A lot (all) nuclear accidents also occurred with older reactor designs.
Traditional nuclear reactors were designed in such a way that they required management to keep the reaction from running away. The reaction itself was self-sustaining and therefore the had to be actively moderated to stay inside safe conditions. If something broke, or was mis-managed, the reaction had a chance of continuing to grow out of control. That’s called a melt-down.
As an imperfect analogy, older reactors were water towers. The machinery is keeping the water in an unstable state, and a failure means it comes crashing down to earth
Newer reactrs are designed so they they require active management to keep the reaction going. The reaction isn’t self-sustaining, and requires outside power to maintain. If something breaks or is mismanaged, the reaction stops and the whole thing shuts down. That means they can’t melt down.
As an imperfect analogy, newer reactors are water pumps. If power is interrupted nothing breaks catastrophically, water just stops moving.
Correct me if im wrong. I think most of the fears come from positive void coefficient reactors which some of the older reactors have like the RBMK which Chernobyl had. Unlike today where they are negative void coefficient.
You’re correct, but the two groups that are anti nuclear are Boomers and The Greens parties.
Boomers are easy, they grew up with a few nuclear incidents, including reactor issues as well as the USSR stuff.
The Greens is paradoxal, youd think they were pronuclear, at least in the interrum. But they are anti nuclear because of a variety of reasons. So you see situations like in Germany recently where the Greens forced the government to get rid of nuclear reactors, and in their place, comes more Gas reactors… Greens want 100% renewable, but don’t seem to understand that they should be fighting for 0% fossil first … then when that’s obtained go for 100% renewables.
Because every time you remove a nuclear reactor, the only firm power replacement is a fossil fuel reactor.
I say this as a lifelong Greens voter, my political party have a small, and vocal group of idiots.
(In case you’re wondering, yes the anti nuclear Greens are usually boomers)
I’m one of those guys. I voted to ban nuclear here in 2017.
I absolutely would love to put 0% fossil before 100% renewable. But as long as nuclear was a choice little more than token efforts were made to expand renewable capacity. Then we banned it and suddenly solar installations are sprouting like mushrooms. Before the ban we put in 330MW per year. The increase in the increase in solar was this much last year (670->1000MW)!
This month we had another vote in a climate bill and as soon as that was accepted the regressives came out and called for more nuclear and complained how all that solar and wind is going to ruin christmas the landscape. I’d love to have renewables AND nuclear but somehow it always ends up being an OR…
Just to be clear: This isn’t an attack on pro-nuclear folks. I get your point and in theory you’re right. I just never seen it put into practice…
the installed capacity is a nice number but unless you also install batteries AND take capacity factor into account, you’re replacing load following dispatchable generation with intermittent ones that is backed by literal fossil fuels
I mean just look at the carbon intensity of a German kWh
Hi! I’m a nuclear engineer. I just wanted to do a small drive-by clarification/lecture.
There are a lot of feedbacks that are considered when designing a nuclear reactor, it’s not just a single void coefficient. There are thermal feedbacks, feedbacks related to the decay of fission products, feedbacks related to the burnup of fuel, the burnup of the neutron poisons, the activation of the water in the primary loop, etc etc. When designing a nuclear reactor, all of these effects must be examined. Generally, this involves finding the transfer function and confirming that all the poles of the transfer function have real part less than 0. (This is where the “negative” part comes in, they’re complex numbers in general, but as long as the real part is less than zero this corresponds to a decaying exponential.)
An aside on criticality. We are quite fortunate in that due to a quirk of nuclear physics, fission reactors are possible. We call the time difference between one fission and the next from the neutrons produced a “generation.” If we had to react on the timescales of a “generation” based on the simple model where one fission leads directly to another, then we’d have to react in milliseconds, and this just wouldn’t be possible to make a reactor safe, even with an extremely well designed system of feedbacks. However, some fission products will decay and release a neutron, these so-called delayed neutrons make controlling a nuclear reactor on human time scales possible (minutes and hours instead of milliseconds), and it makes these feedback loops far more stable. So we aim to keep the criticality below 1 for “prompt” neutrons, and slightly above 1 for delayed neutrons, then we rely on the feedback systems (primarily thermal and fission products) to keep the criticality oscillating very slowly around 1.
For specifically Chernobyl, there is a more broad idea that we concentrate on in reactor design, that of overmoderation vs undermoderation. Reactivity has a relative peak at a particular amount of moderation, and we want to design the reactor in such a way that it can never get more moderated than that peak, because that would give a positive feedback loop if increasing the power led to a concomitant decrease in moderation (which is normal, the density of liquid water decreases with increasing temperature). Because Chernobyl was graphite moderated and steam cooled, we had an especially bad case of this where the core flooded and was massively overmoderated, and in order to get the water out of the core they attempted to turn the reactor all of the way up and boil it out, but in doing so this caused the reactivity to go massively supercritical as the moderation was reduced from absolutely smothering the reaction to just right. It was so supercritical that it was supercritical only with the prompt neutrons, so-called prompt supercriticality, which is why you read things like the power went up 1000x in a second.
The United States does not, and did not even at the time, allow certification of designs where it is possible for this to occur. All reactors must have negative reaction coefficients for all major feedbacks in all operating scenarios, and, in fact, due to this stringent process there are only 4 reactor types that the NRC has currently certified for new nuclear reactors (with 3 more currently under review), (and each design has to be certified jointly with the location where it will be built, so something like Fukushima, where the backup generators are in the basement in a flood zone, would not pass certification review in the US.)
Anyway, I hope this was interesting and educational.
A lot (all) nuclear accidents also occurred with older reactor designs.
Traditional nuclear reactors were designed in such a way that they required management to keep the reaction from running away. The reaction itself was self-sustaining and therefore the had to be actively moderated to stay inside safe conditions. If something broke, or was mis-managed, the reaction had a chance of continuing to grow out of control. That’s called a melt-down.
As an imperfect analogy, older reactors were water towers. The machinery is keeping the water in an unstable state, and a failure means it comes crashing down to earth
Newer reactrs are designed so they they require active management to keep the reaction going. The reaction isn’t self-sustaining, and requires outside power to maintain. If something breaks or is mismanaged, the reaction stops and the whole thing shuts down. That means they can’t melt down.
As an imperfect analogy, newer reactors are water pumps. If power is interrupted nothing breaks catastrophically, water just stops moving.
Correct me if im wrong. I think most of the fears come from positive void coefficient reactors which some of the older reactors have like the RBMK which Chernobyl had. Unlike today where they are negative void coefficient.
You’re correct, but the two groups that are anti nuclear are Boomers and The Greens parties.
Boomers are easy, they grew up with a few nuclear incidents, including reactor issues as well as the USSR stuff.
The Greens is paradoxal, youd think they were pronuclear, at least in the interrum. But they are anti nuclear because of a variety of reasons. So you see situations like in Germany recently where the Greens forced the government to get rid of nuclear reactors, and in their place, comes more Gas reactors… Greens want 100% renewable, but don’t seem to understand that they should be fighting for 0% fossil first … then when that’s obtained go for 100% renewables.
Because every time you remove a nuclear reactor, the only firm power replacement is a fossil fuel reactor.
I say this as a lifelong Greens voter, my political party have a small, and vocal group of idiots.
(In case you’re wondering, yes the anti nuclear Greens are usually boomers)
I’m one of those guys. I voted to ban nuclear here in 2017.
I absolutely would love to put 0% fossil before 100% renewable. But as long as nuclear was a choice little more than token efforts were made to expand renewable capacity. Then we banned it and suddenly solar installations are sprouting like mushrooms. Before the ban we put in 330MW per year. The increase in the increase in solar was this much last year (670->1000MW)!
This month we had another vote in a climate bill and as soon as that was accepted the regressives came out and called for more nuclear and complained how all that solar and wind is going to ruin
christmasthe landscape. I’d love to have renewables AND nuclear but somehow it always ends up being an OR…Just to be clear: This isn’t an attack on pro-nuclear folks. I get your point and in theory you’re right. I just never seen it put into practice…
the installed capacity is a nice number but unless you also install batteries AND take capacity factor into account, you’re replacing load following dispatchable generation with intermittent ones that is backed by literal fossil fuels
I mean just look at the carbon intensity of a German kWh
Switzerland imports so much of it’s energy I don’t think it matters much yet. When it starts to matter we have huge hydro dams we can use for that.
Hi! I’m a nuclear engineer. I just wanted to do a small drive-by clarification/lecture.
There are a lot of feedbacks that are considered when designing a nuclear reactor, it’s not just a single void coefficient. There are thermal feedbacks, feedbacks related to the decay of fission products, feedbacks related to the burnup of fuel, the burnup of the neutron poisons, the activation of the water in the primary loop, etc etc. When designing a nuclear reactor, all of these effects must be examined. Generally, this involves finding the transfer function and confirming that all the poles of the transfer function have real part less than 0. (This is where the “negative” part comes in, they’re complex numbers in general, but as long as the real part is less than zero this corresponds to a decaying exponential.)
An aside on criticality. We are quite fortunate in that due to a quirk of nuclear physics, fission reactors are possible. We call the time difference between one fission and the next from the neutrons produced a “generation.” If we had to react on the timescales of a “generation” based on the simple model where one fission leads directly to another, then we’d have to react in milliseconds, and this just wouldn’t be possible to make a reactor safe, even with an extremely well designed system of feedbacks. However, some fission products will decay and release a neutron, these so-called delayed neutrons make controlling a nuclear reactor on human time scales possible (minutes and hours instead of milliseconds), and it makes these feedback loops far more stable. So we aim to keep the criticality below 1 for “prompt” neutrons, and slightly above 1 for delayed neutrons, then we rely on the feedback systems (primarily thermal and fission products) to keep the criticality oscillating very slowly around 1.
For specifically Chernobyl, there is a more broad idea that we concentrate on in reactor design, that of overmoderation vs undermoderation. Reactivity has a relative peak at a particular amount of moderation, and we want to design the reactor in such a way that it can never get more moderated than that peak, because that would give a positive feedback loop if increasing the power led to a concomitant decrease in moderation (which is normal, the density of liquid water decreases with increasing temperature). Because Chernobyl was graphite moderated and steam cooled, we had an especially bad case of this where the core flooded and was massively overmoderated, and in order to get the water out of the core they attempted to turn the reactor all of the way up and boil it out, but in doing so this caused the reactivity to go massively supercritical as the moderation was reduced from absolutely smothering the reaction to just right. It was so supercritical that it was supercritical only with the prompt neutrons, so-called prompt supercriticality, which is why you read things like the power went up 1000x in a second.
The United States does not, and did not even at the time, allow certification of designs where it is possible for this to occur. All reactors must have negative reaction coefficients for all major feedbacks in all operating scenarios, and, in fact, due to this stringent process there are only 4 reactor types that the NRC has currently certified for new nuclear reactors (with 3 more currently under review), (and each design has to be certified jointly with the location where it will be built, so something like Fukushima, where the backup generators are in the basement in a flood zone, would not pass certification review in the US.)
Anyway, I hope this was interesting and educational.