Showing posts with label metal 3d printing. Show all posts
Showing posts with label metal 3d printing. Show all posts

3D Printed Small Internal Combustion Engine from Romania

Researchers from Romania 3d printed a small working two-stroke engine on a professional metal 3d printer.

Project description:
Romanian Valentin Stamate, a researcher at the Transilvania University in Brasov, presented a 3D printed two-stroke airplane engine prototype. It cost some EUR 20,000 to manufacture and the expense was undertaken by the Brasov University.
The engine is a 10 cubic centimeters one, with 10,000 rotations per minute. Most of the engine parts were produced by SLM and SLS-type 3D printers out of steel, aluminum, and steel and bronze powders. The only parts that were not 3D printed were the propeller, which is made of wood, the cone and its fastening system, the supporting bearings, the screws, the nuts and the spark. The engine is fueled by a mix of methanol and oil.

Now, I know what you are thinking: interesting project but 20 thousand euro is a lot of money for a small engine. Any you are right.
The first thing that came to my mind was my lawn mover broke a few days ago, and since I live in Croatia the replacement part was hard to find and too expensive for my taste. There are MANY small engines in the world and with right investment and economics of scale, this is a very large market. Just the replacement part market is huge with thousands of different engine models with hundreds of parts each.

THIS WORLD NEEDS CHEAPER and OPEN SOURCED 3D PRINTABLE SMALL ENGINES!!!
Now go and make it happen.






















Source:

https://www.romania-insider.com/romanian-researcher-presents-3d-printed-plane-engine-prototype/

Desktop Metal 3D Printing with Microwave Enhanced Sintering

Here is another revolutionary step forward in 3D printing: the desktop metal 3d printer. It deposits metal "paste" made from metal powder with a polymer binder in a similar way as any common FDM machine and the parts are then sintered in a microwave enhanced furnace chamber.
The price is comparable to higher-end professional FDM machine from a few years ago. They also sell production cell that has much higher capacity for more demanding production facilities.


Tech specs:

  •  Build volume: 12 in x 8 in x 8 in (305 mm x 205 mm x 205 mm)
  •  Materials:  Steel, Titanium, Aluminum, Copper and other undisclosed materials
  •  Layer height: 50 μm (minimum)
  •  Dimensions: 60 in x 49 in x 30 in (1500 mm x 1250 mm x 750 mm)
  •  Technology: Microwave Enhanced Sintering
  •  Price: $120,000 for the desktop version, $250,000+ for manufacturing cell production system


Desktop Metal presentation video:




Here is a much more in-depth video by GoEngineer with many details about the machines, materials, and the process:




Company homepage:

https://www.desktopmetal.com/



Cytosurge FluidFM µ3Dprinter is world’s first sub-micron metal 3D printer

Cytosurge AG, based in Zurich Switzerland, presents their revolutionary FluidFM µ3Dprinter which is world’s first 3D sub-micron direct metal printing machine.
This 3D printer could be used as an advanced tool for development of many new scientific and engineering applications from biology to nanorobotics.
It is one of the first steps towards practical manufacturing of parts for nanobots floating in your body to repair the damaged cells.







From the video description:
At the forefront of nanotechnology, additive manufacturing, life sciences and single cell biology, Cytosurge FluidFM µ3Dprinter is the world’s first 3D printer capable of delivering sub-micron resolution in direct metal printing, while offering scalability and good prospects in both production cost and speed.
The FluidFM technology opens a new world for metal object manufacturing and enables research opportunities in fields such as microelectronics, semiconductors, surface modification, microbots, sensors, material science and many other fields. Virtually any design can be offered to the system, including overhanging structures with 90 degree angles, without support structures or post processing steps.
High-precision surface modification processes can also be executed by printing ultra-thin or structured objects and by depositing multiple metals at the target surface. With the FluidFM µ3Dprinter various metals like Cu, Ag, Au, Pt can be printed.
The printing of other metals (Sn, Cd, Cr, Ni etc.) and various alloys are under investigation.


Company homepage:

https://www.cytosurge.com/page/micro3dprinting



New 3D Printed Airplane Seats Could Make Huge Savings

Autodesk researcher Andreas Bastian used advanced generative design to make a new type of lightweight airplane seat that could make huge savings on fuel and money if applied in future aircraft.
Due to complex geometry, the seat was made on Cronus 3D printer with 5 printheads and then cast in metal.

Project description:
The structure was 56% lighter than the conventional aluminum seats. With 30% calculated to be purely down to the generative design.
Autodesk believes these weight savings could rapidly reduce fuel emissions and thus drastically save costs. Calculating the projected cost savings, the team evaluated the weight savings into fuel savings.
By doing so, the project cites an estimate of $200 million USD in possible reductions over the lifetime of a fleet of 100 aircraft. Additionally, the team calculates fuel emission savings that could compare to removing 80,000 cars off the road for a year.




























Source:

https://3dprintingindustry.com/news/autodesk-believes-3d-printed-airplane-seat-save-airlines-millions-dollars-113082/

Laser-assisted Advanced 3D Printing with Silver Ink

Researchers at Harvard’s Wyss Institute for Biologically Inspired Engineering and the John A. Paulson School of Engineering and Applied Sciences (SEAS) developed a new 3D printing method.

They use a miniature nozzle to spray silver ink that is solidified by lasers in midair to produce self-supporting 3D structures.

The application of this technology will probably be in advanced electronics circuits production or biomedical devices.




























Here is the video of the process:



Source and more information:

http://www.pnas.org/content/suppl/2016/05/11/1525131113.DCSupplemental

http://www.pnas.org/content/113/22/6137.abstract

http://www.pnas.org/content/suppl/2016/05/11/1525131113.DCSupplemental/pnas.201525131SI.pdf

Arc Bicycle 3D Printed with MX3D Robotic Arm

Arc Bicycle is made from a metal lattice frame 3D printed with MX3D robotic arm. It looks very cool, both futuristic and organic.





Project description:
A student team from TU Delft in the Netherlands designed and produced a fully functional 3D printed stainless steel bicycle. The students achieved the goal of their three-month project by printing the frame of the with the help of MX3D in Amsterdam. The Arc Bicycle is the first ever 3D printed metal bicycle to be produced using a welding process. For information please contact:

Project Coordinator: J.C.Verlinden@tudelft.nl

Student Team: arcbicycle@gmail.com

MX3D: press@mx3d.com

Here you can see a close-up of frame being 3d printed with metal welding 3d print head attached to industrial grade robotic arm:


3D Systems ProX DMP 320 Metal 3D Printer

3D Systems released a new industrial metal laser sintering printer: the ProX DMP 320. What is the price? Well, if you have to ask, you probably can not afford it :-)


Here are the presentation videos:







Product homepage:

http://www.3dsystems.com/3d-printers/production/prox-dmp-320

Produce PDF brochre with detailed tech specs:

http://www.3dsystems.com/sites/www.3dsystems.com/files/dmp_lineup_trifold_web_0.pdf




Planetary Resources 3D prints with real asteroid sourced metal

Planetary Resources is one of the companies who want to mine asteroids for metals and work in the asteroid belt. They will need to work with materials they find there to produce machinery and structures in space.

To develop this technology they have partnered up with 3D Systems to produce a 3d printed metal part with materials for an actual asteroid that hit the Earth. The asteroid (or meteorite) used for the print materials was sourced from the Campo Del Cielo impact near Argentina, and is composed of iron, nickel and cobalt. The machine used to print it was the new 3d Systems ProX DMP 320.

As you can see the object has complex geometry and is simillar to support structures used in satellites.

























Here is a detailed video about manufacturing in space and asteroid mining technology:





You can watch an interview with Chris Lewicki, president and CEO of Planetary Resources here:

http://www.engadget.com/video/519396020/

... and more detailed Engadget post:

http://www.engadget.com/2016/01/07/planetary-resources-meteorite-print-3D-systems/


If you want to learn more about the company check out their cool mission video:





Company homepage on the project:

http://www.planetaryresources.com/2016/01/planetary-resources-and-3d-systems-reveal-first-ever-3d-printed-object-from-asteroid-metals/

Laser Based Direct Metal Deposition by RCAM


Boys and girls at RCAM gave us this wonderful amalgam of advanced laser metal 3d printing paired with high-end robotics. Laser, robots and 3d printing. Yep, it doesn't get much cooler than that.








Learn more at:

http://www.smu.edu/Lyle/Centers/RCAM




Source:

https://thestack.com/world/2015/09/07/new-3d-metal-printing-technique-combines-lasers-and-advanced-robotics/


Cosine AM1 industrial FDM 3d printer

Cosine AM 1 is powerful new 3d printer that is at home in industrial and professional production setting. It has large format, speed and ability to 3d print with many advanced materials including carbon fiber and metal powders.

Here are the technical specifications of their AM1 machine:
  • Build Volume:  1100mm * 850mm * 900mm
  • Accuracy:  .07mm per 200mm
  • Layer Resolution:  .1mm-1mm
  • Max Extruder Temperature:  450°C
  • Max Bed Temperature:  250°C
  • Max Chamber Temperature:  85°C
  • Nozzle Sizes:  .5mm, 1mm, 1.5mm
  • Max Flow Rate:  3.5 kg / 24hrs
  • Machine Weight:  700kg
  • Machine Size:  1650mm * 1400mm * 1600mm
  • Voltage:  100v-220v 50hz/60hz 3KVA
It can print with wide spectrum of materials:


NormalAdvancedAdditives
 PLA Polycarbonate Carbon Fiber, chopped
 ABS Nylon Carbon Fiber, continuous
 HIPS PBT Carbon Black, ESD
 PVA Acetal Glass Fiber
 PETG Stainless Steel Powder
 Bronze Powder
 Mica
 Glass spheres


Here you can see AM1 printing:




And here is AM1 printing in carbon fiber and polycarbonate:




Cosine Additive company page:

http://www.cosineadditive.com/






Orbit1 desktop metal plating machine for your 3d printed parts

Orbit1 is desktop metal plating machine that will easyli cover your 3d printed objects with metallic layer.

They are on Kickstarter now, early bird for full kit starts at 1999 USD:




Interview by Make:




Here is a demonstration with 2 hour time lapse:




Go to their KS campaign page to get more information or fund it:

https://www.kickstarter.com/projects/1499748748/orbit1-a-tabletop-electroplater-turns-your-ideas-i/video_share

Company page:

http://www.orbit1.co/

Orbit 1 has a nice design 

Examples of 3d printed objects plated with metal on Orbit 1



GE has 3D printed a working small jet engine

New advancement from GE where they managed to 3D print fully functional small metal jet engine. It runs up to 33,000 RPM. Soon someone will make open source version of it. That would have some interesting implications.

Here is a video about it:



Read more about it at:

http://www.gereports.com/post/118394013625/these-engineers-3d-printed-a-mini-jet-engine-then


Laser sintered jet engine parts

Space Race with 3D Printed Rocket Engines Continues

Race for space is getting more heated and 3d printed parts are becoming present in every major project from rocket engines to 3d printed satellites. Everyone is competing: big government agencies, private companies, student groups and private citizens. We have even seen 3d printed open source liquid fuel rocket engine.
3D printed rocket engines can be very fast in production and affordable even as low as 500 USD for the open source version printed by external service provider.

Here are some new developments:

Vulcan 1 rocket engine developed by SEDS team


SEDS (Students for the Exploration and Development of Space) is well known for their previous successful Tri-D 3d printed rocket motor developments. Now they are crowd-funding further development of bigger Vulcan 1 3d printed rocket engine and launch their Vulcan 1 rocket over 10000 feet.



Check out their KS campaign:

https://www.kickstarter.com/projects/1054991011/vulcan-i-rocket-powered-by-3d-printed-engine

NASA has developed a full size 3d printed copper engine


NASA successfully laser sintered full scale copper rocket engine.



They write:
“Building the first full-scale, copper rocket part with additive manufacturing is a milestone for aerospace 3-D printing,” said Steve Jurczyk, associate administrator for the Space Technology Mission Directorate at NASA Headquarters in Washington. “Additive manufacturing is one of many technologies we are embracing to help us continue our journey to Mars and even sustain explorers living on the Red Planet.”

Numerous complex parts made of many different materials are assembled to make engines that provide the thrust that powers rockets. Additive manufacturing has the potential to reduce the time and cost of making rocket parts like the copper liner found in rocket combustion chambers where super-cold propellants are mixed and heated to the extreme temperatures needed to send rockets to space.

A selective laser melting machine in Marshall’s Materials and Processing Laboratory fused 8,255 layers of copper powder to make the chamber in 10 days and 18 hours. Before making the liner, materials engineers built several other test parts, characterized the material and created a process for additive manufacturing with copper.
“On the inside of the paper-edge-thin copper liner wall, temperatures soar to over 5,000 degrees Fahrenheit, and we have to keep it from melting by recirculating gases cooled to less than 100 degrees above absolute zero on the other side of the wall,” said Chris Singer, director of the Engineering Directorate at NASA’s Marshall Space Flight Center in Huntsville, Alabama, where the copper rocket engine liner was manufactured. “To circulate the gas, the combustion chamber liner has more than 200 intricate channels built between the inner and outer liner wall. Making these tiny passages with complex internal geometries challenged our additive manufacturing team.”

“Copper is extremely good at conducting heat,” explained Zach Jones, the materials engineer who led the manufacturing at Marshall. “That’s why copper is an ideal material for lining an engine combustion chamber and for other parts as well, but this property makes the additive manufacturing of copper challenging because the laser has difficulty continuously melting the copper powder.”
Source and more information:
http://www.nasa.gov/marshall/news/nasa-3-D-prints-first-full-scale-copper-rocket-engine-part.html


Rocket Lab Electron Launch Vehicle


Rocket Lab is a private company that wants to provide cheap satellite rocket launch system for small satellites. Their Electron Launch Vehicle  rocket is made with carbon fiber and uses electrically powered 3d printed motor.




Rocket Lab uses Rutherford rocket engine that is almost entirely 3d printed:



Rocket Lab’s flagship engine, the 4,600lbf Rutherford, is a turbo-pumped LOX/RP-1 engine specifically designed for the Electron Launch Vehicle.
Rutherford adopts an entirely new electric propulsion cycle, using electric motors to drive its turbopumps, and is the first oxygen/hydrocarbon engine to use 3D printing for all primary components.

China has tested a 3d printed rocket engine part


China is making a progress forward, according to the report by 3ders.org:
Engineers from Institute 41 (part of the China Aerospace Science and industry Corporation) have already successfully tested an engine ignition device that has been created using 3D printing technology.

This is reportedly the first time Chinese engineers tested a 3D printed rocket component, but it seems to be very suitable for the job. Shell structures typically used for the ignition components in rocket engines are very difficult to design and produce, and are very costly and time-consuming to create. Engineers felt themselves bottlenecked, so a team from the ignition technology research laboratory of Institute 41 began incorporating 3D printing into their R&D process.
In collaboration with local manufacturers of 3D printing equipment, these engineers eventually and successfully 3D printed the first set of shells for ignition devices. To ensure these shells met all design requirements, researchers produced hundreds of 3D printed test samples, which were submitted to various extensive testing sequences.

We live in very interesting times... where will you boldly go?

3D Printed Antenna Knowledge Base

Since I'm getting more involved with communal WiFi mash networks and open source smart city project in my town, I decided to research and make a small knowledge base on 3d printed antennas.
This post will be updated as I gather new information.

Basically, there are two main areas of 3d printed antenna development: High-tech industrial and DIY. The main difference is in type of machines and purpose. Industrial 3d printers are very diverse with applications ranging from aerospace to consumer electronics, while DIY printers use mostly FDM and are used in hobby projects, drones, HAM etc.

High-tech industrial and commercial 3D printed antennas 


Optomec Aerosol Jet Antenna 3D printing


Optomec is an industry leader and they integrate their antennas in wide variety of products.



Here is the summary from process homepage:

Mobile device antennas including LTE, NFC, GPS, Wifi, WLAN, and BT have been printed using the Aerosol Jet process and independently tested by a leading cell phone component supplier.
Measured antenna performance is comparable to other production methods. The Aerosol Jet printing process is scalable – antennas can be printed on up to 4 cases simultaneously on a single machine. Machine throughput for a typical antenna pattern measuring ~300 mm2 averages 30,000 units per week. 
The Aerosol Jet printer lower manufacturing costs for antennas used in mobile devices. The process works with standard injection molded plastics – no special additives or coatings are required. Based on Aerosol Jet technology, the digital process prints conformal antennas using conductive nanoparticle silver inks.
The printing process accurately controls the location, geometry and thickness of the deposit and produces a smooth mirror-like surface finish to insure optimum antenna performance. No plating or environmentally harmful materials are used in the process.

You can see more on Optomec homepage:
http://www.optomec.com/additive-manufacturing/printed-electronics/aerosol-jet-core-applications/printed-antennas/

3D Printing antennas on curved surfaces with nanomaterials


From the source:
“Omnidirectional printing of metallic nanoparticle inks offers an attractive alternative for meeting the demanding form factors of 3D electrically small antennas (ESAs),” stated Jennifer A. Lewis, the Hans Thurnauer Professor of Materials Science and Engineering and director of the Frederick Seitz Materials Research Laboratory at Illinois.

“To our knowledge, this is the first demonstration of 3D printed antennas on curvilinear surfaces,” Lewis stated. The research findings and fabrication methods developed by Bernhard, Lewis, and their colleagues are featured in the cover article,"Illinois Calling" of the March 18 issue of Advanced Materials (“Conformal Printing of Electrically Small Antennas on Three-Dimensional Surfaces”).

Source with more details:

http://engineering.illinois.edu/news/article/2011-03-15-3d-printing-method-advances-electrically-small-antenna-design

http://spectrum.ieee.org/nanoclast/semiconductors/nanotechnology/nanoparticles-enable-3d-printing-for-cell-phone-antennas

http://scholar.harvard.edu/files/lewisgroup/files/adams_advmat_2011.pdf

Here is a similar technology used at Lawrence Livermore National Laboratory:


Source article and more information:

https://manufacturing.llnl.gov/additive-manufacturing/designer-engineered-materials

Fractal antenna systems 


Fractal Antenna Systems is a company that has been working for some 20 years in creating specialized antennas for military and civilian sector based on fractal patterns. They recently published that they also use 3d printers to make some designs.

Here are some other works on the topic of 3d printed antennas:


Fully 3D Printed 2.4 GHz Bluetooth/Wi-Fi Antenna by Paul Deffenbaugh, Kenneth Church from The University of Texas El Paso:  

http://utminers.utep.edu/pdeffenbaugh/2_4_ghz_imaps_paul.pdf

3D PRINTED ELECTROMAGNETIC TRANSMISSION AND ELECTRONIC STRUCTURES FABRICATED ON A SINGLE PLATFORM USING ADVANCED PROCESS INTEGRATION TECHNIQUES PAUL ISAAC DEFFENBAUGH, M.S.E.E. Department of Electrical and Computer Engineering (doctoral dissertation)

http://emlab.utep.edu/pdfs/Deffenbaugh_PhD_Dissertation.pdf

COMPACT FORM FITTING SMALL ANTENNAS USING THREEDIMENSIONAL RAPID PROTOTYPING by Bryan Jon Willis



Origami antennas and packaging using 3D printing technologies by John Kimionis and Manos Tentzeris

http://spie.org/x113138.xml

From other media:


3D printed satellite and space based antennas


I made a more detailed post here with several projects and materiel sources: 

http://diy3dprinting.blogspot.com/2012/12/3d-printed-satellites.html

DIY 3D printed antennas

 

If you search Thingiverse you will currently find 500+ projects tagged with "antenna".


As far as I know all of them are arrays where the actual antenna is some form of non-printed metal wire held by 3d printed frame or enclosure.

DVB-T antenna deigned to hold metal wire on 3d printed frame and that can be mounted on a back of a TV screen


There are many models ranging from UHF satellite communication arrays to drone piloting antennas like this one:




You can also make supports and guides to make more complex antenna designs like this DIY clover leaf antenna guide:































All the files and instructions:

http://www.thingiverse.com/thing:1082803

http://flitetest.com/articles/Cloverleaf_Antenna


So can we produce real metal antennas on DIY machines? In theory there are two project that enable you to embed wire into your plastic filament:

Slew ring wire embedding:

http://diy3dprinting.blogspot.com/2014/05/3d-printing-with-guided-slew-ring-wire.html

and Spoolhead:

http://diy3dprinting.blogspot.com/2013/09/embedding-metal-wire-in-3d-printed.html

Future will show are there any projects working with conductive filaments, but I don't know anybody currently developing antennas based on them.

Services like Shapeways can print in metal (they actualy make molds and then cast metal AFAIK) so Shapeways list 300+ products tagged with "antenna".

Link: http://www.shapeways.com/search?q=antenna

Here is an example of Shapeways made antenna:

Right Hand Polarized Antenna 5.8GHz 3D - for RG316





Let me know if you have anything related to this subject. Any feedback is welcome. 

3D printable open source liquid fuel rocket engine

Graham Sortino from New Jersey developed and tested 3d printed rocket liquid fuel engine. He went one step further and open sourced it! The engine is controlled by Arduino Uno! We live in amazing times!
The engine is made from three main modules: the igniter, injector, and the main engine body, all of which were SLS 3D printed by Shapeways and ExOne in bronze steel and machined afterwards to get the exact fit. Post-processing is a problem due to hardness of sintered metal so some tools break, the internal coolant lines are still not possible to 3d print due the geometry complexity and metal powder residues. 

The price is very low: 3d printed igniter costs some $60, the injector $80 and the rocket engine $260, for a total of just $400. Space exploration with extremely low budget!

The engine is still in development and not yet finished but it is a big step forward in open sourcing aerospace engineering! 

Engine specifications:
  • Fuel: GOX / Ethanol
  • Fuel Mass Flow: 0.0545 kg/sec
  • Oxidizer Mass Flow: 0.0545 kg/sec
  • Total Mass Flow: 0.1093 kg/sec
  • Design Mixture Ratio: 1:1
  • Design Force: 50 lbf
  • Design Chamber Pressure: 150 psia
  • Design Temp: 2572 Kelvin
  • Design Specific Impulse: 209 Isp 
Here are some photos of it:

Ignited engine. You can clearly see the mach diamonds.

3D printed engine and main lines / sensors

Here you can see a live test fire and mach diamonds:




Project homepage with files and instructions:

http://wiki.fubarlabs.org/FubarWiki/Small-Liquid-Fueled-Rocket-Engines.ashx

GitHub repository:

https://github.com/gNSortino/OSREngines/tree/master/Engines/2014-GOXEthanolRegenEngine

For previous 3d printed rocket engine named "Tri-D" look at:

http://diy3dprinting.blogspot.com/2013/10/students-developed-and-successfully.html

To boldly go where no one has gone before!


Laser metal deposition five axis 3d printing for aerospace appliances by Merlin Project

Laser metal deposition (LMD) is DMLS process that is the future of aerospace industry. Since European Union is a manufacturing powerhouse it is investing in many R&D projects like Merlin.
Ever major technological power is in the race to rule the industry and advance in digital manufacturing age.

From project description:
A 5 axis laser metal deposition manufacturing method is being developed by TWI for an EU-funded project which is demonstrating drastic time reduction in the manufacture of aero engine casings. 
In LMD, a weld track is formed using metal powder as a filler material which is fed through a coaxial nozzle, to a melt pool created by a focused high-power laser beam.
By traversing both the nozzle and laser, a new material layer develops with precise accuracy and user-defined properties. The application of multi-layering techniques allows 3D structures to be created.
To find out more please visit the project website: http://www.merlin-project.eu/ or go to TWI's website:http://www.twi-global.com/news-events...

Here is a video of the process. It took seven and half hours to print this thin walled casing prototype for jet engine test beds.





Here is a list of LMD technical advantages and disadvantages:

Advantages of LMD:
  • Metallurgical bond (not mechanical, thermal spray)
  • Wide variety of available powders 
  • Very low dilution is possible 
  • Relatively high deposition rates 
  • Process is highly repeatable 
  • Low impact on base material compared to similar processes (HAZ) 
  • Superior metallurgy compared to similar processes 
  • Virtually unlimited build height 
  • Very flexible tool path compared to wire applications 
Disadvantages of LMD:
  • High capital equipment costs
  • Powder cost is typically higher than wire
  • Capture ratio of additive material < 100% (based on process parameters)
  • Cannot control the process manually – CNC is required 
  • Experienced, specialized staff required (e.g. laser safety engineer, skilled operators)
LMD laser toolhead schematics:



Using home microwave for lost PLA 3d printed aluminum parts

Lost PLA is method used to produce cement molds for metal casting and it is used mostly with molten aluminum. Desired object is 3d printed in PLA, cast is made around it and the PLA is melted away. The mold is then used for metal casting. Entire process is usually done with a propane gas powered kiln or smelter, and this project used home microwave oven.

The process is simple but you will need to take safety seriously. Object 3d printed in PLA is coated with susceptor that transforms microwaves into heat. Susceptor is made from mixture of silicon carbide, sugar, water, and alcohol. The part is then placed in a mold made of plaster of paris with perlite and heated in an unmodified household microwave to burn out the PLA.
A second microwave with a top emitter is used to melt aluminum, which is then poured into the prepared mold. When the metal cools down, the mold is broken to take out the metal part for post-processing



























From project description:
Our system uses consumer microwave units to perform burn-out of PLA from molds, and a second microwave to liquify aluminium, to be poured into the mold. 3d printer inspired mechanics will move the aluminium from the microwave, into the target mold under human control across the network, so that there is no risk to the person operating the machine.
What is working and what we're working towards:
What works now is that we are able to successfully melt aluminum inside a microwave and supply our molds to get fine quality crafted aluminium parts.
The vision is to automate the process and build machines so that the system can be remotely run by a human being safely from their terminal.
Automation will be as simple as two to three machines powered by arduino with minimum axes.

One machine will be a forklift to pickup the item and deposit it safely onto a pair of fire bricks. One is a crane to pickup the top from the kiln, and one is a combination of forklift and a x,y table. This will pickup the cup, place over target, and pour through a heated steel funnel into the mold.
Ideally, we see an operator walking to the machine, starting the microwave on the mold & aluminium. When notified the machine is done, the operator can use gloves to pickup and bury the mold in sand, then walk back to their workstation, and pour the aluminum remotely. This will reduce the risk of injury to an operator to near 0, and not require any dangerous gasses to perform the melt.
All of the software will be released under the GNU GPL V3 as the project advances, with the hardware designs released under the TAPR OHL.

Detailed project page and build log on hackaday.io:

http://hackaday.io/project/2434-microwave-aluminium-printing

Project homepage:

http://fosscar.faikvm.com/trac/wiki/LostPLA


UPDATE:

Here is very detailed video presentation by Julia Longtin on Chaos Computer Club 31th Chaos Communication Congress. It is a great how-to guide on casting high quality 6040 aluminum pieces using a 3D printer and commercially available consumer microwaves



Here is a more detailed guide on how to make and use microwave oven DIY smelter for silver or tin solder:

http://www.instructables.com/id/microwave-smelter/?ALLSTEPS





Here is a different approach to melting aluminum in a microwave oven:



Fabrisonic SonicLayer 7200 industrial ultrasonic metal printer with integrated CNC tools

Fabrisonic SonicLayer 7200 is industrial ultrasonic metal printer with integrated CNC machining tools.
It is a BIG machine that 3d prints with aluminum tape layers which are fused together with ultrasound and then machined with CNC tools into final shape. It can produce intricate internal structures and make metal products on industrial scale.


Fabrisonic SonicLayer 7200 3d printing anc CNC machining center. Source: Fabrisonic





SonicLayer 7200 Production scale automated UAM system technical specifications:
  • Integrated 3-Axis CNC Machining
  • Automated Tape Feeding System
  • 5000-lb load
  • 9-kW power
  • 72 x 72 x 36 in. Roll and Pitch Capability

Here is a video showing the machine in action:




Price is unknown.

Homepage: http://fabrisonic.com/soniclayer-7200/


Here are some previous smaller Fabrisonic machines and technology overview:

http://diy3dprinting.blogspot.com/2013/07/ultrasonic-metal-3d-printing.html



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