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NASA Moon

NASA Seeks Ideas For a Nuclear Reactor On the Moon (phys.org) 94

An anonymous reader quotes a report from Phys.org: NASA and the nation's top federal nuclear research lab on Friday put out a request for proposals for a fission surface power system. NASA is collaborating with the U.S. Department of Energy's Idaho National Laboratory to establish a sun-independent power source for missions to the moon by the end of the decade. If successful in supporting a sustained human presence on the moon, the next objective would be Mars. NASA says fission surface power could provide sustained, abundant power no matter the environmental conditions on the moon or Mars. The reactor would be built on Earth and then sent to the moon.

Submitted plans for the fission surface power system should include a uranium-fueled reactor core, a system to convert the nuclear power into usable energy, a thermal management system to keep the reactor cool, and a distribution system providing no less than 40 kilowatts of continuous electric power for 10 years in the lunar environment. Some other requirements include that it be capable of turning itself off and on without human help, that it be able to operate from the deck of a lunar lander, and that it can be removed from the lander and run on a mobile system and be transported to a different lunar site for operation. Additionally, when launched from Earth to the moon, it should fit inside a 12-foot (4-meter) diameter cylinder that's 18 feet (6 meters) long. It should not weigh more than 13,200 pounds (6,000 kilograms). The proposal requests are for an initial system design and must be submitted by Feb. 19.

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NASA Seeks Ideas For a Nuclear Reactor On the Moon

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  • NASA says fission surface power could provide sustained, abundant power no matter the environmental conditions on the moon or Mars

    Environmental conditions on the moon? Are we talking about solar winds or what? At least Mars has weather.

    • Re:uh (Score:5, Insightful)

      by trenien ( 974611 ) on Saturday November 20, 2021 @08:25AM (#62004687)
      Might be the problem of cooling the reactor, for instance : no atmosphere/water means no easily available medium through which exhausting heat. That's an environmental problem.
      • large radiator panels will work quite well in a vacuum.

        Your thinking in terms of terrestrial cooling where the heat is transferred to another working fluid, water/air and carried away.

        In a vacuum the heat would radiate away as infrared radiation as long as the panel is kept shaded from Sunlight. Note that it does not need to be insulated, just shaded, even a mylar sheet could do the job.

        Another option would be to use the ground as a heat sink, Some of the extra heat would could be used during the night.

        Re

    • Re:uh (Score:5, Insightful)

      by Geoffrey.landis ( 926948 ) on Saturday November 20, 2021 @08:46AM (#62004717) Homepage

      NASA says fission surface power could provide sustained, abundant power no matter the environmental conditions on the moon or Mars

      Environmental conditions on the moon? Are we talking about solar winds or what? At least Mars has weather.

      Temperature extremes, vacuum, plasma environment.

      The environmental conditions on the moon are very different from those of Earth.

    • Environmental conditions on the moon?

      If it goes critical and the containment vessel is breached, the slag could - possibly - melt the cheese.

    • d'uh Re:uh (Score:4, Informative)

      by theshowmecanuck ( 703852 ) on Saturday November 20, 2021 @09:48AM (#62004817) Journal

      You don't need an atmosphere to have an environment.

    • Sinking the waste heat is the first problem I see.

      The reactor from NR-1 would almost fit, but I doubt a steam cycle is what they have in mind. Building a steam generator (boiler) for 1/6 g would be an interesting exercise.

    • Daylight surface temperature are upwards to 260 degrees Fahrenheit (127 degrees Celsius).

      At night it gets to around minus 280 F ( -173 C).

      Add to that a hard vacuum, constant bombardment my atomic particles (Alpha particles are Helium atoms stripped of their electrons) and micro meteorite impacts. And lets not forget an incredibly fine dust that will get into and on everything.

      So yeah, the conditions on Luna are pretty harsh.

    • NASA says fission surface power could provide sustained, abundant power no matter the environmental conditions on the moon or Mars

      Environmental conditions on the moon? Are we talking about solar winds or what? At least Mars has weather.

      2 weeks long nights, extreme temperatures (-280F, +260F), extremely abrasive dust and additionally Solar activity - make the design quite challenging - hence "environmental condition".

      However just going down under the surface would make the temperature much more pleasant and close to the poles will allow for some erected solar panels permanent supply of electricity, yet I would prefer a backup anyway - preferably nuclear.

  • The reactor would be built on Earth and then sent to the moon.

    No, really...I'm glad they cleared that up...

  • by jfdavis668 ( 1414919 ) on Saturday November 20, 2021 @08:58AM (#62004737)
    If Martin Landau and Barbara Bain couldn't handle the situation, I doubt NASA will be able to. We can't afford to lose the Moon.
  • Time to get our duct tape space suits ready to go to save the colony.

  • NASA would be better if looking into Hypersonic technology.
  • by Gravis Zero ( 934156 ) on Saturday November 20, 2021 @10:21AM (#62004869)

    I'm not nuclear expert but I do know that a circulated heated liquid surrounded by thermoelectric materials would be very compact and generate lots of power. However, since both location go from crazy hot in the day to obscenely cold at night (thanks a lot, Sol!), you are going to want to fallback to radiating heat into rock. This probably wont be super heat conductive but it will be able to prevent the reactor from overheating and you know, melting down (generally an undesirable event). However, you should have a way to extract heat before it goes into rock for heating a secondary liquid loop. This could distribute the heat into water which is quite useful many purposes like humans consumption, water purification to recycle human waste, melting mined lunar water, and other things.

    • You can just have it obscenely cold all the time by parking in a crater at one of the poles. Does mean it wouldn't be that mobile, but you have to start somewhere.

      • Part of "no matter the environmental conditions" means it cannot be location dependent. Don't get me wrong, it's a solid solution to heat disipation but it's too inflexible to meet the requirements.

    • The temperature changes that much if they're exposed to sunlight. There are permanently shadowed regions, but they're far from the lunar equator and present additional landing difficulties.

      https://moon.nasa.gov/resource... [nasa.gov]

      • Part of "no matter the environmental conditions" means it cannot be location dependent. Don't get me wrong, it's a solid solution to heat dissipation but it's too inflexible to meet the requirements.

  • The Moon has ridiculous temperature changes over a for terrain exposed to sunlight. That does leave a lot of engineering issues to resolve for any installation, whether living facilities or a small nuclear plant or solar cells.

    Frankly, I'd look to orbital solar mirrors to provide consistent power, with the kind of beamed microwave power to ground stations suggested for solar powwer on Earth.

    • In fact, that seems like a 'no brainer'. But you don't need mirrors (which would be for ground-based solar), you need direct solar beamed to a lunar rectenna station.

      Because there is no selenostationary orbit possible (the required distance is beyond the Moon's Hill sphere, so the Earth and Sun would pull your satellite off course relatively quickly), you'd need multiple satellites... the number depending on their altitude, but under no circumstances will you get away with two and my uninformed gut instin

      • Putting up a network of solar satellites solves various problems for Earth power as well, without the confusion of coping with Earth shadows. It seems a no-brainer to allow the satellites in closer orbit, transmitting in phases to the ground stations.

      • The mirrors are concentrators are power collectors for the rectennas in orbit, I'm sorry if that was not clear.

        • The rectennas are energy receivers. You use them to convert the microwaves beamed from the satellites into electricity.

          You don't put rectennas in orbit, you put solar panels and a microwave beam generator in orbit.

          • Thank you for the correction, i used the wrong word. I wanted to be clear that the solar mirrors do require transmitters, they are reflecting to their local tmicrowave ransmitter rather than reflecting the power directly to the ground.

    • The surface of the moon is not consistently in sunlight so there will be a need for other power.
      • If ground based solar could be stored reliably and used efficiently, it might still be effective with only ground based equipment. Sending increasingly large masses of nuclear fuel beyond Earth's atmosphere should be a source of concern, even though putting it on a lunar base would seem much safer than leaving it in orbit where it might be more easily serve alternative uses.

        • Sending increasingly large masses of nuclear fuel beyond Earth's atmosphere should be a source of concern,

          Then mine the fuel on the moon, there's a lot of uranium and thorium on the moon, just like there is a lot on Earth. They'd still have to send up enough fuel to get them started but once the reactors are built and have a starter load of fuel the subsequent fuel can be produced on the moon.

          Solar power on the moon to sustain a lengthy manned mission is not practical. The Apollo missions had batteries and RTGs for two men a few uncomfortable hours on the moon. To supply a mission lasting days would take so

  • There have been nuclear reactors on the moon. Read this 4 page document: https://www.iaea.org/sites/def... [iaea.org]

    The cooling was done by radiation. We are well talking about nuclear reactor and not just radioisotope thermoelectric generators.

  • Build a molten salt Thorium fueled reactor with a thermoelectric (similar to Peltier junction) exchanger. Send it to the moon unfueled. Process lunar soil to extract Thorium which is *abundant* and fuel it on-site. They are inherently safe, cooling is not the same class of issue as it would be with a Brayton (steam) cycle Uranium reactor like the ones in use in the US today, the high heat output is useful as process heat for other operations a lunar base would require, and megawatt-scale SMRs the size of se
    • Process lunar soil to extract Thorium which is *abundant* and fuel it on-site.
      Thorium is not abundant. At least not in the sense the word is meaning.

      And if you want to process/produce it: your first exercise is to describe a chemical process how that can be done. I guess you will need "heat" and "water" and some "acids" ... good luck Padawan.

  • The GPHS-RTG (https://en.wikipedia.org/wiki/GPHS-RTG) produces 300 watts for 57kg. So 6000 kg of these would produce 31 kilowatts. But they are only asking for 40 kilowatts from a 6000 kg reactor? This does not seem like a good engineering tradeoff.
    • I concur.

      Plus the 57kg design was built 20+ years ago. We can do better now, at least in terms a weight. (We didn't even have 3d printing of metals then.) And we can probably do better on the heat watts to electrical watts now.

      And if we scale it up we should be able to reduce that further. it looks like they're designed to be stacked. Lunar rock/glass as part of the heat shield means we could produce part of them in situ, after the first completely earth-manufactured batch of them arrived and were got

  • All-in-one autonomous nuclear rocket lander Tesla Starpack StarLink station Amazon buy button for future expansion!

  • Fission needs cooling in all its from. Even an RTG needs cooling. Cooling on the Moon in this range may well be infeasible with current tech, because all you have is heat radiation. If they somebody makes this work, it will be a very interesting solution for sure, but my take is NASA does not want to admit they cannot do it and this is just an attempt at shifting the blame.

    • Already solved.

      The International Space Station generates about 100kwts of heat during normal operations.

      It's radiators handle the load quite well. Getting rid of waste heat in a vacuum is a lot easier than people think and NASA/JPL have been improving the solutions for this issue for decades. Give them some credit for knowing their stuff.

      • by gweihir ( 88907 )

        Have you looked at the size of the ISS compared to what NASA is asking for here? Obviously not.

  • If you heat a sterling generator with a solar collector (bunch of focused mirrors) and cool through the regolith them you should be able to very easily produce huge amounts of energy. And it's simple, crude, and inexpensive. Solar in space needs to be gallium arsenide, if it is to last.. expensive and limited power generation. Nuclear generates power through heat generation, usually to a steam engine. That's also very expensive...

    One could crudely assembly a solar collector using pieces of even a broken

  • Sounds like a Naval Reactor core?

Every nonzero finite dimensional inner product space has an orthonormal basis. It makes sense, when you don't think about it.

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