#1 SpaceFab: 3D printing and robotic assembly in space
Posted: Tue Sep 03, 2013 5:46 pm
Ok - this is an idea and project that makes me happy.
In my mind, a project like this would neatly dodge the huge cost of money per pound of stuff put into orbit problem by just requiring raw materials be replenished. An orbital factory based on this design could make things very interesting.
NASA's documentation on it, if you're curious: http://www.nasa.gov/sites/default/files ... derFab.pdfgizmag.com wrote:SpiderFab, a series of technologies under development by Tethers Unlimited, Inc. (TUI), combines 3D printing and robotic assembly to build and create spaceship components and structures in orbit. The groundbreaking systems are being designed to enable on-orbit construction of antennas, booms, solar arrays, trusses and other multifunctional components, ten to hundreds of times larger than currently possible with existing technology.
TUI has recently received an additional US$500,000 phase 2 NASA Innovative Advanced Concepts (NIAC) contract, supplementing an initial $100,000 phase 1 contract awarded in August 2012 to develop the new technology.
The ability to fabricate and integrate large components in space such as “kilometer-scale antenna” and massive solar arrays should enhance NASA’s ability to acquire and distribute higher resolution data using wider bandwidth with greater signal to noise ratios and at a much reduced life-cycle cost. Additionally, by reducing packing size and mass, NASA will be able to use smaller and less costly launch vehicles to deploy systems vastly bigger than present capabilities allow.
Currently, large space-bound components are manufactured in situ and then folded within a rocket shroud to deploy when orbit is reached. This approach can be expensive and, clearly, the component size is limited to the space available within the shroud.
“On-orbit fabrication allows the material for these critical components to be launched in a very compact and durable form, such as spools of fiber or blocks of polymer, so they can fit into a smaller, less expensive launch vehicle,” says Rob Hoyt, TUI’s CEO and Chief Scientist. “Once on-orbit, the SpiderFab robotic fabrication systems will process the material to create extremely large structures that are optimized for the space environment.” The TUI space fabrication technologies will also create systems that are both repairable and re-configurable while in orbit and may even evolve to support the utilization of orbital debris and asteroid materials some time in the future.
In parallel with the NIAC funded SpiderFab research, TUI is also developing, under NASA contract, a “Trusselator” device that will fabricate truss structures to enable in-space construction of large solar arrays. “Once we've demonstrated that it works,” Hoyt advises, “we will be well on our way towards creating football field-sized antennas and telescopes to help search for Earth-like exoplanets and evidence of extraterrestrial life.”
If all goes according to plan, TUI will demo the new technologies out there in space before 2020. A detailed 53 page document outlining the full extent of the technology can be found on NASA’s website.
In my mind, a project like this would neatly dodge the huge cost of money per pound of stuff put into orbit problem by just requiring raw materials be replenished. An orbital factory based on this design could make things very interesting.