The Uncertain Future of Nuclear Power

the most American fault condition ever!

@@phileas007 😂😂😂

I thought he was joking for a moment... Then I realize, this is Real Engineering, not Half as Interesting

That actually IS the joke. 😅

Had exactly the same thought 😂

Remember in "the simpsons" that homer's plan whenever there is a big security problem is to just throw water into the control panel so that there is a shortcircuit and the automatic emergency system takes the control of the nuclear plant😂😂😂. When i was a kid i didn't understand how he had so much luck. Now I realise it is thanks to the engineer who designed the safety system😂

To me, the most frustrating thing about the Three MIle Island incident is how it has created generations of "The sky is falling!" panic about nuclear power.
There have been fewer deaths from nuclear power, worldwide, than in too many single dam failures, some chemical plant leaks, and many ferry sinkings.
The deaths from nuclear power are not even a speck of dust on the graph of deaths from coal power generation.

If only the entire world focuses on how to mine deeper efficiently and faster to bolster the global production of the cleanest energy source possible which is geothermal

@@MonkeyJedi99by luck alone. Chernobyl could have wiped out the whole of europe

@@callummcneill6266 It was a meltdown, not a bomb.

This made me pause the video and read about Helsinki's underground city. Incredible

@@drewcipher896 just lek mi

Another video for realengineering to do!! 😍

Humans vs nature isn't the issue with nuclear waste. Yet another example of a complete misunderstanding of the issues at play.

South-west Australia isn't an option because the area is a known biodiversity island, where a large number of the flora/fauna can only be found there.

It's not even just that the design was not suitable. It's that it was 100% known and they were told about it every step along the way, but they ignored it and actively covered up any mistakes and accidents.

“Boss the fastest way is pump sea water nearby to spray the reactor”
"sea water corrodes the reactor! Our company can't afford that lost, think something else"
"but Boss-"
kaboom

The most frustrating part is the nuclear industry itself. They have a record of negligence, secrecy lies and cover-ups. Nuclear power gets a free pass because it provisions the Western nuclear arms race - as it always has - with raw materials and expertise. It also gets a free pass because the rich and powerful arms and power companies will discredit and eliminate politicians and anyone else that get in their way.

@@shadowmistress999 LOL

This is the main reason we are opposed to nuclear in all forms. We don't trust any humans with it. The people who designed and built it don't live next to it when it fails.

Salt has a higher temperature and it requires much better materials and steel, otherwise the reactor will quickly deteriorate. Well, imagine that the steel after hardening is kept at a temperature of about 300 degrees so that its internal stresses disappear and it becomes softer. And when using salt, the operating temperature can be above 300 degrees.

Great encapsulation of just one of the problems with nuclear energy! I see nuclear energy as a very poor expediency while we develop energy storage (batteries) that will make renewables the predominant energy source on the planet.

@@itsmatt2105 Except that batteries now are still decades or centuries away from being viable sources of energy through renewables, considering that they would have to replace coal/oil/nuclear as baseline energy production for the grid. That's not even taking into account the limited geographical applications of renewables, the environmental destruction from material sourcing, energy cost for cooling the batteries, and complications with recycling the batteries that make them extremely inefficient at scale.
Nuclear is definitely the most efficient system in terms of energy density per cost and safety for baseline power grid loads when you consider the engineering designs of gen 3 and 4 reactors. SMR's and microreactors are going to be the standard by the end of the 21st century.

@@itsmatt2105 Until some mega genius invents a battery that can safely store a small nuclear bomb's worth of energy in a space no bigger than an energy drink can i'm afraid renewables will never be a replacement for the energy density of nuclear power.

Being in liquid form does make reprocessing a lot easier though. Because those solid fuel reactors only "burn" about 1% of the fuel: a molten salt reactor may be able to dramatically reduce the amount of material handling. My guess in on the order [of] 90% (since you are moving the same material more than once to some extent).
I agree that the non-proliferation treaty is a significant barrier. With solid fuel it is a lot easier to audit the controlled substances by counting pellets. Liquid fuel is not really "countable".

Absolutely this, disappointed at Real Engineering for not considering the actual engineering reality here. Stored nuclear waste has never harmed anyone. Not only are the storage casks extremely safe as @maxwyght1840 describes, but also the material itself is not that dangerous. The radioactivity of nuclear waste decays exponentially: so within a thousand years it'd be safe enough to hold it in your hand (with gloves on, it's still chemically bad for you). By comparison fossil fuels kill millions every year due to air pollution. Every tonne of uranium produces 13Kg of high level waste which is safely contained and stored. The same amount of energy from coal releases 600Kg of mercury, which it throws into the air and leeches into water ways from ash piles. Radioactive waste will be largely safe in a few thousand years, mercury will be poisonous forever and it notoriously bioaccumulates up the food chain. People perceive that nuclear waste is very dangerous .. but the reality is that it's actually the safest form of energy waste we have. It doesn't matter that it's quite toxic, it's safely contained and it is containment that *actually* matters here.

And a big portion of those casks are filled with contaminated PPE and medial waste not spent fuel. We'll still need them even if we start recycling fuel.

The only thing they haven't done yet is drop a nuke on it XD

Mine are dangerous

Ocean dumping too is very safe. Divers have taken Geiger counters down there and didn't get any reading outside of waste barrels from the 1950s worse than an airplane, only on the soil directly below it (but only for a few inches out).

Speeding tain versus dry cask is the only time the train loses.

With the same confidence as the operator of the Titan sub.

Guy that invented adding lead to car fuel drunk lead to show it's not harmful (he knew that's a lie). He was very sick for few years, and never fully recover, but he "prooved" his point and whole world was severily poisoned for 100 years by leaded fuel. He earned a lot of money tho, and GM even more.

@@cherriberri8373 Was looking for that ahha. Hopefully he makes another video addressing that. Again misinformation being spread.

@@ynemey1243 there is literally a video of a train hitting one of these casks and the train lost. Also, we take countless radiation surveys around the casks and find they are no danger to anyone near them

It's better than air, at least.. the other most-available fluid xD

And water is super abundant, so we cat get a lot of it for cheap.

​yeah this video is full of small and a few worse errors unfortunately :(

@@adfaklsdjf Well, why would you use fluids at all over solids? because you can use convection with a fluid. And once you have convection, conductivity plays a minor role. Keep the pumps running and than the most important thing is the specific heat capacity and there water is great.

@@ma_nu yeah I felt the reason to use fluid coolant was kind of obvious.
it doesn't invalidate the original comment's point that water's conductivity isn't great.. but I felt another comment worded it a bit more charitably in a "I think you meant to say ___" framing

wait what... how... what retard thought that was a good idea? having direct connection is one of the most basic safety features you can have on any system.

RUclips doesn't have appropriate reaction buttons for this so I'll verbalise it...
WHAT THE ACTUAL FUCK MAN!!!
I work in rail safety and that sort of crap was designed out a century ago. Modern Computer Based Interlockings show 3 primary indications, effectively green or red, and white for when field objects are at variance with operator inputs with a few more to indicate specific failure modes.

@@mulgerbillAlso an electric throttle valve on a car has redundant position sensors…

The Western Provinces in Canada have also signed an agreement to develop multiple government funded SMRs across the prairies.

good to know.. thank you.

Maybe they weren't included because of not keeping up in the race. Their website only shows rendered images and not much of how they will going to achieve technical challenges.
There are many "partially" government funded SMR projects, not much of them will going to make it to the finish line without more stable investment.

​@@dongleseon8785uk has no expertise left bro the industry and experties left uk a generation ago even before that uk was not a reliable player

Rolls Royce are the same amateurs, at best, these SMR projects will be simply expensive and not very economically profitable.

There's a fascinating story there. Do you plan to publish?

Well, nevertheless, the HBO is filming series not about its accident at Heysham 1 2018 or Windscale Fire, not about Fukushima, but about Chernobyl.

Yes, that points to an inherent problem with nuclear though, doesn't it? Because greed and human stupidity are very, very common everywhere. It is no good saying that a plant designed and run by thoughtful competent people is safe because if you go building thousands of them I can guarantee that some will not be designed and run by such people.

@@kenoliver8913
That's an issue that can be solved by NOT privatizing our power grid in an effort to line the pockets of the privileged few.
Also, greed is NOT an inherent problem of nuclear power unless you consider human green an inherent problem for ALL power generation. The ultimate consequence of a meltdown is indeed the worst possible outcome, but if we are going by total numbers of people killed because of greed, coal leads the way, and it's not even close.
Attacking nuclear power while we are still burning fossil fuels is like lecturing someone for eating processed foods.... while you shoot street heroin.

@@CanadaMMA Cost saving incentives come from reality though, not privatization. Chernobyl was a result of cost-saving driving really bad decisions even though it was in the furthest environment from privatization we've ever seen.

He called dry-casking "dangerous"?! (>

I would prefer to spend a day around the dry cask storage than a day in an American school.

@@ddopson if i remember it correctly, kyle hill made a video about nuclear waste storage and how safe it actually is. Let me tell you I'd make an entire bunker out of these dry casks (with nuclear waste in it), that's how safe those things are.

They are not dangerous. Waste has not effected the environment in any measurable manner. Of course, the real issue is that we don't have a _long-term_ solution for nuclear waste. We don't know what will happen to it in the hundreds or thousands of years ahead when plates and continents are shifting. This is a problem that Finland(or another country around there, I forget) is working on.

@@abystanderstandingby6769 They're safe against *accidents* .

and then blaming the position of the warning lights instead of the fat lazy guy lol

The Homer SImpson incident

that means the alarm was right against the guy's crutch

​@@AluminumOxideHe probably felt a slight increase in testosterone because of the alarm 😅

Doh

FYI - Ontario CA means the town of Ontario, California.

@@MrThepinkeagle No it doesn't. 177 Tie Rd, Tiverton, Ontario, Canada

@@Jessev741 I'm Canadian, and well aware of where Bruce Power is. CA just isn't an abbreviation for Canada in an international context.

​@@MrThepinkeagle CA is actually the recognized two letter abbreviation for Canada in the ISO standards.

Darlington…east of Toronto, Ontario CA is in process of building SMRs.

It was a design from the 60's. There was a limit to how much automation they trusted/could do at the time.

I get that, but I'm talking about the valve that should've been reopened after the maintenance.
It never should have mattered that the operator couldn't see the warning lights.

@@tomf3379 yeah it sounds like they basically forgot to go through a checklist (or... they didn't have a checklist)

From what I have learned from other sources I think it is a bit more complicated than that, the valve was ok, but when they find there was a problem, the man at the console activated the emergency valve, there is a problem troughs, the light is activated by the switch not by the actual movement of the valve, so they fought it was open when in reality was blocked, and they had no way of knowing that.
To be fair in a modern nuclear reactor, no such thing could occur without having the engineers informed.

Also modern valves are made to break automatically without intervention, it can be due to pressure/heat other factor

How do you address the danger of air or water getting into the cooling loop (or sodium leaking out of the system) and leading to an explosion? Also, doesn´t sodium tend to form alloys that fall out of the liquid and block cooling passages? I guess my question is, do the benefits of switching to sodium outweigh the risks of introducing a new technology and the risks of using sodium itself?

Hey Cookie, RUclips comments are the last place to network lol. I'm in the industry (actually on the fusion side right now). If anything for the improbability of it, can you and I connect? I've been following your company for quite some time.

Yeah using a sodium primary loop and nitrate secondary loop sounds like a great idea… Sodium fast reactors have been tried and they don’t work. Sodium has terrible volumetric heat capacity and a really high Prandtl number. Not an ideal coolant.

There are other designs, both high temperature gas, and supercritical CO2, but those are more expensive, if far more efficient.

NuScale has a lot of experience with this, they've been doing what you're talking about for decades. And they haven't built anything yet, they don't have any real experience🤣
Therefore, turn to a proven company that not only builds nuclear power plants, sells fuel to you, but is also ready to take spent fuel from you for processing under a contract.

Naw man we can totally trust capitalist cost cutting and profits for the already wealthy when it comes to properly handling one of the most dangerous systems humanity has ever developed

@@Praisethesunson I don't trust them, but i trust the communists even less to be safe with nuclear power so what can i do but pick the lesser of two evils.

CANDU are truly the superior technology.

Also, there are plans developing to build several new CANDU reactors, as well the first SMR plant, in Ontario. All the old CANDU reactors are being refurbished with the goal of 100 year life times.

Is it an issue that they have positive void coefficients?

CANDU has great fuel flexibility, a U.S. based company called Clean Core Thorium Energy has developed a new thorium-HALEU fuel that reduces fueling cycles, improves safety and most importantly reduces waste by 87.5%. They are just starting pre-licensing and feel their product should be available this decade. An 87.5% reduction in waste would effectively make existing CANDU reactors 4th gen equivalent reactors.

@@nav27v I guess Canada won't have the climate change issues that takes down French nuclear reactors every summer now. Or at least, they are betting on nothing unforeseen to turn their reactors into massive paperweights.

Even more technically, the relevant quantity is the concentration of the fuel, not its density. Good catch, though.

volume of molten salts goes up, like the video said, so not incorrect

@@DemsW -- The arrow labeled "volume" points downward, and the exact wording of the narration is, "this expansion decreases the volume of fuel in the core of the reactors".

The density of the fuel decreases which means there’s less mass of the fuel in the reaction chamber where it can undergo fission is what he’s trying to say. He accidentally said these is less volume in the reactor which doesn’t make sense since volume of the reactor doesn’t change. He meant to say less mass is in the reactor.
It is a weird way to say it but is correct.
You’re also correct that density decreasing also means neutron absorption decreases as well.

@@mvmlego1212 Yeah you're right It's on me I thought you were talking about the narration

Are they cruise-missile-proof?

@@grahambennett8151 the kind of structure needed to stop a cruise missile is cheaper to build than a conventional containment vessel. A strong concrete box and a few thousand tons of rock piled on top should do the trick. If not, add more rock. Also, as long as there is no release, even having to scram the unit after a strike isn't any worse than a fossil fuel operation which is likely totally unprotected.

Of course it won't be cheaper. It's all hype and deceit. It's like making a car not with one engine, but with a large number of small engines and spare parts for them.

Some costs would go down with mass production, but in reality it's marginal and there's other aspects of reactor operation that make SMRs undesirable. MIT's studies found that with bigger reactors, a lot of cost overruns occurred because the reactors needed small redesigns to better fit their intended environment. Reactor redesigns require design reviews, re-licensing, and the added delays mean more interest builds up on loans taken out to fund the powerplant's construction. With smaller reactors, it's the local installation point in the powerplant that needs to be redesigned, not the reactor. The argument is that because the reactor and powerplant can be made in parallel and most redesigns will be civil engineering problems, it'll avoid those reactor redesign issues. The time to build is reduced, the risk of delays goes down, and so design review and loan interest costs should stay minimized.
The other problem that comes up is the fuel. Small reactor cores need more concentrated fuel, this is due to "neutron economy". Fission depends on the probability of neutrons hitting and interacting with fuel atoms, so you either cast a wider net (larger core, less enrichment) or a finer net (smaller core, more enrichment). Most reactors have gotten bigger over the years because they get to maximize neutron economy. Raw natural Uranium is dirt cheap fuel, enriched Uranium isn't. SMRs need enriched fuel, so that bites into profits over time.
SMRs and micro reactors are good choices for remote locations, and there are 5-10 MW reactors being designed for those applications. SMRs don't make as much sense for the power grid, they make more sense as testbeds, and that's really the key to Gen 4 SMRs. If Gen 4 reactors get commercial adoption, they'll get bigger over time to chase neutron economy and carry their unique benefits with them, but they need a buying customer first. Nobody wants a giant, multi-billion dollar unproven reactor.

Yep, thanks to the Carter administration banning the recycling.

Including the facility at Zaporizhzhia?

@@fwiffo no leaks, spills, meltdowns yet.

@@trapjohnson Ah, no catastrophe YET, but it's serving as a pretty good hostage! After blowing up the dam, it's clear that Russia has no qualms about creating a massive ecological disaster. And they could do it at any time if they don't get their way. Even without any sort of radioactive release, giving a malicious actor that kind of leverage in a conflict already qualifies as "very dangerous."
Obviously, Russia has nukes. But the same thing can and will repeat itself with non-nuclear powers in the future.

​@fwiffo it would be just as if not easier to mine and process new material than to turn spent fuel in dry cask storage into a dirty bomb.

There, the problem was not in the basement, it was that the doors were ordinary office doors, which did not even have tightness. And Fukushima continues to poison the ocean, water seeps from below because the reactor melted through the base.

You are absolutely right!

Best way to avoid Fukishima-like incident is to shut down old generation reactor and not keep it running for the sake of producing materials for nuclear weapon.

All nuclear accidents have been the result of a long chain of human errors. The problem is the human mind seems not really suited for a low risk but high impact on failure technology.

@@henreator noone runs LWRs to make weapons. You have been lied. And for those concerned about backup generators: if you can fit primary system in 60m tall bunker - you can also put generators there. Two more pipes needed.

looks promising, I'd like to hear more about this seemingly simple design, advantages, disadvantages, etc

As of July 7 2023 Ontario Power Generation has chosen to construct three additional BWRX-300 SMR reactors at the Darlington nuclear facility increasing the total being built in Canada to four.

Do let me know what happens when a missile hits it.

@@grahambennett8151 so what is the point of your comment exactly? I'd dig for meaning but it every answer I come up with seems so absurd I simply can't guess.

​@@grahambennett8151?

It's a catch20 in the US, to build a demonstrator reactor in the US you need a licence, to get the licence you need to have built a demonstrator reactor

Really? Copenhagen atomic??? No disrespect to those guys but we understand LWRs so much better than molten salt and if you read back to the old experiments they’re always having problems with leakages and corrosion. And I see no reason why they would face any less licensing hurdle once they are even at that stage.

All things concerned, Copenhagen atomics not exactly closer to the final line though...

That is a lot of handwaving about technology that doesn't exist. Even existing nuclear technology always delivers over time and over budget. Some people seem to be extremely optimistic or even delusional about the lack of problems any new nuclear technology will face in development.... Even after they already get bogged down by those issues.

@@TheSonic10160 That's by design, they love to say bureaucracy is there for 'safety,' but it's really there to control opposition.

That is because this is an anti-nuclear youtube channel.

@@chapter4travels It is not anti-nuclear, but the author is clearly afraid of going against the established narrative "windmills & photovoltaic vs. global warming".

There aren’t enough minds in nuclear because it’s a rabbit hole the world does not have time to go down right now no matter how much you idiots believe it can cure every one of our problems. You guys bend over backwards to ignore the fact that renewables are significantly cheaper, more versatile, and more abundant than nuclear while fulfilling the same goal. Stay mad at the world for not drinking your Kool-Aid.

Expanding on the issue of grid capacity. The capacity factor of wind and solar power plants is low, therefore the max power has to be high to produce enough during suboptimal weather conditions. It is possible to supplement Wind and solar with gas turbines nearby to always max out the grid connection rather than building a separate grid connection for gas and wind power plants. The issue of max power vs annualised power production means that cost will be higher and capacity factor has to be taken into consideration.
In terms of the SMR hype, the new reactors might work well, but their cost of production and economies of scale are not yet realized. With large nuclear reactors the total number of reactors are reduced meaning, the cost might be lower if they are built cost effectively.
Currently the capital costs of nuclear power plants are high given the low confidence of banks in these projects. Therefore an effect strategy for building and financing large reactor must be realised before their wide spread building. That said S. Korea has build several reactors cheaply. The S. Korean reactors are based on old Westinghouse designs and are proven also coming from a time when nuclear reactors were built cheaper than at the present moment.
It will be interesting to see if SMRs succeed in attracting capital, finalizing designs and cheaply building reactors. I am however sceptical if small reactors are the best idea.

You can use heated water for a heat exchanger which causes the salt water to boil. You collect the steam and that's your destination water. You definitely don't want to drink reactor water. Even the release of reactor water needs to be closely monitored.

Might as well build every nuclear plant like a US submarine, chock full of redundancy so a torpedo hit will allow the system to continue running.

Wow you mean ignorance and making even overwhelmingly clear things political often can cause real life harm? When has that ever happened before lol

Very interested to see how Poland's transition to nuclear goes. I think they are the test case for the modern nuclear powered economy. If it goes well, nuclear will see much greater use around the world. If it goes poorly, I think nuclear is largely dead.

​@@SocialDownclimber For Poland and Estonia, it will still be expensive and inefficient energy. + even if they have resolved the issue of supplying fuel, which will not be the cheapest, how will they dispose of spent fuel? This will be an additional big expense.

@@VictorLarsen-fy9ls That's how I think it will go too, but I don't know for sure and a lot of people seem to think it will be cheap. Glad my own country seems to be going in a different direction but I'm happy to see what happens in the end.

Nuward, Hexana or Newcleo

ruclips.net/video/2HzP4wnyBUs/видео.html, ruclips.net/video/FvmEYESz8Y0/видео.html

That'll just increase the chance of nuclear ICBMS taking off.

And safest, despite what the media outlet $ensationalism and fossil fuel funded studies would have us believe.

Yes but we still have to take ores like uranium out of mines which we can’t replace

cleanest and safest until a disaster shall happen🤷🏽‍♂️

Hope for the future there is. Trust in the Force we must

​@@johannesalexandrius5749everything is prone to disasters smh

TRUEEEEEEEEE

Is this a bot?

@@GM-xk1nw nah I just dont have a life

Real day*

Read the history of the infamous NuScale campaign and stop listening to any amateurs, look for the information yourself.

Not just the carbon, how much radioactive particles have we dumped into our air, soils, and bodies of water because we were too worried that if we change some unknown but tiny- in comparison- amount of different radioactive particles would be released? It feels like nobody around me can use their brain anymore.

5:41 It gets better. Check the spelling of Finland on the headline of the paper shown.

Who cares?

@@oyuyuy Apparently, at least two of us do. Can't have the banjo pickers taking over the world now can we.

​@@oyuyuyones who have slightly more dignity and conscience than you

@@worldoftancraft Lmao, sure clown

I have never heard of a nuclear powerplant having tanks.

@@gorb2518 They definitely do, or at least some. The one near me is separated from the main land with a large straight road in the open with multiple checkpoints and some kind of vehicle with a cannon on it.

​@@texivaninot everything with a cannon is a tank, could be an APC

@@shashwatsharma2596 Well I guess everything I said is moot then, it's just an APC, everything will be fine now.

@@gorb2518 Come to the nuclear plant in South Carolina. They will be happy to use it on you.

I agree, and I think this will be one of the biggest stumbling blocks to it being economical. You'd have to make massive savings by being able to mass produce each SMR in factory to compensate for it

But the most essential parts are still self contained, so surely the rest of the plant can be less complex as a result? Instead of building a custom container and piping into the ground, you can make much simpler buildings and (in theory) mass produce the reactor housings in a factory. It's like building an IKEA bookshelf instead of carving one from a big block of wood.
Or that's what it sounds like. Maybe the plants themselves need to be pretty complicated anyway 🙃

True. But no one is going to complain about a building housing steam turbines, and you can link a number of reactors to the same turbines.

@@ollietizzard5180 What kind of mass production of SMR can we talk about if they have not even reached the level of production and utilization of fuel? This campaign is bottom.

I mean not really. Look at the plant footprint of BWRX-1000. It's 50% smaller per MW of electricity, and 90% smaller than it's larger cousins. These are already being built and will probably be the first SMR to come online.
When you look at test reactors which are even smaller than SMRs they have small enough footprint to be used in existing institutions like research labs, training facilities, and even universities.

Not to mention the lifespan of solar panels, batteries and wind turbines (and yes, believe it or not but these things need constant maintenance) and the amount of energy required to make them in the first place

@@benpietersen3723
you say all that but then coincidentally ignor all those arguments when it comes to nuklear power.
hypocricy much.

Finally, someone states the obvious. Thank you. Comparing the LCOE of intermittant sources to baseload variants is ridiculous.

Even the name checks out

The recycling of nuclear fuel has been promised for at least half a century, and never got anywhere. It's delusional to assume this is going to happen in time to store the enormous waste produced by bringing up SMRs to any scale that would matter.

It's a BWR, which is a form of PWR, which have only been able to be economical throughout history by going bigger, due to inherent drawbacks in the use of water as a primary coolant. Same argument against NuScale.
PWR SMRs sound shiny and new and great but managing the high pressure, low operating temperature, potential for loss of coolant through a change of state and fast acting shutdown systems in a economical manner while meeting today's safety standards has always been an issue for PWRs and will continue to be - you'll see the same delays and ballooning costs with these reactors as we are currently seeing with full size PWRs, and it's going to be used as a example of why the nuclear industry as a whole isn't economically feasible, which just isn't true at all. It's a major separator between Gen III + systems (like those I just mentioned) and the Gen IV systems mentioned in the video, which don't rely on water as a primary coolant, and therefore can be economically made smaller.
SMR shouldn't come first, it's a result of using a more suitable primary coolant, which neither NuScale nor GE Hitachi are doing. People like it in the industry cause it's closer to what they know, but that doesn't mean it's a better choice.

@@wmoysey BWR - Boiling Water Reactor and PWR - Pressurized Water Reactor. Some would call it a big difference. In a BWR, the reactor boils water to make steam. This wet steam flows though the turbine. In a PWR, hot high pressure water used to cool the reactor gives off it's heat in a heat exchanger (steam generator) to other water which boils to steam and turns a turbine. It is a bit like apples and oranges and maybe using the words, "form of PWR," should be editied. I see you've already edited your comment once.

@@wmoysey When the logistics and design is implemented correctly light water reactors have a decent cost record. US second gen water-cooled reactors at 600 MWe had an inflation-adjusted LOE of about $1,000 per megawatt vs about $2,500 for LNG. French light water reactors likewise have given France the lowest electricity cost in Europe. So there is plenty of evidence light water reactors can work if implemented right.
The big advantage of light water reactors is they are available in the near future. Additionally over 20 BWRX-300 reactors are already on order. The nearest true 4th gen design is the X-energy gas-cooled pebble bed Xe-100. It should be available around the same time as the BWRX-300 and in a lot of ways is superior. Such as safety, a 4x reduction in high-level waste, 60 years of continuous operations, etc. But it’s not setting the nuclear world on fire, with two plants in the US and Canada on order. So for the 2027 to 2037 time frame, the GE design looks like the winner. And as pointed out scaling from 600 MWe to 1,000 MWe didn’t pay off so its historically accurate to say the industry believed scaling to 1,000 MWe reactors would be better in theory, but in reality, it wasn't
Smaller US second gen plants were a lot more economical, so there really isn’t a historical precedent to believe going down to 300MWe should be worse if the plant is 90% smaller in space and materials than current boiling water designs. Also, the GE plant is the 10th iteration so it’s a well-known design and most coal plants are 250MWe to 600MWe. Using an existing brownfield coal site can reduce costs by 25-33% according to Department of Energy estimates so 300-600MWe for a reactor size might be the sweat spot as there are so many more siting opportunities for reactors of this size.
I think in the long run more advanced molten salt reactors and possible high-temperature gas plants will be better, but for now, GE’s design is winning the order war, its scales a lot better than NuScale and other designs as well, while still retaining many of the benefits of being small and modular.

300 MWe on the BWRX-300? Okay, how quickly can they deliver 120 of these? I would like to fill in 20-30 GW base load with a bit extra for future growth and redundancy. At least much better than buying 400 NuScale.

than you need to put this thing inside a city. not going to happen

It could be used for greenhouses or other things as well.

All the micro nuke plants on the drawing boards have an even higher waste heat number. That's why the boosters of the industry always talk about putting one on every city block to provide building heating. Without utilization of the waste heat, micro nukes make no economical sense. Even with utilization of the waste heat, they still make no sense.

@@yakovkosharovsky8487 Maybe not for municipal heating, but factories and other industries often need steam for their processes, so it might be a good idea to locate the power plant by an industrial district so that the factories can use the waste heat

@@yakovkosharovsky8487 it is ecomonically viable even if you have to run 40km heating lines. Also, you have already CHP nuclear in Europe and even trigeneration one.

This right here is exactly my argument for nuclear energy, every nuclear accident in history has been an isolated incident usually caused by external forces/conditions, not by the nuclear reactor itself, in the case of Fukushima ask yourself, how would ANY building survive an earthquake of that magnitude, the earthquake caused significantly more damage than the reactor meltdown by a factor of at least 10 yet "environmentalists" who are payed off by oil and coal place the blame on the nuclear plant for the damage as if IT had been the cause of the earthquake.

Read about the “Windscale fire” accident, how stupid the reactor design was.

You're not exactly right, but how you're wrong actually makes your point stronger. The meltdown itself didn't kill people, except one person who died from lung cancer attributed to their radiation exposure 4 years later. The death toll attributed to Fukushima is from the evacuation and events surrounding the meltdown, not the meltdown itself. Not really the same.

I believe I recently came across a study on how the Fukushima accident caused a shift in government energy policy, which in turn ended up killing more people than the disaster itself actually did. Something to think about.
Edit: some people pointed out that the Fukushima meltdown caused no deaths, and that is correct. After re-finding the study, it refered to the 1232 deaths that followed the rapid Fukushima evacuation.

Actually no one died from the Fukushima meltdown.

The Englishmen put pressure on Europe through the topics of ecology and CO2 in order to squeeze out industry and capital from Europe to their English countries, this is their capitalism. As a result, they have destroyed nuclear power and made other sources of energy very expensive and not profitable for industry, and the abandonment of cheaper Russian gas.

👍👍 Yes, you have excellent points! As do many other commenters. I always really liked Real Engineerings Videos, but this one really has an awful aftertaste of propaganda

Came on here to ask the same. Was quite surprised at Brians choice of words there. All relative I suppose

@@abc20914 I'm guessing he meant it is theoretically dangerous in the sense that the waste is still a physical, tangible object that can be accessed. Fossil fuel waste is discharged to atmosphere (though ironically it does more damage there than solid nuclear waste ever has)
To answer your question:
- the majority of "waste" is low level waste. By volume, most waste is material that had been near a reactor, and is minimally radioactive. This could be stuff like old pipe lagging or even nitrile gloves. All the waste has to be accounted for in the nuclear industry (though it if course depends on each countries regulations).
- the intermediate and high level stuff contains spent fuel and is more dangerous in terms of radioactivity. It forms a very small proportion of overall waste (though not trivial)
-stuff that is "really" radioactive decays quicker. So when you hear of things being "radioactive for thousands of years", this will be stuff that is quite weak and very slow decaying, often only alpha or beta emitters that can be blocked by paper or skin.
-high level waste is often vitrified and encased in concrete, and left in containers that are quite literally bombproof, under armed guard, weighing many tons. So although the stuff inside IS intrinsically dangerous, is for all practical purposes stable, inaccessible and going nowhere.
(This was a large generalisation and hopefully someone will correct me or provide more details)

@@ollietizzard5180 that’s a pretty good summary, and I think you’re probably right, the waste itself that’s being stored in the ILW containers is very dangerous, however those have very stringent regulations for how they’re stored. An incredible amount of analysis is done to ensure they’re safe, as a few examples there are seismic analyses to ensure no earthquake could cause the release of the material, and the same for various other scenarios like one of the more infamous, “survive a fully fueled 747 impact”

i’m so happy Canada isn’t scared of nuclear cause honestly the only other solution that we would’ve gone for was coal or using the tar sands and i’m sure everyone knows how bad those are

Our grid needs aren't big enough for a large reactor, even the 700 MW CANDUs I believe, so the development of the 300 MW SMRs we're looking into is very nice, and Ontario's now building four so we'll have at least one built elsewhere before deciding to start one of those

Xenergy, BWXT, Project Pele, USNC- these are just off the top of my head US SMR projects still going strong with government backing.

@@Anthrofuturism Not one of the ones you mentioned is anywhere near as far along as NuScale and NONE of the ones you mention are receiving $2 billion in U.S. government support, like NuScale. Now that NuScale has failed and is being sued for FRAUD, look at the stock of those other projects

@@clarkkent9080 yes Xenergy and BWXT were awared 2billion in April 2022 via Project Pele. Just Google it.

Nope. It can't catch fire it's already in a chemically stable state, it's sort of pre-burnt, and it could evaporate water into steam, but there shouldn't be any water near it, the only water is in the steam turbine loop, and that's assuming you use steam turbines.

@@killcat1971 I'm been told the reason the Navy doesn't really like molten salt reactors is it's explosive reaction to water, of which the reactor would perpetually be near on a ship.

@@Edax_Royeaux That may be part of the problem, but the designs often involve using convection currents which might be a problem in a vessel that's moving and altering angle.

@@Edax_Royeaux You may be confusing Sodium Cooled Reactors which the US Navy rejects for the reason you cited. Big problem on a naval vessel, not so much on land where it can be isolated from water/air.
Another reason may be power density. Naval reactors are often enriched north of 90% to make them small and quiet.

"neither process heat nor heat for heating homes" Converting electrical energy to heat has an efficiency of worst case nearly 100% and best case 300% - 500% when using a heat pump. For process heat this might not be applicable to get to high temperatures but for heating homes i see absolutely no reason why we would need heat production and cant fare with electric heating.

It's not in the neighborhood of the people who own the plant so it's fine.

Why not just cut out government funding for solar subsidies and watch as nuclear takes off. The world must suffer the blackouts of solar covered California for people to demand reliable energy. People will only protest for climate related things if their lives are peaceful. The moment you make their lives inconvenient, they will buy as many fossil fuels needed to make them happy again.

The next 2 reactors at Cernavoda are still CANDU. Plus R1 will be refurbished at the same time.

CANDU is not small or modular, it's infact inherently large facility due to the heavy water pool.

This is incorrect. The CAREM in Argentina is near the reactor mounting stage. We are way ahead of all of you, nuScale is just a small test one, CAREM is straight a power plant.

@@kennethferland5579 lol, read my comment again

@@Argentvs Sorry, I think I didn't express myself clearly. The romanian Doicești plant will be the second one built on the NuScale type technology and design. I wasn't saying it will be the first functional SMR in the world ...

Fukushima had redundancies of 2 back up water pump systems. But the first system required electricity which had stopped across most of the country and the second were diesel generators with their own fuel tanks......stored in the basement of the plant. 🙄

So technological development has been artificially hampered since the 1970s, including through the creation by the Rothschilds of environmental organizations such as Greenpeace.

SMR is just hype and corruption. Read the history of the NuScale campaign, they do not have a single serious project, even paper projects have not been properly certified, they have no experience, they exist for decades only at the expense of investments without doing anything. NuScale collects promises and agreements in different countries like fleas in order to receive investments. And who will supply the fuel? Who will dispose of this fuel? This campaign does not provide such services.

Nuclear got expensive when construction in the western world got slow. At 8% interest (normal for nuclear now) a 12 year build costs 60% in rent payments and 40% in literally everything else. A 5 year build as done during the heyday at 4% interest would cost 16% in rent payments and 83 in literally everything else. Rent has gone from costing 20% ontop of building the powerplant to 150% ontop of the powerplant. MSRs can make nuclear a lot cheaper by passive safety features making construction faster, Easier modularization, making construction faster, higher temperatures allowing use of modern coal plant engineering in the steam/CO2 part of the power plants allowing engineers form those sectors to work here, the fuel salt being only slightly above atmospheric pressure for pumping it around not requiring as heavy a bunker light water reactor require and the reactor vessel being made out of specialty stainless steel that is much less thick allows it to actually be manufactured by more than 4 factories in the world.
Light water might be cheaper in a pure engineering world but we have to deal with financing and logistics in our real world that make nuclear cost 3 times more than it would actually need to cost.

@@pokekick4185 *MSRs can make nuclear a lot cheaper by passive safety features making construction faster, Easier modularization, making construction faster*
A big reason "construction" is so slow is due to regulation, bureaucracy, ... though. This is unlikely to change with SMR's.
Passive safety systems can also be build into bigger reactors, so that isn't a good reason for why SMR's would change things. The same with higher temperatures.
Like the only thing you've said that SMR's has that big reactors can't have is modularity. And that has its own downsides too.

@@MDP1702 I agree that most of the reasons cited are not SMR specific, however the financing piece could be a game changer if the smaller plants can be built faster. Long build times can double or triple the cost of building the plant as noted, which is the biggest part of the nuclear cost.
It may not matter if the sticker price/MW is a bit higher or the efficiency is a bit lower if that financing cost multiplier hurdle can be overcome.

@@richardbaird1452 That is the thing, can they be build faster? A lot of the time problems are bureaucratic and financial in nature (which is why it generally goes faster in countries like the middle east and even south korea) and ofcourse you'll need a lot of SMR's to get the same amount of power output. For example you'd need 27 reactors of NuScale to have the same power output as most modern big nuclear reactors.
I want to first see them building the equivalent of a large reactor before making any conclusions.
I also wonder if it might not be more expensive to refuel those 27 reactors vs a big one.

The French are one of the few countries that reprocess and the main reason for that was for their nuclear weapons program. They have only reprocessed 1/3 of their spent fuel and their facilities are reaching the end of their life and will not be replaced adding millions of toms of highly radioactive waste

Capitalism will kill us all if it means line go up

That's why nuclear is and should be heavily state regulated and even state owned. All countries that do nuclear have strict independant nuclear safety regulators, that regularly audit them and allow them to run their plant only if they meet their regulations. Not as much can be said about the oil or chemical industry

Solid nuclear designs (not PWRs) can't really go wrong even if someone really fucks up.

@@leonmorel789 And yet the system doesnt work flawlessly. The problem is the low chance, high impact nature of nuclear power plants.

Except utilities are basically paid to build and maintain energy assets. Utilities don't cut corners.

On the other hand it is on demand. Best thing you can do with not on-demand power sources is decoupled energy consumers such as carbon capture and synfuel production, where it doesn't really matter when exactly the work is being done.

@@zolikoff If energy is spent on useless hype processes, then the price of electricity will increase for all consumers.

@@VictorLarsen-fy9ls I agree with that statement

Some newer designs currently under licensing use a molten salt heat storage similar to thermal solar to decouple the nuclear plant from the electricity generation which allows for load following while the reactor runs at 100% at all times (e.g. Natrium, SSRW). Essentially this turns the reactor into the equivalent of a gas peaker plant, which is exactly what is needed with renewables.

@@richardbaird1452 A PWR can already load follow just fine, including using around 5% of its capacity as peaker, but in general it's more expensive to do that than to just use a constant output. So places with lower % nuclear don't do it. France does and it works fine.

S. M. R. Can never be equal to a full scale Reaction...
Difference is the supply...
National or Multiple City's vs City's and Village's
S. M. R. Should be projected to be profitable after at least 10-15 years... So not attractive to individuals for investments and governments largely deal in patch works and rarely commit to holistic solutions.
P.S. didn't bother to read the second half of your comment

@@bk_1627 wow you can't actually read properly, right? I compared SMRs to conventional "existing" nuclear power, not to anything else, and I'm saying it is delusional to think of this technology as "small scale". And no, nobody would have built the plants in Chernobyl or Fukushima if they had known this was a considerable possibility. They didn't talk about acceptable risk, they said it wouldn't happen. And got surprised by reality, like you are saying it would never happen with those SMRs. Yeah, the concept of "meltdown" was known, but they always said it wouldn't happen. And yes, you can skimp on regulation and popular participation when you run an authoritarian government (South Korea isn't that much better than China, in some respects). And we can only hope that China is orders of magnitude better at regulating the nuclear industry than any other industry. Hint: They suck at regulatory oversight, even while making a big show of it. We can only hope they are somehow magically better at regulating this particular industry. I don't even debate that nuclear power sounds awesome in theory. But in practice the risks have proven to be impossible to calculate (that means we don't even know if they are acceptable or not, they may actually be), from simple Human error to natural catastrophes, even adversarial intention.

@@marlmyster Yeah, it would be inconvenient to actually read the comment you are replying to, right? And no, most SMRs would need to be built at larger sites, with multiple SMRs per location. Smaller sites would increase the cost of waste storage and overall security, because a large plant needs the same security than a smaller plant. You can't risk anyone breaking in and taking out the nuclear fuel, and you'd spend a lot of money doing that at every village those things are deployed at...

@@Andreas-gh6is
Reply to @bk_1627
That one is more important

There is and never will be economies of SMALL scale

My thinking too. Moreover, consider the old plant’s fossil boiler is replaced with a new reactor, the old cooling system, power yard, and maybe the turbine/generator/condenser reused.
Green is already banging up against NIMBY resistance. Not to mention right of ways. Cheers

It could be, which is the strongest evidence that he is talking out his arse here. It pisses me off when people go on about waste as this unsurmountable problem, when the simple reality is that it is such a minor concern that the reactor designs that mitigate it are simply not worth it.

@@agsystems8220 You are right about some of his discussion on waste. I have no fear about the casks outside nuke plants. A little Fear, Uncertainty and Doubt (FUD) liven up the video.

CANDUs have really good passive safety characteristics with the small fuel channels capable of natural circulation. Not as bulletproof as Nuscale or other new options but with a proven track record of building at a good cost. I think they combine safety with economy of scale like no other option. The ones with a shared vacuum building and rooftop reservoir have 10-12 days of passive cooling and can continue to cool without power with water being pumped into the boilers even then

@@Canucklug I understand they have great fuel flexibility too. The fuel need not be so refined and I think they have little problem accepting Thorium.