LiftPort Wants To Build Space Elevator On the Moon By 2020

Zothecula writes "When the late Neil Armstrong and the crew of Apollo 11 went to the Moon, they did so sitting atop a rocket the size of a skyscraper that blasted out jets of smoke and flame as it hurtled skyward. For over half a century, that is how all astronauts have gone into space. It's all very dramatic, but it's also expensive. Wouldn't it be cheaper and easier to take the elevator? That's the question that Michael Laine, CEO of LiftPort in Seattle, Washington, hopes to answer with the development of a transportation system that swaps space-rockets for space-ribbons. LiftPort ultimately wants to build a space elevator on Earth, but the company isn't planning on doing it in one go. Instead, Laine and his team are settling for a more modest goal – building an elevator on the Moon by 2020. This is much easier. For one thing, there’s no air on the Moon, so no icing problems. Also, the lower gravity means that no unobtainium is needed for the ribbon. Kevlar is strong enough for the job. And finally, there’s very little in the way of satellites or debris to contend with."

There is one problem...

[Nadaka]

That problem is that there is no way to create a lunar-centric orbit where the upper terminus of the ribbon hovers over a fixed position. So any tether can not be fixed to the ground. So lifting anything with that tether will involve something like a skyhook catch, except it will be at orbital velocities.

Re:There is one problem...

[ClickOnThis]

That problem is that there is no way to create a lunar-centric orbit where the upper terminus of the ribbon hovers over a fixed position.

Actually a Lagrange point would do fine for that. L1 is about 58,000 km from the moon towards the earth.

Re:There is one problem...

[david.given]

Having read TFA, this seems to be precisely what they're doing; it looks like they deploy at the L1 point and extend the tether in both directions. Of course, this does mean the tether needs to be an extraordinary 250000km long.

Despite being totally awesome (which is reason enough to do it!) and also good practice for Earth (ditto) I am slightly at a loss as to how useful this would be. Space elevators are slow, and a lunar elevator would be really long and therefore really slow. And it's not as if the moon's hard to land or take off from.

I'm wondering if there's something useful to do with the other end. The high end of the tether is only 135000km from Earth. Is that far enough into the ionosphere to use for power generation?

One other thing a Space Elevator needs...

[yotto]

They're forgetting the single most important part of a space elevator: It needs to actually be useful.

What are we going to do with a space elevator on the moon? We don't go there for a very good reason: Its expensive as hell. Making the cheap and easy part a little cheaper an easier isn't going to change the fact that the entire rest of the trip is prohibitively expensive.

It's like your friend moving across town to be closer to you, but he lives in Seattle and you live in London.

Re:One other thing a Space Elevator needs...

[jfengel]

If we had helium fuel, we could have helium-fueled fusion energy, if we had a fusion reactor.

Re:One other thing a Space Elevator needs...

[bware]

Why deal with dust at all? Put your scope in space.

The temperature extremes are much worse on the moon - close to absolute zero to hundreds of K if my memory serves right . In space, you just put your scope at L2 or Earth-trailing, build a passive solar shield (or use a cryopump if you need really low temps), and point it away from the sun. Voila, constant temperature and 100% duty cycle. Put your scope in space.

There's also the fact that during the two weeks of duty cycle where you can operate the scope, you don't have solar power, so you have to have some way of storing energy. A telescope in space just uses solar panels and gets power 24/7. You'll have to cool your electronics half the time, and heat them the other half, so again, power, and storage. Go ahead, say nuclear. My understanding is that the moon has very few heavy elements, so all that has to come from Earth. So add a nuclear reactor, RTG, or batteries to your expenses.

Telescopes on the moon have to have pointing mechanisms, and the moon has gravity, so it's more mechanically complex (dust, vacuum). Telescopes in space have reaction wheels and thrusters to control pointing. No dust, and also few moving parts in vacuum. Much simpler. Put your telescope in space.

That is, in fact, why we are putting our telescopes out at L2 or Earth-trailing. Hubble would have been there had it not been for the mandate that it ride the shuttle. Have you noticed that we're not putting telescopes in Earth orbit anymore? It's not because we don't have the shuttle. It's because Earth orbit is sub-optimal, and not just a little bit.

As far as comparing astronomy on the moon to astronomy on Earth, well, Earth has a lot of advantages for telescopes, and that's why there are lot more of them here on Earth than there are in space. Not least that you can breath the atmosphere and find cheap places to sleep and have grad students pull the late night shifts. There are of course disadvantages, and you could never have JWST on the ground, but the moon is just not a great place for telescopes. I'm not entirely talking out of my ass here. I've sat in the rooms where these tradeoffs were made, and the moon gets put on the list. Then we start ranking. The moon ranks low in performance (duty cycle, power), high in cost (humans in space suits have to build it, everything has to be shipped from Earth), and high in risk (you have to ask why, srsly?). Then by the wonders of Excel, the moon drops to the bottom of the rankings.

But it is considered.

That's even assuming we had the capability to build a telescope on the moon. Which would be insanely expensive. Humans building telescopes, launchable or not, where they can breathe is always going to be way cheaper than building them on the moon.

Care to link to any peer-reviewed documentation that shows the abundance of He3, or any other interesting mine-able elements on the moon? I am ignorant of the geology of the moon, so if there's evidence that there are mine-able elements on the moon (including He3), I'd be happy to have my ignorance lessened.

You haven't really addressed the question of you know, actually having a working fusion reaction that needs He3. We don't. And probably won't any time soon. What are the economics of mining something we don't yet need and is difficult to store?

..ok, how?

[kheldan]

Wouldn't we need to get back to the Moon, establish some sort of colony there, and create the industry and infrastructure just to build such a thing in the first place? I can't see this all happening in the next 8 years.

Re:Space elevator orbiting the moon?

[Time_Ngler]

They said Space elevator. Space elevator "orbiting the moon" are your words. This link shows exactly what they are attempting to do: http://www.gizmag.com/lunar-elevator/23884/pictures#2

Re:Just build it horizontally

[randall77]

Because catching a bullet with a gun is just as easy as shooting a bullet from a gun...

Re:The goal of the project?

[History's+Coming+To]

There's plenty worth lifting off the moon, if we can do it. There's water for starters, plus plenty of raw materials for making high quality metals, ceramics, semiconductors and so on. If you can send them into a low Earth orbit then you'll probably find you can beat the per-kilo costs of launching similar material from Earth, what with the big gravity well and atmosphere and all. If you can undercut an entire planet then I'd call that a worthwhile business opportunity. Can't see how a space elevator helps much, but there's plenty worth lifting off the moon.

Re:well that's just silly

[Nethemas+the+Great]

Similar ideas were had about computers and a great many other things. Sometimes the destination is a bit farther from you than your myopic vision permits to be seen. I also didn't say "economical" relative to earth bound alternatives but then you're also making the assumption that we're taking this stuff back to earth. Let's throw a few points up that you might not be considering:

• He-3 is preferable for a fusion fuel since it's aneutronic--no radiation to deal. It comes that way from the moon, the path to producing it on earth does everything but avoid radiation.
• He-3 is useful as an advanced fuel in rocket propulsion
• Power can be produced in space and beamed down to earth
• Many of those rocks we have down here on Earth resulted from really big rocks from space slamming into us. Might be good idea if we have technology, infrastructure and humanity already in space before we're in need of it.
• Putting multi-trillions of dollars into the vacuum is preferable to craters into the middle-eastern sand. The same jobs are created but at the end of the day at you have something far more impressive to show for it and far fewer lives expended.

Kickstarter campaign!

[Esteanil]

You put LiftPort on the front page and forget their KickStarter campaign?
It started on the 23.08, and in 5 days it's raised $27.514 of the 8000 goal.

http://www.kickstarter.com/projects/michaellaine/space-elevator-science-climb-to-the-sky-a-tethered

Re:well that's just silly

[Nethemas+the+Great]

The mining machines wouldn't necessarily need to be: massive, transported via the tether, and/or come down fully assembled. Not everything has to start out on massive scales. For instance consider the state of global shipping back in the 18th century then compare that to the early 21st. Or farming in the 18th vs. 21st. Normally things start out small and gradually build out as technology and resources develop. Staging things is simply an engineering problem which if Curiosity is any indicator we seem to be getting pretty good at. Even during the Apollo missions we were dropping some pretty serious hardware down onto the moon. Powering these machines can come from any number of technologies from mundane to exotic. We already have well proven solar and RTG technologies, there are a few rather interesting possibilities using in-situ resources as well. For instance using the newly discovered water with the aluminum in the regolith to produce hydrogen for fuel. The Aluminum Hydroxide byproduct has its own interesting uses. The obvious one is of course simply using the mined He-3 for fusion power (whenever we get that one figured out).

Few grand adventures into human frontiers are ever "practical" initially and that unfortunately prevents people from seeing what humanity's pioneers and explorers see. In the 1800's no one got what Charles Babbage saw. During the first half of the 1900's very few saw what Konrad Zuse saw. Today no one can miss it and everyone demands it. People too often are quick to see problems as "too hard", too near-sighted to see possibilities, too self-centered to appreciate the benefits to others. You might not get to holiday on Utopia Planitia, or sail the methane seas of Titan but wouldn't it be awesome to initiate the projects now that make that a reality for your progeny? Both incomprehensible business opportunities and human delights await us on this next frontier. What are we waiting for?

Re:The goal of the project?

[lennier]

3He will power the world!

It will certainly be a much cleaner, albeit hugely expensive, non-feasible fuel for the fusion reactors we won't be able to build in 2050 than the cheap and readily available non-feasible fuel we can't extract from ordinary seawater for the fusion reactors we can't build right now.

Re:The goal of the project?

[Immerman]

Indeed, to be stable the elevator would have to be "stationary" within the rotating Earth-Moon frame, with the top extending past either the L1 or L2 point (towards or away from the Earth) far enough that the force of it "falling away" from the moon would be sufficient to counteract the weight of the cable itself.

Calculating the exact distance of the L1 and L2 points can be difficult, but so long as the masses are significantly different they are at approximately the Hills Sphere radius from the smaller mass M2 at r = R (M2 / 3*M1)^1/3. For the earth-moon system that is about 60,000km from the moon, versus the 36,000 km from Earth that constitutes geostationary orbit. So the elevator would have to be about 60% longer than on Earth, but the much lower gravity means it could be far thinner and weaker, and thus easier to build. Even perfect carbon nanotubes barely have the strength-to-weight ratio necessary for an earth-based elevator, with no room for a safety margin.

Plus for the immediate future at least the liability is much lower on the moon - a failure that drops 60,000 km of cable onto the moon from orbit is unlikely to be a problem beyond the fact that your very expensive elevator is now scrap. Drop 36,000 km of cable onto Earth, enough to to wrap almost all the way around the planet, and you're going to have a heck of a lot of secondary damage.

Personally I prefer the idea of the "tumbling cable" elevator - take just a few hundred kilometers of cable orbiting while tumbling end-for-end with the tips coming down almost to the surface like opposing spokes on a wheel rolling along the Moon's equator and you've got an elevator that will match speeds with various points on the equator on a regular basis, coming almost straight down before momentarily stopping and then hauling snagged payload up at roughly 1/4g. By the time the payload reaches it's highest point it will be moving sufficiently fast to easily escape the Moon's gravity, and depending on the particular orbital trajectories of the cable and Moon at the moment of release, moe than enough to escape the Earth's as well, even to put it on a Hohmann transfer orbit to Mars or Venus. Granted all that extra energy means it's not ideally suited to Earth-Moon transfers, but it sure would be a lot smaller and easier to build (except for the necessary drive system to recharge the angular momentum transferred to the payload), as well as making the Moon a major waystation to our much more interesting planetary neighbors.
 

Re:The goal of the project?

[Immerman]

Who needs speed? The elevator would still let you drop big rocks on Earth - sure they're moving slow relative to the top of the elevator when you let them go, but the entire moon is moving at about 1,000km/s relative to the Earth, and once those rocks have fallen the remaining couple hundred thousand kilometers to Earth they'll be moving even faster, more than enough to do massive damage wherever they're aimed. We *might* be able to shoot them down, assuming were willing to expend a space-capable nuke against it, were able to hit the thing given the massive speed it's traveling at (shouldn't be *that* hard to basically stand in it's path), and preferred to have radioactive slag come raining down over a wide area rather than letting the rock vaporize it's target. Of course if several rocks were dropped at once that would be far more difficult.

That's the one big problem with a space-based economy - once you're moving heavy stuff around in orbit *everything* becomes a high-yield weapon, and there's not much anyone on Earth can do to defend against it. It's like the ultimate version of trapping your enemy in a narrow canyon where you can fire down at them from all sides. And if an Earth-moon war should ever break out, well the Moon is almost guaranteed victory - both sides will see any incoming weapons a long way out with plenty of time to intercept - but hitting the Moon requires high-energy launches, while launching from the moon requires only ~1/25 the energy (~1/5 the escape velocity) so they can just throw rocks all day long for the cost of launching one missile, and any debris from intercepted weapons in either direction is far more likely to fall back to Earth than hit the moon.

Re:well that's just silly

[spauldo]

Seriously, name one thing that's on the moon that you think is worth trillions of dollars, keeping in mind that its surface is entirely covered in rocks.

Rocks in space.

Seriously, look at the price of titanium on earth - about $7 US per kg for commodity ferro titanium. Look at the price of titanium in low earth orbit - according to Wikipedia, it costs about $4300 US per kg using a Proton rocket (the cheapest non-subsidized launch method listed). There's quite a lot of titanium on the Moon, as well as aluminum, iron, and magnesium.

That's why we want to mine asteroids and the Moon - getting material out of the Moon's gravity well is a lot easier than getting it out of Earth's gravity well (and of course asteroids generally don't have an appreciable gravity well).

If we want a space station that's more than just a few tin cans glued together and can protect its inhabitants from radiation, we need building materials. We can get many of those materials from the Moon. We'd have to learn how to process and smelt them there first, of course, but you have to start somewhere.

He3? Well, maybe later. You don't build a gas station before the invention of combution engines. Water is more valuable, if it can be collected in any serious amount, which we still don't know.

That said, I have my doubts that anyone could put a space elevator on the moon in 8 years. It's just not going to happen. The design phase would take at least half that time.