2. The rovers have a max speed of 500 meters a day, run out of power frequently(I'll mis you, Spirit) and are screwed every time a dust storm happens. Also shading increases energy absorbtion, so it doesn't help. It just increases overheating.
This came up the other day. Can't remember which rover it was (Sojourner, Spirit or Opportunity), but when one of them landed, the power it collected was (IIRC) 900Wh. Then the dust started to build up, and it fell, fell, fell, down to 350Wh. 250Wh would have been "death", they think. Then a wind came along and dusted the panels clean. And because of a more favourable elevation of the sun, at that latitude in that particular season, the panels actually produced more power than they had upon landing. They had to schedule an afternoon "siesta" for the robot to prevent the electronics from overheating, having now more than enough power to run the robot for far longer than they could actually make use of it for.
Anyway, this station has a guy with a brush stored in the airlock, if that's still a problem. And spare bits and pieces ready to be fixed if something like Spirit's semi-broken wheel happened to a bit of base equipment.
Spirit. In the end they ended up using the robot for astronomical observations at night to burn power.
As for the brush thingy, how are you going to brush away the dust in the athmosphere. It's not dust accumulation on the pannels that is the main problem(Though that forms a rather large energy and maintenance problem, as the dust is magnetic and tends to stick) but the fact that the sun is occluded by "fairly" frequent dust storms, which can remain in the atmos for up to half a year.
3. Orientation mechanics clash with the fact that the station has to rotate. This combined with a large size means that the pannels will suffer severly from centrifugal force. After all, in order to get decent efficiency you have to point your cilinder at the sun, and only use one layer of pannels (any next layer would just be shaded by the first) This means that they have to extend a long way from the station, hence enormous centrifugal force. They'll tear the station apart.
You're designing the station wrong. Even if you had to set your panels further out from the station, plenty of Earth structures withstand 1G, and can handle more. It's quite possible to ensure that you can make the station withstand the centrifugal or centripetal forces, as necessary, for quite a range beyond the 1g 'nominal'.
I'd set up a stationary solar array station in close proximity (to allow some form of Broadcast Power to be easily used and coordinated) and not bother spinning it, if it were actually troublesome (and I don't think it is) to attach most of the panels to the rotating wheel/cylinder/whatever...
The stronger you make the structure, the heavier it becomes. It's a sort of balancing act. And seperating the station from it's powersource will make manoevering quite problematic, though still possible.
The only thing angular momentum does is creating artificial gravity and allowing the spacecraft to maintain it's current heading. It doesn't supply any force to negate gravity. (If it did that, It would either need to slow down or be producing infinitive energy)
I sort of understood where you were at with your original response here. I thought you'd probably misunderstood what was meant (i.e., you can move space-stations around, doesn't need to be stuck in LEO at all), but where you're going with what you just said, I don't really know.
Are you, perchance, conflating the angular momentum of the station's own frame of reference ('artificial gravity', by way of applying centripetal force to the soles of those standing inside the wheel) with the angular momentum of the station travelling in whatever orbit/freefall path it is currently instanciated in?
You don't get it -- a space station with angular momentum need not be in orbit around anything. It can go anywhere and be anywhere
This quote, and previous conversation, led me to believe that he thought that angular momentum would just negate any other gravitational influence and allow the station to just fly wherever it wants without significant energy expenditure.
I get the idea you have no bloody idea what you're talking about.
I think, perhaps because you're misunderstanding things that I think I understand, but that you're seemingly interpreting quite differently, I'm perfectly entitled to fire that statement back at you. However, I'm going to restrain from saying that you misunderstand your understanding, because there may still be more confusions at my end, regarding one or more bits of what I've snipped...
It wasn't directed at you.
There isn't any free oxygen on mars, so any combustion requires twice the fuel mass per watt-hour,
Erm.... Combustion would use the same fuel, but need to be supplied more oxygen. There's 0.13% Oxygen on Mars, IIRC, compared to nearly 21% on Earth, so you'd need to concentrate that oxygen to anything up to 160 times what it normally is. Or less, if you can feed it faster without removing the "heat" third of of the "fire triangle".
I think you forgot to account for the fact that Mars atmos is only 0.6% as dense as Earths.
Nuclar batteries would be a sensible option, and these have been proven as a reliable and safe option on many, many space missions. Make them on Earth, in orbit or the Moon, and send them to Mars. Or send them down our space elevator - more on that below.
By "Nuclear Batteries", you mean Radiothermal Generators, yes? I'm not sure they're quite as good as straight fission (or possibly available fusion) power generation plants.
IIRC, the devices so far rarely reached more than a few tens of Watts each. (There was one which was an actual reactor at the core of the thermoelectrical jacket, which was quite powerful, though. A few kW. But I'd consider a standard reactor/turbine concept a bit more efficient, with the inevitable maintenance problems surely improved by future developments. There's probably an intermediate step that's better though. What's that Thorium concept supposed to be again?)
The largest scale use of Radiothermal reactors that I know of are some lighthouses in the polar circle. Furthermore, a thorium reactor is identical to a conventional one, with the exemption that it runs on Thorium instead of uranium. This results in less nuclear waste and less meltdown risk(Thorium has a much lower metling point)
There is some civilians [Fusion generator] prototypes running, and an important test plant should be finished in 2020 (including already 3 years late). Lots of prototypes are running since years, even though they're mainly about testing, potential uses, and not much about energy production.
And it's already used since decades in military devices.
Wut? I've not heard a thing about fusion power, civilian or military, having been "in use" at all. They've got various machines where, for a few milliseconds or so they can pump in a huge amount of power and momentarily get... well, I'm not even sure if they've broken even, just yet, but a (not so?) huge amount back for just that moment, straight from the fusion (or from the heat generated, or something)... But they're a long way from being self-sustaining.
Unless I've been asleep and missed something.
Iter should have a break even, and I believe they reached one at the National Ignition facility last year. For now, all fusion energy reactors use more energy than can be recovered from the heat they produce.
Well, unless you give me an exemple of something that can threaten a Earth base, yes, I'll consider you as an uninformed pessimist who like space. And war ain't it. Just dig deep enough, keep the location more or less secret. If there is anything that can threaten you, humanity is advanced enough they don't need your help.
"Just dig deep enough." Yes, self-sustaining underground bases are so cheap and easy...especially housing 2-3,000 people. How deep is it before it starts costing as much or more than a Lunar base to build and keep alive? (Hint: A Lunar base could be built for a "mere" $35 billion; I calculated that, under ideal circumstances and assuming solar panels of merely 15% efficiency, and putting a $50-60 billion price tag on the whole thing, exporting solar power to Earth at well below market price repays that in weeks. Solar power alone.) That's not good for ya? Ignoring environmental issues as good problems, too? How about political crap? That could be more devastating than a war. If, for example, you put this hypothetical, expensive, base in Alaska, and after a war Russia annexed Alaska, what happens to the base? Even if this is unlikely, consider the basic concept: As long as a base is on Earth, it is susceptible to Earth-based attacks. Don't buy that, either? Somehow you've made it immune to every kind of attack known to man? Seismic events would ruin your base. They're not much of a problem for a Lunar base near the surface, but an underground base hit by an earthquake would probably risk caving in. Still not good enough? What did you use to get down there? Your seal on the door had better be pretty good, or your little base is going to get water trickling in from rain or melting snow, assuming that the aquifers in the area are nonexistent or properly sealed. Too improbable? How about your settlement breaking down because you're always a mile or several underground, with no chance to have fresh air, see the stars, or even be in a relatively open area? (A lit dome a couple hundred feet across might help, while rendering it more vulnerable to attack or earthquakes.)
Not good enough for you? Gimme a bit.
I'd really like to see to see those calculations. Did you account for occlusion by moon dust, maintenance cost, launch costs, development costs, transmission losses and costs(largest obstacle, for example microwave requires you to evacuate a large part of Earth's sattelite network). I posted some calculations earlier in this or on another thread about orbital solar power production, and even with high efficiency low weight pannels, constant exposure, no maintenance and optimistical transmission costs, it was unlikely they'd ever get out of the costs. Considering launch costs (majority of the problem) to the moon are several (10 times or more) higher than to LEO (which isn't even a good place to place solar power, but I was giving them the benefit of doubt) I doubt you'd make a profit that easily.
-Solar flare: Survivable, and a Martian colony will be hit much harder than Earth.
Isn't Mars farther away from the Sun? And wouldn't a Martian base presumably be built with a temporary radiation shelter for stuff like this?
I was talking about an semiapocalyptical flare. The oh god, everything electronic is death kind. Or more positively, the aurorae equatorialis kind. Mars has no magnetical field, and the mars colony will most likely have less reserve supplies to replace stuff.
-WWIII: You really think that an off planet colony will be able to maintain neutrality? After all, an offworld location is one of your best assets to break the MAD stalemate
I can't imagine an offworld base being worth the resources it takes to attack, let alone the time. Enemy missile stockpiles and such are much bigger threats, and don't require you to lift nukes into space to attack them. Also, you're assuming that the colony is built by a government. Why would Russia, the US, North Korea, or anyone waste resources on, say, an AT&T base on the Moon when they've probably got a dozen or more Terran threats to nuke?
Any governement is not going to let you build a colony without infiltrating it. Especially in a cold war type scenario. Sure, nobody is going to attack it during the war, but it will be forced to take on allegiance before. Especially if there's a chance of humanity nuking themselves into extinction.
And besides, the requirements for a fully, completely autonomous colony are enormous.
Define "fully, completely autonomous." Once you have food, water, oxygen, shelter, and power, it seems you're mostly set. The first three can be mostly or entirely solved by greenhouses; shelter and power should be obvious.
Complete, high tech industry capable of producing parts to replace anything that fails. Medical infrastructure capable of making new medicine. Political structure and police system capable of sustaining the society. Basically, everything on Earth, pocket edition. Some way to resolve the oh god we're alone in the universe feeling.
Solar and wind power aren't enough for humans needs, as for the low production, and for the variability (because, you don't use the same amount of energy sleeping, the morning, the evening, night, etc).
Nice thing about non-Earth areas, they have acres to burn. Dust and low atmospheric pressure are still issues, but a bit of labor (maybe brushing off the panels once a week?) and using lots of windmills as a backup only can help compensate.
You're pannels won't be so nice to get dusty in one before the other. What really happens is that first you get a dust storm, severly reducing power while you can't do anything (What'd you going to do, brush the atmosphere?) and then wind settles and dust starts to rain down on a large part of the pannels. Secondly, magnetic dust. It sticks to the pannels, meaning specialized brushing equiptment.
Thirdly, wind mills are absolutely useless. Even at best times the wind is the equivalent of a slight breeze, and the martian conditions are merciless for rotating parts. My guess is that you'll end up spending more power on keeping the windmills heated to prevent them from breaking due to the temperature shifts than you'd ever get from them.
Also, one strong flare and your entire energy netword is fried, as there are no protective magnetic fields on Earth. And reinforced circuits ain't going to help you. The cost would simply be to large to bear.
Don't bet on fusion. I'm reminded of a quote about stem cells: They're 20 years away and always will be.
The fusion constant is actually 40 years, not 20.
Hydrogen bomb.
For civilians project, there is some reactors, most of them being built in 80s, for testing and application purposes. The ITER, which would technically work the same as a plant (but for thermal tests, mostly) is being built.
For others military projects, there is some lasers that are being built to improve the atomic/nuclear bombs.
The + (for electricity plants) :
No radioactivity
3 to 4 times more energy than actual nuclear plant
Easy to find fuel (˛H)
The - :
Need a lot power to actually start the reaction (i.e. atomic bombs are detonator for hydrogen bombs)
There's probably some other things, but I'm not an expert (or maybe we didn't discovered them yet)
The only reason the hydrogen bomb comes out positive is because you want to produce heat (so a 100% recuperation efficiency), and because the fusion stage is actually used as a trigger for the ternary fission stage.
Secondly, fusion plants are still radioactive. They just don't produce radioactive waste. The reaction does produce errant particles, which have to be stopped. This also causes lot's of wear on the inner reactor plating. Second gen fusion would mostly solve this, as electricity is litteraly a product of the reaction.
While the primary fuel is easy to find, both tritium and He-3 are extremely hard to find. The first can be made in labratories and in the reactor itself, but it still increases costs.
Other problems with fusion is the fact that they have to be extremely large scale, operate a ludricous temperatures* and cost a lot.
*The main point of the Iter is to test if the design can actually resist the heat.
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Topic: Humans, and eventually a colony on Mars. (Read 66473 times)