacturing-for-parts-up-to-7-feet-tallQuote>One of the constraints on additive manufacturing machines that make metal parts from powder has been the relatively small build envelope of these machines. Rapid City, South Dakota-based RPM Innovations is now prepared to challenge that constraint with laser deposition additive manufacturing machines that have a build envelope of 5 ×5 ×7 feet. An 83-inch-tall rocket-like part made from Inconel 625 that was grown in one of this company’s machines will be on display in the Advanced Manufacturing Center at IMTS.>Nearly 80 percent of its applications have been related to aerospace or defense, including aircraft engine components and aircraft structural components for “companies whose names you’d recognize,” he says. Inconel 625, Inconel 718 and titanium 6-4 are among the alloys that the machines apply routinely.The rocket-like part took around 340 hours to build is approximately 7,000 layers, he says. And to the RPM staff, that is not all that long. “We have had big parts—not as tall as this, but broader and a lot more complex—that took us 1,800 hours to build,” Mr. Mudge says.>
>One of the constraints on additive manufacturing machines that make metal parts from powder has been the relatively small build envelope of these machines. Rapid City, South Dakota-based RPM Innovations is now prepared to challenge that constraint with laser deposition additive manufacturing machines that have a build envelope of 5 ×5 ×7 feet. An 83-inch-tall rocket-like part made from Inconel 625 that was grown in one of this company’s machines will be on display in the Advanced Manufacturing Center at IMTS.>Nearly 80 percent of its applications have been related to aerospace or defense, including aircraft engine components and aircraft structural components for “companies whose names you’d recognize,” he says. Inconel 625, Inconel 718 and titanium 6-4 are among the alloys that the machines apply routinely.The rocket-like part took around 340 hours to build is approximately 7,000 layers, he says. And to the RPM staff, that is not all that long. “We have had big parts—not as tall as this, but broader and a lot more complex—that took us 1,800 hours to build,” Mr. Mudge says.>
Test program for adoption of Powder Bed Fusion EBM Ti-6Al-4V at Lockheed Martin Space Systems Co.Tuesday, May 12, 2015: 11:00 AMRoom 201A (Long Beach Convention and Entertainment Center)>
does LM use it?
might be some errors in this article, haven't sifted into all the details....Enjoy! Built Almost Entirely of 3D Printed Parts, the World’s First Battery-Powered Rocket is Unveiled"The launch system, which is used to launch small satellites into orbit, features the electric Rutherford engine, which is the first oxygen/hydrocarbon engine to use 3D printing for all of its primary components, including everything from its engine chamber, to its pumps, main propellant valves, and injector."
I wonder how many people realize how radical this concept is. They are saying that the total mass of batteries and motors is less than the total weight of propellant and gas generator.This is a phenomenal claim. I wish them every success but realize this is very bold.
They are saying that the total mass of batteries and motors is less than the total weight of propellant and gas generator.
Must remember that GG propellant mass at the end of the ride is zero while depleted battery weighs the same as full.Some W/kg and Wh/kg figures would be nice to go with that claim.
This Is NASA's First 3D-Printed Full-Scale Copper Rocket Engine Part
Quote from: Prober on 04/22/2015 01:09 pmThis Is NASA's First 3D-Printed Full-Scale Copper Rocket Engine Part I wonder if they will go the whole hog and hot fire it as well?
I got the chance to try "platelet" fabrication technology in 1998-99 when we built this engine, which was LOX cooled, 2400 psia Pc design pressure, 6.6K-lbf. As can be seen from the photos, individual copper foils were assembled in a stack and then diffusion bonded together. It wasn't cheap at the time costing about $80K, but we fired it 40 times and it worked well.
Given my employer, and that I work in a building named after him, this immediately brings to mind the work of Raytheon's Percy L. Spencer, who devised the technique of brazing stamped copper plates together to build a multi-cavity microwave magnetron (patent #2458802), rather than machining it from a solid block of copper, in response to an urgent plea from Great Britain for help with air defense radars during WW-II. Additive manufacturing in 1940, in other words.
According to Raytheon: The First Sixty Years, the company bet the farm on this innovation and went on to dominate the radar market during the war to the tune of 80% share, producing up to an unprecedented 2,600 magnetrons a day.
Called SuperDracos, the engines were made from 3-D printing. It will be the first time that SpaceX fires all eight of them at the same time.
I read something in an article on the upcoming SpaceX manned dragon launch abort system test that the lift vehicle in the test will have 3D printed rocket engines.http://phys.org/news/2015-05-spacex-mile-high-feature-buster-dummy.html