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  • From a technology standpoint, there's not too many greater challenges than nuclear power

  • in space.

  • The physics involved in it is quite intenseit has that luster of something totally

  • different.

  • We start with that highly enriched core, the splitting of the atoms generates that heat

  • that we need at the right power levels, at the right temperature levels, and then we

  • transfer that heat up to the power conversion system.

  • You convert that to electricity at that engine, reject some of the waste heat, and then use

  • the electricity for whatever you're trying to power, whether it's a coffee maker or a

  • very expensive instrument for science.

  • It sounds pretty simple because it kind of is simple.

  • It's just the engineering pieces aren't always simple.

  • Nuclear energy and space flight have a deep history that stretches all the way back to

  • the Cold War.

  • At the time, scientists were looking for new ways to harness the power of the atom, and

  • nuclear offered something special for deep-space missions.

  • We don't have to rely on the sun.

  • When we go out in deep space or whether we're in a shadowed crater on the moon or whatever,

  • we've got our own energy source.

  • That's the biggest plus.

  • The secondary piece of that is the amount of power that energy can provide.

  • Fission power is very, very high on the power density scale.

  • As a quick refresher, nuclear fission releases heat energy by splitting atoms, and fusion

  • combines two lighter atoms into a larger one.

  • They both release an enormous amount of energy, but scientists found fission easier to control

  • for space missions.

  • To tap into nuclear's potential, NASA launched a research program called SNAP.

  • This kickstarted the development of radioisotope thermoelectric generators, which use plutonium-238

  • and thermocouples to convert heat into electricity.

  • These units have been on a number of famous missions like Curiosity, Cassini, Pioneer,

  • and even Voyager 1, which is currently cruising on RTG power 21 billion kilometers away from

  • us.

  • The program also developed SNAP 10A, a fission reactor that's considered the U.S.'s first

  • and only known nuclear space reactor.

  • It took off in 1965, failed after 43 days into the mission, and will be orbiting Earth

  • for another 3,000 years.

  • All subsequent nuclear space programs, like NERVA, which looked into nuclear powered rockets,

  • were shuttered or just didn't get off the ground.

  • Now, given, they were working on bigger power systems, which was part of the problem, I

  • think.

  • But, they were also chasing materials and processes and things that weren't available

  • at the time.

  • Today, nuclear power systems are seeing a comeback, and that's thanks to new mission

  • targets.

  • When we start talking about putting men on the moon in 2024 or on Mars in the 2030's,

  • you need a lot more power.

  • That's where fission really kicks in.

  • Kilopower, is one to ten kilowatts of electrical power.

  • That's starting with the fuel source.

  • It's uranium, molybdenum alloy fuel.

  • Highly enriched.

  • We have sodium heat pipes that are attached to that core.

  • That sodium heat pipe carries that heated vapor up to the Stirling power conversion

  • system, and then we have to cool the cold side of the engines to get that temperature

  • difference that we need for that power conversion and keep the engines from overheating.

  • The other pieces of the reactor that are, obviously, very important are the neutron

  • reflector.

  • That helps direct those neutrons back into the core and keep that chain reaction going

  • at the power levels that we need.

  • Before operating this, we have a poison rod inside the center of that core and then, when

  • we get to our destination we have a mechanism that would pull that rod out, make sure that

  • those neutrons will not be absorbed anymore and they can start the actual chain reaction

  • that we need.

  • One of the biggest attributes, I think, to the success of this program was that we kept

  • everything very small.

  • And, we're looking to make it as lightweight as possible.

  • Once the design was approved by NASA, the system and the people behind it were shipped

  • off to Nevada for testing.

  • KRUSTY was the experiment, which stood for Kilopower reactor using Stirling technology.

  • That experiment was really a follow-on to the Duff experiment, a demonstration using

  • flat top fissions.

  • Los Alamos, typically, or always likes to name their nuclear experiments after Simpsons'

  • characters.

  • We run through all those mission scenarios, where we would turn off the cooling to the

  • whole top end of the power conversion system and see how the reactor reacted.

  • And then, how we could really mess with them and see is it going to be a stable controlled

  • reactor.

  • The experiment culminated in a 28-hour test, from reactor startup to shutdown.

  • It operated at 800 degrees Celsius and produced over 4 kilowatts of power.

  • The highest power nuclear mission we've ever completed was Cassini, that had 870 watts.

  • So, already our lowest is already higher than any mission that's ever been done.

  • We did things to that reactor that you shouldn't do to a reactor, but it was really neat the

  • way it handles.

  • From concept to test was about three and a half years.

  • That's a real quick timetable.

  • To me, that's the most impressive piece.

  • Me and one of my buddies down at Marshall, as we were cleaning things up afterwards.

  • You know, the thousands of CAD models that we had and the information that was generated,

  • we're like, how did we do all that work?

  • I'm like, I don't know.

  • Some days, I don't know.

  • We worked a lot of hours and just had a lot of passion.

  • The fact that it worked really well was just a bonus.

  • This was a major step in demonstrating nuclear power's feasibility in the new space age,

  • but there are still hurdles ahead.

  • The real challenges are really political and how we develop all the safety and security

  • pieces to launching a nuclear system.

  • There's a whole lot of work related to making sure that there's no way you accidentally

  • start that reactor up.

  • And then there's what we call the launch safety piece, which also has a criticality accident

  • associated with it, so if the launch vehicle fails, and it falls into the ocean or on a

  • beach or in the general public, we have to show that it's not going to turn itself on.

  • Political will might be in favor this time.

  • Congress recently passed a bill earmarking $100 million for NASA to develop nuclear thermal

  • rocket engines.

  • So a future of fission, for both propulsion and power, is looking ever more promising.

  • We've just finished some studies with JPL on how we use this for what we call nuclear

  • electric propulsion.

  • So, you couple our reactor with an electric propulsion system and we can go do deep space

  • missions, carrying much higher payloads, faster times.

  • We've got design concepts that couple four of those to give us forty kilowatts electricity

  • on one lander that now you can use for your human habitat.

  • Once we improve the technology and it's available as a power source, you'll start to see some

  • really neat propulsions on what they can do with that extra power.

From a technology standpoint, there's not too many greater challenges than nuclear power

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NASAの新しい宇宙用原子炉は核分裂を動力源とする (NASA's New Space Reactor Is Powered by Nuclear Fission)

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    林宜悉 に公開 2021 年 01 月 14 日
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