Since were talking hundred-year timescales, wouldnt it be better to drill deep into the moon, set off a massive nuclear device inside the moons crust and build this thing in the resulting cavity? Then youre not only protected from muscle loss due to lack of gravity, but also from radiation (though probably not all).
At least we would have a good use for all these nukes
Why not simply build a space station instead with the same concepts? For argument's sake it would be a small O'Neil cylinder with a short shuttle or small space elevator to the moon.
I'd expect research or mining sites to be quite basic and not like this habitat anyway.
edit: I guess, if they build it in one of the moon's craters where the sun never shines, and where pockets of frozen water exist, it would make shielding from the sun a lot easier than a complex orbit.
Tethered, wheel and tubes are all the same thing. The minimal setup is one habitat tethered to an equal weight. As you add habitats, you eventually end up with a wheel. If you stack these wheels, you end up with a tube.
> still existing gravity towards the moon, which would be a constant additional force pulling you sideways
That would be why it's a cone not a cylinder, to line up the "subjective down", the sum of forces including lunar 1/6 g; with the direction that the ground is in.
Stopping would be an issue. But it looks like there is some accommodation for that in the form of a big "bathtub" at the bottom that could hold the water. IDK why there's so much water in the first place though.
You mean everything fall left* and do a big mess on the wall, right? Frames of reference are fun. We also have a force pulling us sideways on Earth since it's rotating but without doing the math, it's probably a lot lower than 1/6 g, indeed.
* or right, no idea if this is spinning clockwise or anti-clockwise.
And no matter which direction it spins, it depends on which direction you look. if you are looking "upwards" it falls "backwards", "downwards" = "forwards" and so on.
The Moon's "atmosphere" is (practically) frictionless, so if you build this thing with a similarly-frictionless bearing (e.g. really strong magnets) it could theoretically spin near-indefinitely.
Whether that's actually achievable (while still allowing people and supplies and water and oxygen and such to enter and exit) is of course another question.
I wonder what it would do to human biology to have 1 g pulling us down as we evolved to handle, but also 1/6 g pulling us sideways. I guess it would cause all sorts of balance and medical issues.
> 1 g pulling us down as we evolved to handle, but also 1/6 g pulling us sideways.
Look at the design, with the surface not vertical but at a steep angle inward. It's pretty clearly designed to produce a total perceived weight equivalent to 1g, composed of 1/6 g downwards caused by the moon, and I suppose 5/6 g sideways caused by rotation. The floor is at an angle that works with the sum of these forces.
I can't read Japanese and just watched the videos, but what they illustrate seems pretty strange. Why is it mostly water instead of human living space? If the water's meant to let in more light, that's more likely to end up boiling the water during the day and freezing it solid overnight. https://en.wikipedia.org/wiki/Moon#Surface_conditions
Water happens to be a rather effective radiation shield, so I suspect that might be at least part of the reason why there's so much of it in the design.
Better way is to make a scientific committee, that would declare all side effects (muscle loss, bone density loss...) as totally random and uncorrelated to moon environment. Worked before...
I always wonder why is nobody considering simply introducing "heavy" weights for every person to wear on planetary body like a moon? A sort of inverse-exoskeleton if you wish.
For an average 75kg person, you'd need to add roughly 5x (375kg) to their weight to reach parity between Moon and Earth, which if done with iron or steel would need less than 50l of volume spread around the body. Heavier metals could be used for an even lower volume, of course (though you'd want to avoid poisonous metals like lead, mercury or osmium), though you might hit other bottlenecks (gold and platinum are 2.5x denser, and iridium even more so, but price comes into play — perhaps locally sourcing them on other "rocky" planets is more feasible).
This does not resolve all of the issues mentioned in the article (like the effect on our internal organs, childbirth and such), but can definitely target a bunch of externally accessible muscles to keep them from getting atrophied.
Perhaps this will be a cheap solution for those not living in the rotating megastructures. I should start collecting gold to be able to go sightseeing on the Moon.
The additional mass will have tons of inertia, making ordinary activities like walking difficult, regardless of its current weight in the local gravity.
> This does not resolve all of the issues mentioned in the article (like the effect on our internal organs, childbirth and such)
Yeah it would be like anchoring a balloon. Sure it's not going to float away but it's still a balloon. It's our internal jiggly bits that are important too.
Weights don't really accomplish much. The acceleration due to gravity is constant regardless of mass, so you would still have to bunny hop. And as a sibling comment pointed out, the inertia of all that extra mass would be huge, so actually moving would be 6x more difficult. You'd trip almost immediately, and the impact with the ground would hurt as much as on Earth, since you've calibrated your gravitational potential energy to be the same.
The already have a good solution for surviving in Zero-G: Exercise.
We had people on the ISS stay for a year.
I would also imagine the difference between zero gravity and little moon gravity to be quiet significant regarding keeping people healthy.
Will long extended stays be healthy? No but that is a problem for the far future. I think the focus now should be to get the basic logistics in order. I am sure there would be enough people that would be willing to participate in a mission to Moon even if it meant a shortening of their lifespan. Nothing about the first colonization attempts will be pretty but colonization has never been very pretty in human history to begin with.
Some long-term microgravity health risks are also short-term mission risks, like ocular problems and increased blood clotting. If a centrifugal habitat helps prevent these, so much the better.
Does this address the Coriolis effect and other issues that make rotational "gravity" feel really weird compared to actual gravity (6:58 https://m.youtube.com/watch?v=nxeMoaxUpWk)?
Also unless I missed it, they fudged the part where the trains transition from the static tracks to the rotating structure. If so, that speaks volumes to their level of attention to detail.
Did anybody pick up what the lit up pit in the middle was supposed to be?
Any activity that requires going outside will inevitably get some amount of dust through the airlock. So, it is going to slow it down by a lot, but not stop it.
Well, vacuum cleaners are a thing and could probably be exported to the moon to take care of any dust getting inside. The dust is extra abrasive because it hasn't been exposed to weathering due to the lack of athmosphere and so has kept all the sharp edges. As soon as it gets inside and gets chafed/bumped around, many of the sharper edges will abrade. Of all the challenges for making humans live on the moon, sharp dust is one of the smaller ones.
Could some sort of robotic vacuum autonomously suck it up and get rid of the harshest of edges. At least in the regions nearest to the base where active work is being done
Some of it stuck to the outside of spacesuits and/or robots when they went outside. Neither should be going beyond some intermediate garage area anyway, just like you don't usually park your car in the bedroom.
> And what's stopping the rest?
The airlock door? There's no wind on the moon, so it won't blow inside on its own.
> And where do you put what's captured?
Well, I'd assume that once your vacuum cleaners are full you'd take a moon-lorry and dump the lot into a nearby crater or something. If it's as sharp as advertised, the sharp edges might make it well-suited for use in concrete as well.
In any case you don't have to keep the entire moon clean, only the inside of the base. It doesn't seem to be a terrible burden to clean the suits and rovers after every expedition, more like something that you plan to do anyway because you want to keep those expensive things well-maintained.
I find the title a little bit strange. Japan, the country, did not propose anything. Specific entities within Japan did. Perhaps I'm too post-nationalistic for this article's title.
I feel like building this as a spinning ring (possibly inside a crater) makes more sense from a structural integrity standpoint (and possibly also a radiation shielding standpoint). Granted, lunar gravity probably makes structural integrity about ¹/₆ᵗʰ as hard to achieve as on Earth, but the spinning tower still seems a bit precarious.
Why does it have to be ON the moon though? An orbital station would rotate just the same, and if you are close enough to the moon you could still travel to the surface now and then for specific missions.
61 comments
[ 4.8 ms ] story [ 115 ms ] threadAt least we would have a good use for all these nukes
I'd expect research or mining sites to be quite basic and not like this habitat anyway.
edit: I guess, if they build it in one of the moon's craters where the sun never shines, and where pockets of frozen water exist, it would make shielding from the sun a lot easier than a complex orbit.
In fact, maybe we should just cut to the chase and build amusement parks on the Moon. You know, for "physical and mental health" or something.
- Everything falling down and the mess on the floor when this thing has a downtime
- The still existing gravity towards the moon, which would be a constant additional force pulling you sideways (down) with 1/6 g
That would be why it's a cone not a cylinder, to line up the "subjective down", the sum of forces including lunar 1/6 g; with the direction that the ground is in.
Stopping would be an issue. But it looks like there is some accommodation for that in the form of a big "bathtub" at the bottom that could hold the water. IDK why there's so much water in the first place though.
* or right, no idea if this is spinning clockwise or anti-clockwise.
Whether that's actually achievable (while still allowing people and supplies and water and oxygen and such to enter and exit) is of course another question.
Look at the design, with the surface not vertical but at a steep angle inward. It's pretty clearly designed to produce a total perceived weight equivalent to 1g, composed of 1/6 g downwards caused by the moon, and I suppose 5/6 g sideways caused by rotation. The floor is at an angle that works with the sum of these forces.
Having said that, "spin gravity" isn't always comfortable, it depends on how large and how fast it is: https://space.stackexchange.com/questions/9575/mitigating-na...
This structure looks easily big enough to be out of danger, at 3rpm and 100m radius.
For an average 75kg person, you'd need to add roughly 5x (375kg) to their weight to reach parity between Moon and Earth, which if done with iron or steel would need less than 50l of volume spread around the body. Heavier metals could be used for an even lower volume, of course (though you'd want to avoid poisonous metals like lead, mercury or osmium), though you might hit other bottlenecks (gold and platinum are 2.5x denser, and iridium even more so, but price comes into play — perhaps locally sourcing them on other "rocky" planets is more feasible).
This does not resolve all of the issues mentioned in the article (like the effect on our internal organs, childbirth and such), but can definitely target a bunch of externally accessible muscles to keep them from getting atrophied.
Perhaps this will be a cheap solution for those not living in the rotating megastructures. I should start collecting gold to be able to go sightseeing on the Moon.
No cheapo solutions for us plebs then. /me dumps all the platinum in the trash.
Yeah it would be like anchoring a balloon. Sure it's not going to float away but it's still a balloon. It's our internal jiggly bits that are important too.
For this I just have the right solution: extremely rich iron diet.
We had people on the ISS stay for a year.
I would also imagine the difference between zero gravity and little moon gravity to be quiet significant regarding keeping people healthy.
Will long extended stays be healthy? No but that is a problem for the far future. I think the focus now should be to get the basic logistics in order. I am sure there would be enough people that would be willing to participate in a mission to Moon even if it meant a shortening of their lifespan. Nothing about the first colonization attempts will be pretty but colonization has never been very pretty in human history to begin with.
Also unless I missed it, they fudged the part where the trains transition from the static tracks to the rotating structure. If so, that speaks volumes to their level of attention to detail.
Did anybody pick up what the lit up pit in the middle was supposed to be?
And that reason is the moon dust.
The moon dust is quite special as it is highly abrasive and sticks to anything because of the electrostatic charges.
It seeps though any gap and will wear down and render any mechanical machine useless in very short time.
Nothing soft (clothes, plastic) will survive on moon for more than few months.
The dust is a nightmare for anything non-moon and there is no help.
See one of the latest Real Engineering videos: https://www.youtube.com/watch?v=0k9wIsKKgqo
Dust buildup can be significantly decreased by weaving conductors throughout the outer shells and applying a current to it.
> Well, vacuum cleaners are a thing and could probably be exported to the moon to take care of any dust getting inside.
Specifically that last part.
They're the same statement once you think about it some or have some domain experience
What your comment seemed to suggest, was trying to preemptively remove all the dust.
Moon encampments need to be clean rooms with respect to the outside
It's a little like being underwater in a dome. If you see stuff from the outside inside, there's a dangerous leak.
Oh, except for that this dust kills you if you breathe it in, which water doesn't
Some of it stuck to the outside of spacesuits and/or robots when they went outside. Neither should be going beyond some intermediate garage area anyway, just like you don't usually park your car in the bedroom.
> And what's stopping the rest?
The airlock door? There's no wind on the moon, so it won't blow inside on its own.
> And where do you put what's captured?
Well, I'd assume that once your vacuum cleaners are full you'd take a moon-lorry and dump the lot into a nearby crater or something. If it's as sharp as advertised, the sharp edges might make it well-suited for use in concrete as well.
In any case you don't have to keep the entire moon clean, only the inside of the base. It doesn't seem to be a terrible burden to clean the suits and rovers after every expedition, more like something that you plan to do anyway because you want to keep those expensive things well-maintained.
Your assumptions about vacuum cleaners are fine. Do remember that it's sharp glass powder that immediately embeds, so that won't work
I see that you have imaginary beliefs about how much work cleaning is. NASA says differently.
Things that you guessed on the spot aren't interesting ways for you to argue.
It's not actually a valid comparison. Having water fall from the sky really changes the nature of rock dust
Dust on the moon is basically all what we would call obsidian glass dust (sharp) because it's made in asteroid impact craters
It is as if people in the West thinks the entirety of China is united on every decision, invention that comes out of every entity in the country.
https://www.youtube.com/watch?v=nxeMoaxUpWk
Before I watched the video, I didn't know the Soviet Union tested a (small) centrifuge for artificial gravity in space back in the 70s:
https://en.wikipedia.org/wiki/Kosmos_782
So a university and a corp = Japan now. Wow.
So next time Facebook partners with some academics, we can say "The US proposes..." ?