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康奈爾大學(xué)開(kāi)發(fā)一款軟件使3D打印技術(shù)可在空間站應(yīng)用

星之球科技 來(lái)源:網(wǎng)易2022-03-08 我要評(píng)論(0 )   

如果在未來(lái)太空探索更加深入,那么人類就需要能夠在太空中實(shí)現(xiàn)自給自足,畢竟從地球往太空運(yùn)送物資不像送快遞:網(wǎng)上下單,幾天后就能送到。例如宇航員需要一些零部件,...

如果在未來(lái)太空探索更加深入,那么人類就需要能夠在太空中實(shí)現(xiàn)自給自足,畢竟從地球往太空運(yùn)送物資不像送快遞:網(wǎng)上下單,幾天后就能送到。

例如宇航員需要一些零部件,最好的辦法就是用現(xiàn)成的材料制作一個(gè),3D打印技術(shù)則可以很好的幫助實(shí)現(xiàn)這一目的。

但是想要讓3D打印技術(shù)在太空應(yīng)用,還會(huì)面臨諸多挑戰(zhàn)。重力的缺乏、時(shí)間和空間尺度的差異以及溫度的劇烈變化都可能阻礙這一過(guò)程,導(dǎo)致材料浪費(fèi)和零件無(wú)法使用。

最近,康奈爾大學(xué)就著手研發(fā)了一款軟件幫助解決這些問(wèn)題。

If deep space exploration is to become a reality, humans will need to be as self-sufficient as possible. Since ordering supplies from Earth won’t be practical, the astronauts will have to fabricate their own components for equipment and other products through additive manufacturing, better known as 3D printing.


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But the challenges for “Earth-independent manufacturing” are as vast as space itself. The lack of gravity, differences in time and spatial scales, and radical changes in temperature could all stymie the process, resulting in wasted material and unusable parts.

Those challenges may be overcome thanks to modeling software created in the lab of Derek Warner, professor of civil and environmental engineering in the College of Engineering, and successfully tested aboard the international space station as part of a collaboration between Cornell, Hewlett Packard Enterprise (HPE), NASA and the ISS U.S. National Laboratory.

The experiment, conducted on Jan. 1, was part of an ongoing effort to demonstrate the functionality of the HPE Spaceborne Computer-2, which was launched to space in Feb. 2021 and installed on the space station as the first commercial, state-of-the-art edge computing system with artificial intelligence capabilities. The new edge computer enables real-time processing of massive amounts of data in space, eliminating the long latency issues, and the waiting, associated with relaying data back and forth to Earth.

For the last year, astronauts have been running a range of data-intensive experiments on Spaceborne Computer-2, from processing medical imaging to DNA sequencing. Additive manufacturing was a prime candidate for testing because it is “absolutely critical to the things NASA wants to do with deep space exploration and going to Mars,” according to doctoral student Terrence Moran, who designed the Cornell software.

But even on solid terrestrial ground, 3D printing can be a fickle process full of trial and error, even for experts who have decades of experience with the technology. Those problems are only compounded in the unforgiving environment of space. After all, the most common form of 3D printing is powder bed fusion, in which powder is layered on a substrate and bonded or melted, which requires gravity. But there are also regular hiccups with the process itself.


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“Let’s say you’re in space and you need a part,” Warner said. “If you just were to draw the part or upload a CAD file to your 3D printer and press print, it probably won’t work, just because 3D printing isn’t at that level of maturity. You would need to adjust the printing process and the parameters, so it will come out successful and you won’t waste your material.”

The Cornell Fracture Group, which Warner leads, specializes in conducting scientific and engineering research to better understand and predict the deformation and failure of structures. With that expertise, Moran developed a modeling software that can simulate how the 3D printing process will play out for a desired component and whether the result will be high or low quality.

“Previously, this was computationally infeasible due to discrepancies in time and spatial scales and high thermal gradients,” Moran said. “So we developed the software with a physics-based model, made it portable, and uploaded it to the ISS. It was successfully run and the results were consistent with the results we’d done during our research. The timing and everything were the same.”

In essence, the modeling is a form of virtual printing, one that promises to save time, material and, in combination with Spaceborne Computer-2, digital bandwidth. Not only will the software benefit deep space engineering; it could be an asset much closer to home.

“One of the allures of 3D printing is that you can manufacture locally,” Warner said. “So the neat thing about this is that, while space might be the most extreme environment, for the military or on oil rigs or other places, there’s also going to be a need for doing the same thing. This demonstrates that it’s possible.”


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