You have me thinking of like… A ring around the equator with space elevators on it (with stations at the top), and “rail” tracks, with trains traveling between all the stations. Gaussian launchers sending packages to your nearest delivery depot.
Believe it or not, that’s a feasible (ish) plan for a space elevator we could build right now. Instead of having a counterweight at GEO that’s pulling on a carbon nanotube rope, you have a ring spinning inside another ring in LEO. The outer ring could be made of Kevlar, and IIRC, it would take something like a year or two of all current Kevlar production. You then need four stations approximately equidistant apart around the equator to act as counterweights.
The station for the Pacific would itself be quite the engineering challenge. Not a lot of land you can use at the place you need.
Okay, trying to wrap my brain around this one at 4:15am.
Is the idea that a ring around earth basically floats there because it’s around the whole planet? Like, when it attempts to fall towards earth on one side, it would require it to move up on the other, away from gravity? So it’s perpetually falling towards earth, but balanced because it’s also falling in the opposite direction on the other side of the of the planet?
Or have I completely misunderstood?
Also, one of the videos mentioned it would need to be filled with something (I forget now), in a vacuum tube that ran its whole length… What happens if the vacuum tube gets a hole in it? Does the whole thing break apart and crash to earth?
I want the future they describe, but I can’t say that I understand it lol
Been a while since I looked at this one, but the idea was that the inner ring would be rotating at faster than orbital velocity at that altitude. This would normally cause it to push itself out to a higher orbit, but the outer ring (or belt) would prevent that. That outer belt would be under a lot of tension, but not carbon nanotube level tension.
You have me thinking of like… A ring around the equator with space elevators on it (with stations at the top), and “rail” tracks, with trains traveling between all the stations. Gaussian launchers sending packages to your nearest delivery depot.
Believe it or not, that’s a feasible (ish) plan for a space elevator we could build right now. Instead of having a counterweight at GEO that’s pulling on a carbon nanotube rope, you have a ring spinning inside another ring in LEO. The outer ring could be made of Kevlar, and IIRC, it would take something like a year or two of all current Kevlar production. You then need four stations approximately equidistant apart around the equator to act as counterweights.
The station for the Pacific would itself be quite the engineering challenge. Not a lot of land you can use at the place you need.
Just anchor one of the garbage patches and use that.
Okay, trying to wrap my brain around this one at 4:15am.
Is the idea that a ring around earth basically floats there because it’s around the whole planet? Like, when it attempts to fall towards earth on one side, it would require it to move up on the other, away from gravity? So it’s perpetually falling towards earth, but balanced because it’s also falling in the opposite direction on the other side of the of the planet?
Or have I completely misunderstood?
Also, one of the videos mentioned it would need to be filled with something (I forget now), in a vacuum tube that ran its whole length… What happens if the vacuum tube gets a hole in it? Does the whole thing break apart and crash to earth?
I want the future they describe, but I can’t say that I understand it lol
Been a while since I looked at this one, but the idea was that the inner ring would be rotating at faster than orbital velocity at that altitude. This would normally cause it to push itself out to a higher orbit, but the outer ring (or belt) would prevent that. That outer belt would be under a lot of tension, but not carbon nanotube level tension.