@@borystsolinthe hope is that being small, they can be made modular and thus reduce the cost significantly. Of course, if only one or two are built, then the price won't come down.
@@JohnGeorgeBauerBuis Maybe that was sarcasm. A plug door flying out due to someone forgetting to put some bolts in and inspection failing to catch missing bolts is quite the epic double-fail.
Pretty on brand for the nuclear industry actually. The nuclear industry has perhaps the most captured regulatory body of any energy technology on the planet. If regular people had any idea what actually goes on inside the worlds nuclear plants, they would demand that they all get shut down yesterday.
The comparison to airplane construction is unsettling with all the cost-cutting measures and skimping on safety that whistle-blowers are getting killed over...
In as much as what you're saying is true you are just highlighting one particular manufacturer and trying to push the whole thing into some kind of conspiracy when in reality if you compare the amount of death from playing compare to the cars and other form order mobility airplane has achieved greater safety than most means of transportation the history of passenger airline proves it because any plane crash is a major headline and from search headline engineers learn and create safety and improved the reliability of air crafts.
What makes me crazy is that Three Mile Island was the nuclear disaster that could have been. But its always reported as a disaster that was. The incident caused a scare for sure with evacuations and concerns about released radiation but the containment building held and did its job of containing anything that escaped the reactor.
It was a nuclear incident, it most certainly wasn't a nuclear disaster. You don't get to redefine words or domain terms, that is criminally stupid especially in a field that does some have inherent dangers to it and you should get no say on the topic if you cannot even agree to describe things as they are over what you fear or hope they ought to be
Then maybe look up the insane amount of negligence in both building and running it that resulted in the meltdown. We got lucky with 3 mile island. Safety rules were massively upgraded afterwards for a reason. A meltdown is a complete loss of control and should never happen. If it happens there is no way of being certain if the structure will actually hold or just delay the inevitable.
My dear friend, you are talking logic to the ignorant, uneducated, and willfully illogical masses. We know nuclear is better and safer over the lifetime than fossil fuels - from extraction to consumption. Unfortunately the PR image that doomed it would require a strong leader to say to your average idiot voter, “We’re doing this whether you like it or not” and we don’t have any strong leaders like this anymore.
Nuclear carrier reactors are comparable to SMRs. They have an outstanding safety record and probably billions of dollars have gone into studies and designs. Ford class output 700 megawatt but much of that energy is diverted to propulsion. But it seems a sound starting point instead of starting from scratch. A previous potential safety feature of SMRs wasn't mentioned here. Yes, build them in factories, but install them in suitable holes. If one goes critical it's small effort to use remote control bulldozers to simply push dirt into the hole and seal off the radiation leakage. Technically these are well within reach. The real problem is we can't get anything done anymore. It's all talk and arguments.
Problem with naval reactors is also that they usually use highly enriched Uranium, which is much more expensive and really not needed for a "simple" power plant. It's also weapons grade, so safety really is a concern there. I don't think these reactors by themselves would work in a stationary civilian setting, but they would probably be a good starting point if their design wasn't classified. That being said, the easiest and cheapest way of producing nuclear power is just like we are doing it now.
Nuclear reactors on ships are also manned by trained personnel just like in the big power plants. Having and managing the necessary personnel that would be scattered all over the place may be a big issue. Even if reactors can be mass produced, getting enough trained personnel is whole other issue.
@@SunShine-xc6dhThat's just so wrong. Nuclear fuel is just so far from refinement needed for nuclear bombs so it's impossible for actual nuclear explosion to happen.
@@SunShine-xc6dh a nuclear weapon is a bomb that will explode. A nuclear reactor won't do that, because it's not a bomb. Nuclear power is statistically one of the safest ways to generate power.
@@theDaNi0 sensors + earthquake measurements + overflow measurements + leakage protection + heat protection + protection from potential airstrike (yes all nuclear plants have this) and so on
I'm no expert but here in the USA after Three Mile Island Congress enacted such difficult regulations to comply with that nobody could build a new power plant without violating the law somehow. I worked in the industry briefly in the 90s at a place that built power plants and it was if time had stopped after TMI. All the outstanding orders for new power plants were cancelled, most people quit or were laid off and a skeleton crew carried the load. The company eventually collapsed. I'd love to see new nuclear power plants in the USA but we need to change the laws so its possible and economical to build and operate them.
stop being scared period. Thorium reactor are safe and could immediately end all of our psyop agendas related to the fake climate change naradigm, designed to enslave humanity to the demonic forces of hell.
Hey there! We actually took a closer look at Thorium nuclear energy some months ago. Check out our video 👉 ua-cam.com/video/Km6kqykX900/v-deo.html We are curious to hear what you think.
I look at the people building nuclear and then I think of the dimwits that will end up in charge of safety so no I'm fine with my radiophobia just where it is.
Problem with people is that most of them are to lazy to start using their own brain. They just think on the foundation that mass media though them. Farm animals pretty much. No critical thinking, no evaluation of potential and risk, no strive for individual growth .
There are almost 200 small modular reactors operating with a 100% safety record for 65 years, all over the world. Huh? Yes, on ships, almost all military. No one thinks twice about getting aboard a nuclear ship or having one in port. But oh, the Chicken Littles!
Except those are not designed to be cost effective. Which is why they are only used for submarines and the largest of aircraft carriers. There are hints that the newest A1B reactor might have potential for civilian power production, but good luck getting Bechtel and the USN to share.
@@anticarrrot Jesus Krist. My point was that we already have hundreds of small reactors in long, successful service. Cost effectiveness is not in the conversation.
@frequentlycynical642 Well actually... The video is about cost effectiveness Well actually... A lot of those reactors quite famously don't have 100% safety record Well actually... Nations have barred nuclear vessels from their ports, and lots of people think twice before boarding one - mostly because of the 'ticket price'. And great Flying Noodly Spaghetti Monster, watch the fucking profanity
The reason SMRs are so expensive is that the development costs are being paid for by just a few units. If the designs work and are reliable, then many more SMRs can be built spreading the development costs over many more units. Government research grants to pay the development costs make sense.
If only the worlds military budget is used for science and innovation. (Ex. $30B Nasa vs $815B US military, 27x of nasa’s budget. ) We already terraformed mars by now and stopped human climate change/Global Warming through clean energy.
The true cost should include the safe storage of nuclear waste for 100s of years and the decommissioning costs which are probably around the same or more as building them in the first place. In the UK renewables (mostly wind and solar) account for between a third and half the generated electricity for much of the time. Thankfully coal is zero to 1.5%. Amazing progress from the days when most power was from coal.
There are 4 of them being built right beside each other not far from Toronto. The first one will be be finished by the end of the decade. So come 2030 it'll start being feasable to scale them.
SMRs are most practical in space (moon and mars), and in desolate environments. Unlike their bigger counterpart, they can more easily be 'automated'. With SMRs you can quite easily build a reliable power source in desolate environments like the moon and Mars, etc (Titan - Saturn's moon).
You have to think about the money. Imagine holding a billion dollars... and betting that "solar/wind + storage" is going to be more expensive in 10-15 years than your nuclear technology (an industry know for massive time and cost over-runs). You honestly wouldn't do it.
yes and plastic can be recycled too, yet we have the great ocean garbage patch. that somthing is theoretically possible has nothing to do with it being practically possible.
All 4 generation reactors can use or recycle more than 50% of nuclear waste to the nuclear fuel. All of them can use at least twice recycled nuclear fuel. All fast reactors can produce more nuclear fuel than got It's basics.
I am strongly against not pursuing nuclear out of fear. That is just nuts. There is zero chance we reach climate goals without the consistent energy from nuclear
I broadly agree, but when I start hearing folks in the nuclear industry talk about "unesscessary regulatory burdens" it's difficult to trust. People forget that nuclear power workers aren't just neutral experts here to provide the best opinions, they are financially invested in the success of nuclear power even if it means making something that isn't safe. The problem is the margin of error is such that, if those cost inflating regulations aren't followed, even small disasters can leave radioactive products that are really expensive to clean up. Honestly, I think people forget that other industries with similar environmental impacts like chemical processing plants or former mining operations really ought to have had these kinds of regulations too, but we see what happens when companies can just pull out and leave their trash behind, and the results are horrifying even when it's not radioactive byproducts causing the environmental impact. The sad part here is that these non nuclear impacts often go ignored. We're not doing ourselves any favors if we replace one shitty polluting system of energy and industry with another that just pollutes differently. Honestly, this is why I think that any kind of green energy initiative that fails to also address the problems of late stage capitalism (i.e. needing to run a profit on carbon neutral energy) isn't going to work out. That's the piece that I think some nuclear power advocates miss out on. It becomes a sort of tunnel vision that is honestly just as driven by the fear of climate change, which is a valid fear to be sure, but which ignores the possibility of substituting one shitty future for another. Let's just not pick shitty futures? Socialize energy production.
Fourth generation Nuclear power plants, small, reliable. No meltdowns, re-usage of nuclear waste from the past, small and modular. These are the goals for a return of nuclear as power source. You are right, the public may reject the technology out of fear, from past disasters. But they don’t think that the Superphenix has been working for 30/40 years now, and there are 54 active Nuclear power plants in the US
@@saturationstation1446 Mind you, from the known nuclear disasters, there were zero (0) casualties in Fukushima. The other tragedies happened due to human error or cost saving measures. On average, water dams do more harm than nuclear, and people don't seem to fear them?
ITs fine .I have one across the road about a mile away-- Darlington - 3 reactors and a SMR under construction, 35 years and no problems.@@saturationstation1446
I'm still banking on Last Energy being the ones to break the SMR barrier first. Using mostly off-the-shelf parts from mature oil/gas industry supply chains is brilliant, and should finally allow for true enough standardization to actually get the cost per reactor way down.
@@adamdavies6248True. But I think this is misguided considering the excellent safety record of nuclear powered ships. What really should be banned is filthy oil-burning ships - especially cruise ships - that produce a huge amount of local pollution.
In case of nuclear power economy of scale means lots of output power. SMRs need everything a large reactor has, so the savings are not there. Same counts for wind energy as well, so we see wind turbines get bigger and bigger.
thanks for your report, I find it balanced for the short timeframe. I believe that bigger nuclear power plants are the way to make an impact (both in terms of energy baseline and low CO2 emissions), while, as you pointed out, SMRs can have a niche application to energy-intensive industries that need additional energy capabilities (e.g. for steel production). All in all, the implicit good news is that investment is rising after decades of negligence - and with high investments comes high innovation, just as it was for solar and wind. Perhaps in the next video you can highlight the investments in EU and the Countries that plan to start or expand their civilian nuclear fleet. Thanks!
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“In any system of energy, Control is what consumes energy the most. No energy store holds enough energy to extract an amount of energy equal to the total energy it stores. No system of energy can deliver sum useful energy in excess of the total energy put into constructing it. This universal truth applies to all systems. Energy, like time, flows from past to future” (2017).
That is true and continues to be true for fossil fuel industry. But there are much cheaper and safer alternatives than nuclear for the grid. Like the giant fusion reactor we get for free in the sky.
@@beyondfossil I too am a big fan of solar energy but as long as we are not able to store solar energy long term we are reliant on backup power plants and for places where hydro and geothermal aren't an option nuclear energy could come into play.
@@mrkokolore6187 Sure, and the grid scale problem is actively being worked on. Furthermore, the more renewables production that comes online, then the more research & investments will be put into accelerating the growth of grid storage industry -- a positive feedback loop. At 99.9% the mass of the solar system and 173,000 terawatts peak energy flux to the Earth, the sun daily provides several orders of magnitude we use every day. Less than 1% of the world's land surface covered in current generation solar panels could power all the grids. There is enough offshore wind to power the world several times over. There is always some combination of sun and wind in most places where most of world's populations tend to be located. Keep nuclear for military and special scientific applications. Because the next 10 years will be pivotal to change course in our fossil fuel dependency. Whereas a single nuclear power plant can take 10+ years from inception to becoming online and operational. Pursuing nuclear at this critical juncture will have negative impacts on timeline.
@@mrkokolore6187 The grid storage problem is being actively worked on. Plenty of information on that online. The more renewables that come online, the more the grid storage industries grows. (Looks like UA-cam failed to post my other reply)
@@beyondfossil Yeah, I am aware of the continuous work on energy storage. For me pumped hydro and thermal energy storage(i.e., sand or molten salt) seem to be the most promising solutions. Perhaps also sodium-ion batteries. I also heard of a method where you convert iron oxide into iron metal with excess energy and burn it back to iron oxide when you need more power. All interesting and cool concepts. Don't know if they will be ready soon enough tho. Especially with fossil fuels still being dirt cheap. The problem is the focus on profit and fossil fuels sadly seem to still be very profitable.
Do you know how crazy effective this would be for farmers? I live in Canada. It’s cold. Can’t grow anything 1/4 of the year even tho I’m in one of the warmest zones. With those reactors as a power supply, you can run massive greenhouses. Large enough to grow things like bananas, citrus, custard apples, tropical plants that normally can’t be grown anywhere near Canada. All at a large scale. Large enough to make the food cheaper, with the benefit of being fresh.
Definitely worth continued experimentation. Not just for our immediate energy needs today, but also for space explorations of tomorrow. Many NASA probes (such as Curiousity) are powered by nuclear energy, and I can imagine many ships humanity sends (crewed or non-crewed) will absolutely require nuclear energy sources out in the infinite void where we won't have anything else.
Who are "people"? I wouldn't want to live anywhere near one of these things. Nuclear fission is a very poor way to make electricity, and today it's also one of the most expensive means of electricity production.
Not 100% green if you consider the energy required to build them and the toxic nuclear waste that has to be stored for 100s of years and the energy used in mining and processing the uranium fuel etc
I know you want to be part of the conversation but if you are just repeating the talking point of the video without even Googling if what you are repeating is true or not then you are just wasting time.
@@Alphachewei nuclear fission power could greatly solve much of our world’s energy needs. It doesn’t require nearly as much mining and extraction as coal and fossil fuels, it emits zero greenhouse gasses, and all of the waste products it produces are all stored in containers. Whereas fossil fuel waste is vented into the atmosphere. Unfortunately the hurdle for nuclear power is political and a scientifically ignorant population of people. As for the video, it’s saying that rather building huge costly nuclear facilities that can take a decade to permit and develop, large energy-consuming businesses can build a new generation ultra efficient on-site reactor for their energy needs.
The problem with SRMs is that they don't have the economics of scale of traditional larger nuclear plants. So the energy production from them needs to be subsidized
That's not true, there is no need for subsidies you are clearly a European though lol. SMR's (Not SRMs) are still cheaper then fossil fuel and provide reliable backbone power, you can over build it and dump the waste energy into CO2 collectors to recapture the CO2 we've released. The thing keeping their costs up is the fact nuclear power especially SMR's aren't the mainstream thus they don't have the economics of scale. All we gotta do is build SMR factories and get the fuel cheap. Thorium SMR's are my favorite as they're physically resistant to meltdowns without needing active cooling.
Safe by design, in most cases means liquified metal (like lead) not water. Because it nearly impossible to heat up lead to make it waporize and even when lead leaves reactor it will get solid fast. Also, rods in the ractor are moving down (stoping the ractor) without power application to maintain its position.
As much as I support nuclear energy SMRs never seemed a too bright idea. You have great economy of scale with the normal size, the site has to be specially monitored and defended wheter it produce 300MW or 3-4GW. Same with the infrastructure. Also they use more material, the same capacity may requires more personnel. As long as they plan to install many of them at the same site it isn'treally worth it, and if they don't then there is the problem of botth the nuclear waste, and vulnerable infrastructure being too disperesed.
I think the best advantage is the modularity. Who's going to put down billions in investment and wait at least 5 years to see an NPP running. MSRs allow piecemeal expansion. Oh, your energy needs expanded by a few hundred MW? Just add one more reactor to the plant. As opposed to adding gigawatts and spending billions for every reactor.
@@anxiousearth680 Only in theory. In practice, you end up needing a bigger turbine, possibly more power line, and other equipments. You also shut down the facility cause you "install an upgrade", regulators has to check the new parts, you need instrumentation, controlls and ppl for the new reactor. You have to prove with tests that the new one did not change the current characteristics of your installation significantly, and now you have to run all of them on a capacity that justifies the new one, with its added costs, manifacture, maintenence extra staff and permitting. The problem is, you end up redoing everything for addign like 50-100MW which in many case can be done as a major upgrade on an existing higher capacity plant. And while at it, you better just build another big one, jump through the hoops once and add another 1000-1200 MW.
In Australia SMRs are already widely employed specifically to extend the life of coal and gas generation - miners, media & right wing politicians tell the punters that SMRs are almost available and will deliver cheap, hassle free electricity and so renewable projects should be handbraked to leave the market open until such time as we can build them all.
Here is one issue I have with these SMR related videos. Virtually none of them, including this one, had pointed out that SMRs absolutely work and we have decades of experience. Just look at all the nuclear submarines and aircraft carriers. Since the 50's there have been over 160 nuclear naval vessels built, and every single one of them is powered by a SMR.
@@astebbin I shall argue the 2 points you made are perhaps erroneous. 1. Enrichment Levels: Naval nuclear reactors runs on military grade enriched fuels of over 93% enrichment. The proposed SMRs run on HALEU grade of no more than 20% enrichment. It is simply far too low to be weapons grade. The much lowered enrichment level also serves as an extra level of safeguard to the already stellar safety records of naval SMRs. 2. Proliferation: This seems to be the go-to argument for much of the anti-nuclear energy crowd, but it is simply incorrect. As a matter of fact, commercial nuclear energy generation is the best proven way to denuclearize one's military arsenal. To prevent Soviet nukes falling into the wrong hands after the collapse of the USSR, the Megatons to Megawatts Program was put in place from 1993 till the Russian invasion of Crimea. The program decommissioned an equivalent of 20,008 or 45% of total stockpiled nuclear warheads by the USSR. The decommissioned warheads were then downblended into commercial reactor fuel. During those 20 years, 10% of total US electricity generation came from those "recycled" Soviet warheads. If anything, it should be argued that commercial nuclear energy generation has greatly served the propose of anti-proliferation.
They should look into reactors that use thorium instead of uranium. Thorium cannot be used for bombs. Also, the SNR concept includes burying the reactor to begin with. A thief trying to steal the nuclear material could be stopped long before the reactor has been unearthed.
In Canada we have a pilot SMR in production. It is a pilot project heavily focused on safety and it's current price is estimated at CAD$2.5Billion and produces 10MW of power. It is estimated that the price can drop to 1 tenth ie: CAD$250Million for 10MW of power. . . Now for comparison, we have recently (2024) completed a 10MW solar farm for CAD$16million. We also have a project that includes Battery Electric Storage System(BESS) and 40MW solar farm for about CAD40 to 50million and guarantee at least 10MW 24/7. . . . No way SMR can ever compare to a solar/BESS combo. Most importantly keep in mind that the SMR is still over the Billion Dollar mark. and 'projected to drop'. . . We have the means to a clean future.... the only reason SMRs are entertained is the clear fear that solar can quickly become mini-grids or even home scale use... meaning large corporations will not be able to make money out of mega scale energy as they do today. This is happening today in Spain and there is currently mega political turnoil as a consequnce..
What do you mean in specific thats a vague question. Im going to assume you mean what are the cause and effects interms of negative consequences in the event of a critical emergency or other hazardous incident causing a nuclear radiation leak. The most obvious solution is that because the smr radioactive components are inside the smr then it would be super easy to just take it offline and then take it to a nuclear disposal site (which is safe since we have solved alot of the issues around when the famous disasters happened and when nuclear energy was being debated to replace fossil fuels) Besides progress in nuclear powers safety which make anything like like the famous incidents like chernobyl & fukishima. Now we have systems that have many failsafes and such. But in specific to smrs their design is so that the risk is minimized in the first place but if and when something goes wrong they are both not big enough sources of radiation to be more than a local incident, as well as many of them being underground and shielded by concrete. If that fails its very very easy to shut the smr off and then move the entire thing to a nuclear waste disposal site. If youarent aware already we have actually solved the issue of nuclear waste watch kyle hill's video titled "weve already solved nuclear waste" since they can explain it much better than i could. But the smr is designed so that the whole unit can be easily moved so that means if it becomes problematic it can be moved to a safe disposal site where it wont pose any dangers to humanity or even that local area wher it went wrong or even the workers at the disposal site. In fact, in the video I recommended kyle hill literally kisses nuclear waste containers and stands rigjt by them because he knows its safe. No protective equiptment either just plain clothes. I can try and specifically answer any questions you might have if you specify what you mean but i hope this eas enough of an answer for you. Also i hopeyou check out the video so you arent just relying on my word and you can see for yourself.
@@anarcho.femboyism wow. This is what I wanted to know 👍😀. Thanks for this long wonderful explanation. I have seen the video from kyle after you asked me to and yes. I will complete the video. No me it is bit worrying when everytime governments are involved and funding projects. Most of the time they see their own interest and make compromises. This is usually a red flag in such projects. I think this to me is like a rocket science, where we theoretically apply things but when it come to real life anything can go wrong. Sometime we oversee something minor in nature. That is what I meant by my comment above.
SMRs that consume waste, such as molten salt reactors designed by Copenhagen Atomics. might be a good solution for dealing with waste. Excellent video, but let's keep thinking positively.
Hey there! This is possible and currently studied/considered in some places. It can obviously save costs by using existing infrastructure. Not all coal plants are suitable but according to a study by the Department of Energy it would be about 300 existing and retired coal power plant sites in the US that could be converted.
I think the first discussed option is better from a long term perspective. Having an entity on which the whole of production is dependent is exactly what the two example countries are - soft authoritarian regimes
Unlike wind turbines and solar panels, that are sources of electricity in themselves, the reactor, modular or otherwise, is only the heat source that applies to the high temperature and pressure of the steam plasma required to drive the steam turbines that spin the alternators that feed the transformers that connect to the electricity grid.
One key advantage that wasn't mention in the video is their relation with the grid. A typical nuclear plant will need high voltage cables to serve a huge area while snr could work on lower voltage, smaller grids with no problem. great for small islands or energy intensive companies that don't want to rely on the grid like data enters
One of the reasons France's nuclear energy program has been so successful is that France developed a good design and then refined and improved the design over may units. The majority of France's nuclear power plants are the same basic design. Moderate in size and reliable. On the other hand the US industry had a race to build bigger and bigger reactors. The industry would make a few of a design and then jump to a new larger design. No feedback for the old design to improve. Just a race to the next bigger design.
Glad this video explained the cost side heavily. The promise of SMRs has essentially already failed--they've shown that they're no better cost-wise than our old nuclear plants which was always the problem. The simple fact of the matter is that wind/solar + batteries is already a cost-effective solution that's proven and available today, albeit in need of ramping capacity. SMRs likely still have a niche long term (e.g. commercial shipping, remote outposts), but it really doesn't make sense for the grid when wind/solar + batteries are already cheaper than fossil fuels, let alone nuclear.
All wind and solar energy have only 3% of accumulators power per MW of "green" power. That's change all. 13-15% is the transmission to another time zones. 20% is hydro energy balancing. 50% is fuel (gas, oil or coal) balancing. Only french nuclear reactors can change their power from 50% to 100% up to 200 times per year, but cost of that is 1.5x times more uranium for that.
Considering what's happening in Ukraine these small modular reactors makes a country less vulnerable to attacks. Also nuclear energy is way better for our health. Fossil power plants cause way more deaths every year.
I honestly find it hard to understand how subhumanly evil people have to be to think it's only worth protecting the planet and humanity if it makes a profit.
We use small nuclear reactors in naval vessels. I can imagine converting or replacing the merchant fleet of giant cargo and cruise ships to nuclear. At least they should connect to the local grid when at port so their existing fossil fuel reactors don't pollute the city.
South Africa has one functioning SMR at phelindaba we are actually the leaders in this space but this people don't even mention it because they always want to be seen as first on everything but in actual fact not clever enough.
SMR’s are inevitable, in small quantities, but they need to figure out how to bring the costs down as they’re far too expensive, especially compared to solar and wind + battery storage, to realize any mass scale. Solar + battery storage is so crazy inexpensive and reliable, nothing else can compete.
The biggest mistake in the Fukushima accident was that the emergency battery was installed underground, and seawater got into it. So I don't think all nuclear power generation is dangerous. I understand that Germany, which is close to Russia, has abolished nuclear power plants, but it is also true that CO2 is a stable gas, so it is very troublesome. Until a small nuclear reactor that can ensure safety is completed, we need to reduce electricity consumption at night when solar power is not generated.
We must raise up energy consumption at night to reduce energy losses in generation and transmission. Because of that at least 30% of cars will be electric or plugin electric after 2050
@doesnotcompute6078 you are taking about NEW cars, not ALL cars. It's impossible to exchange half billion old cars to new cars so fast. At least half of new cars will be hybrid
@doesnotcompute6078 no one will ban hybrids. Discounts will be decline after electric cars will reach limit 15% of all cars. There's not enough power and charging stations to serve 100% of electric cars. Limit is 30%. After that - electricity system will be unstable. ENTSO-E in Europe must be one piece of cake, not 6 pieces as now on. It means that every country must have at least 2-3 giant power cables to +/-2 time zones and 30% of backup power without any combusted fuel. It's impossible in 2050. Science and industry must get an incredible combination of accumulators and power generation in one piece, that can replace all parts of traditional generation. I can't believe that. Best strategy is "one quarter". 1/4 is new generation of nuclear reactors wich 50-100% regulated power more than 300 times per year (now there's no any in the world even in the project) - 25% is renewable energy generation (except hydro) - 25% is combined gas turbines / generators (20-30% hydrogen, 70-80% methane) - 25% is hydro energy
@doesnotcompute6078 so on with cars. Some countries like Brazil have methanol hybrid cars. Other have methane and propane/ butane (LPG) cars. Some concepts of ammonia cars are better than hydrogen cars. Some electric cars use sodium batteries So we can't define future of cars in 2050 only "electrical" It's just dreams
SMRs are more like cars, the first ones cost way more than the end product but once mass produced, they become very cheap, and have the potential to undercut all other options. Unlike renewables that struggle to integrate with the grid, need constant maintenance, need major parts replaced every 10-20 years, SMRs over the lifetime could actually be cheaper. The main issue is people still think of nuclear as bad, but if the truth was told, I think you’ll find nuclear is the greenest energy available. There is nothing green about Solar or wind if you look at what goes into them, and how often they need replacing.
1) Water cooling implies high pressure steam. And the need for a thick containment vessel to contain any cooling failure (high pressure steam == explosive failures). This choice is the #1 problem in legacy nuclear. Using ambient pressure cooling should be required (molten salt or equivalent). 2) In the US, we used-up our uranium decades ago. Uranium fuel comes from Russia. Does this sound like a good place to source your energy from? 3) The problem for SMRs is they are still too big. A typical Tesla can DC charge at 200 kilowatts. This should the target. 200 kilowatts electric means 300 kilowatts thermal. In Florida, have the charging throttle down automatically when the home air conditioning kicks-in. 4) The SMR building block should include electrical generation. I want a PNR (Personal Nuclear Reactor) available. Two pieces, each the size of a 50 gallon water heater. One piece is the reactor, the other piece is the electrical. Make this a building code requirement for any building, residential or commercial, over 5000 square feet. 5) Design and manufacture a much smaller 5000 watt electrical version PNR. Then pass a law that bans the use of portable gasoline generators on food trucks.
The energy produced from SMR literally available all year round. SMR + Molten salt battery is the best way forward for this time. Lithium battery and solar is the legacy systems of renewables. These are the future.
@@SocialDownclimber roof panels do not provide enough for the entire grid, sorry. Fact. Your local grocery store isn’t going to power itself from solar panels. My apartment isn’t going to power itself from solar panels Grid size Storage is also a major issue. We need reliable consistent energy from somewhere and nuclear is the answer. I’m not against solar. I just recognize we need more
I have a PhD in Physics. This is a good idea as a short term stop gap while we ramp up renewables and eventually get fusion up and running to save ourselves from screwing up our planet. However, there needs to be very rigorous safety procedures and no one has said what they are going to do with the inevitable nuclear waste from fission reactors that will be around for hundreds of thousands of years after we produce it.
The newer gen 4 waste only requires 500 years to cool down to ambient radiation levels. Some can go 30 years without changing fuel rods and have just one significant moving part using helium. They are small enough so their underground position can naturally cool the reactor if needed.
The salient point here is no-one has managed to build one economically yet. Fusion Power has been only a decade away since 1950, and despite billions in investment, we haven't made that either.
One 300MW reactor could power an island. It would be great for many of the island nations. Or an island such as Guam, who buys diesel fuel to power the island. Or countries such as Belize who buy all their power from Mexico.
8:40 The caption is wrong, she correctly says "per kilowatt-hour", but it's incorrectly captioned as "per kilowatt/hour". We typically measure energy in kWh, 1 kWh = 3600000 J.
1:36 "Civilization ending disasters"? Sounds a little dramatic when you see Chernobyl already being a tourist hotspot and Fukushima having people living near the power plant.
@doesnotcompute6078 you act like its the only polluted place in earth, and there not a million other inhabitable places that are toxic from mining or what not.
South Africa has a very advanced nuclear capability having tested and produced 6 atomic bombs which were declared and dismantled at the end of apartheid. In addition South Africa was the first country in the world to start research on SMR s about 30 years ago and is the worlds leading expert in this field. This research was done by the South African Nuclear Energy Corporation at Pelindaba Pretoria a government owned and one of the oldest nuclear research organisations in the world. Stratek Global has followed up on this research and has just signed up with an investor to manufacture a number of small privately owned nuclear reactors in SA the first probably at Pelindaba. In addition therr is a facility at Pelindaba that manufactures and supplies nuclear fuel that has already produced and will be supplying the nuclear fuel it would require to operate. According to the announcement two days ago construction is said to be going to start shortly. I am surprised that this was not mentioned in this report.
Nobody going to replace "big reactors" with SMRs. SMRs are for places where you have a distant city that require power. Even with all disadvantages of SMR in comparison to "big reactors" they are still better option if you simply don't have suitable ground to build a reactor or if you would like to add power generation gradually during developing of the region.
@@steinarnielsen8954 safest, but as monopolistic companies put profit before safety. I wouldn’t trust nuclear with a safety track record of say, Boeing
When Australia started building Snowy 2.0, a hydro storage facility, it was priced at around A$2bn. The price tag currently sits at around A$14bn, and there is no completion date, or if it will ever be finished. The fact the current opposition party is wanting to build SNR's if they win power, the say party that commissioned Snowy 2.0, pardon me for not believing them.
It's never going to have the energy to cause an accident and can be used in remote locations to generate a lot of power efficiently, while being very easy to quarantine in case of an accident. Seems perfect to me, outside of maybe economics of scale.
As is this whole video and channel it seems. Everything is BS designed not to inform but to introduce dour FUD aka Fear, Uncertainty, Doubt... It's the only thing DW traffics in these days...
@@timwoodruff5728 you know what. You are probably right :-) ... but, small self contained low bureaucracy nuclear reactors have the potential to disrupt petrol industry, but you are right they are probably not lobbying against it at this point.
Fossil fuel companies like SMRs right now because right wing governments and politicians are using the prospect of them coming “soon” to hold off on other renewable energy projects. The politicians say that solar or wind farms may wait or don’t have to happen because SMRs will be a silver bullet to solve the climate change problem and let us live our extravagant lifestyles.
SMRs can also easily be integrated with technologies that are energy consuming, e.g. SMR powered nuclear submarine. The SMR component can easily be automated (alone with the droned, nuclear powered submarine).
If anyone but China can deliver a Nuclear Power plant in time and budget even remotely close to the lifecycle kw cost of solar I might consider Nuclear Power to be viable, but even SMRs are way to expensive to be a good investment compared to solar + energy storage.
Nuclear plants are too expensive, take too long, are too fraught with uncertainty. Uncertainties as; cost overruns, delays, cancellations, accidents, natural disasters, war & terrorism. While solar, wind are cheap & growing very fast. Worldwide solar grew equal to 53 nuke plants in 2023. Even SMRs are 4 times more than the cost of energy now. Legacy nuclear is about 10 times more than solar and wind right now. Tax dollars should not be used to build SMRs. Private equity doesn't want to invest it because of all the uncertainty. The idea that reduced regulatory control is a way to make SMRs cheaper is just playing with fire. Go with solar and wind. It is what the market is doing. This year the US is not building any new coal plants, one nuclear plant and only a small amount of natural gas is being added. The rest, that is 96.5% of additions to electric generation, is wind and solar renewables, or renewable related, namely batteries. Putting 66.7 GW of wind, solar and batteries capacity online in one year is going to retire a lot of fossil fuel plants, as well as negate the need for nuclear. Nuclear at this junction is simply too slow, too expensive and too fraught with uncertainty to implement.
You can't fully substitute fossils with renewables, since they're not stable sources. When you have too much renewable power it doesn't actually provide any benefit, since its going to add even more energy during peak moments of the day but still be useless at night, for instance. You need some backup source that can cover the base load. And you can do that either with fossils or nuclear. Since we want to abandon fossils, the solution needed is pretty clear
@timwoodruff5728 yes of course, I wasn't saying renewable don't have any place in the energy sources cake graph. We need them, and we still have a pretty wide margin of deployment, but we can't hope to phase out fossils going 100% renewable. That base load must be covered by a stable and reliable source
Batteries are filling the gap that used to be occupied by base load power stations. There has always been a mismatch between demand cycles and generation. The graph that plotted demand was called the duck because of the way it looked. It showed low demand at night and the early morning rising up when people woke up, it dropped a little when people were at work and then would rise up again when people got home and turned on TVs, air conditioners, ovens etc. Most electricity used peaked in the evenings after work and then would go down again as people slept. This represents intermittency of demand. Power plants were built to meet peak demand with the rest of the time the plants were being underutilized. Utilities don't want demand to go beyond peak because that would mean they would have to build a new plant to meet demand that wouldn't be its most profitable until demand reached near peak again. Utilities would employ fast turn on peaker gas powered power plants to cover when demand would pass peak periodically. This was always very expensive. Peaker plants would just be standing by until needed and then they would charge the utilities lots of money so they could stay in business when they weren't needed. This was the old model. Base load barely existed since it was only viable for the amount of demand that electricity would drop to at night. Wind and solar plus batteries has created a new paradigm. With batteries power can produced at anytime as long as it is enough to cover all the demand for a few days. Demand can be anytime since matching that demand with batteries can be almost instant, unlike gas peaker plants that need time to start up. Right now places like California and Texas are producing more wind and solar than can be used during the day. Ever see wind turbines not turning? That is the utility curtailing wind turbine generation because there is too much electricity on the grid. The same happens with solar. With batteries all this curtailment can be stopped and the energy can be stored in batteries to be used when it is needed. It also can grow incrementally as demand grows without needing to spend the time and billions to build a whole new power plant. So, to answer your comment. Wind and solar can and does substitute for fossil fuels right now. New generation of wind and solar with batteries is set to be some 50 plus gigawatts in the US this year. Batteries matches both demand intermittency as well as generation intermittency. Wind and solar with batteries are winning the day.
If economics are the issue, why not use them for heat generation too? A lot of industrial processes need insanely high temperatures as part of the manufacturing process. It's a very good way of decarbonising industry while providing a revenue stream for the company researching and constructing them.
@@JeermynRex No? How is that the first thing that comes to your mind when there is the obvious application of using the heat from nuclear fission to process metals, synthetic fuels and desalination, and the generated neutrons to dope semiconductors?
Just make a 50% larger model, smaller than full scale reactor bigger than these SMR, should be more cost efficient while being small and easy to work on than large reactors
I don't see what the big deal is. We manufacture small reactors for years that are put in our submarine and ships. Reinventing the whole thing commercially vs government continuing with what they have been using safely for years is questionable. Allowing many to use the technology is an issue that I believe should be kept , at this point, under direct government control. Having power for the country is a matter of national security and should be controlled by the military [even if it's just the security of the plant]. Use an existing micropowerplant design and have the government install and operate. Keep our need to be dependent on outside countries fuel to power the country. When the units age we control scraping them vs private companies going bankrupt and leaving us to flip the bill anyway.
As good as that plan would be having that many reactors that the military have to monitor would be almost impossible with the personnel that are trained and training.
Actually the nuclear industry has been massively subsidised from the very start in many countries...France, UK, USA, Germany etc.. often through military strategic cross-subsidies like Calder Hall in the UK. If they had to work strictly "by the market" and pay adequate insurance and put money aside for the decomissioning of old plants and waste storage, I doubt a single plant would have been built.
I still think the biggest part of smaller reactors is the effect on public perception. If they can literally SHOW you a map that says, even if this WERE a reactor that could go critical, and it DID go that bad, the radiation and damage would literally only hit the government land around it, then every old person I know would be on board THAT DAY. And i do mean that literally. There is a coffee table in the farming town where I grew up, and my dad still goes there every morning. This conversation happened.
I've wondered why people's reactions to nuclear is to question its safety but nuclear powered warships have been criss crossing the earth for 50 years with barely a handful of incidents, and most of them in the early years. I've imagined for decades ship reactors on land, it's like following a bouncing ball.
Canada knows how to keep the fuel cool. We have decommissioned several reactors due to age. And replaced them,. Yes, there have been incidents but spilling heavy water certainly cant be compared to a meltdown .CANDU reactors are very safe in the business of heavy power generation. We have about 3 Stations on the Great Lakes --Bruce 6.61 MW on Lake Huron, Pickering 3.1 MW ,Darlington 3.1MW on Lake Ontario.@doesnotcompute6078
i think smaller nuclear plants may assist if there is an area to make a larger plant but there needs to be that a equal of those investing to have a consences of working together for the benefit and not for the money. Though they will need to see and have some part of control, it needs the old control to be balance so that all concerned are not tripping over each other's feet.
Smaller footprint than renewables, reliable, no CO2, helps with diversity of energy sources... You can add it to renewables, efficiency for the win as well
The energy produced from SMR literally available all year round. SMR + Molten salt battery is the best way forward for this time. Lithium battery and solar is the legacy systems of renewables. These are the future.
@@multienergico9299 Oh, ya, sure- great if you just ignore all the liabilities that have gone unconfronted for almost every nuclear power plant, ever. Nuclear power has a fatal flaw- people.
You need some statistics to prove your point .Nuclear is safer than you say. nobody has died from a properly built nuclear reactor. Chernobyl was built by the Russians from stolen plans for the CANDU reactor that were rejected because it was flawed and dangerous.. The Russians didn't care about quality and built it anyway.
Nuclear does not compete with renewable. They simply have different purposes. Our electric base load can't be covered by renewables, since they're not stable and reliable. The choice then is between fossils or nuclear. Since we want to abandon fossils, the solution looks pretty evident.
@@bose9618 inaccurate. Renewables and nuclear do compete. Cheap RE reduces profitability of nuclear when nuclear’s marginal price is above RE and is curtailed by grid operators. This is a problem in Europe currently. Please Google to find relevant news.
@@bose9618 *sigh* nuclear and renewables do compete. All tech in a grid competes because they bid in at their cost of operation plus a marginal profit which is regulated in each grid operators territory. In the EU, renewables bid in at $0 because they have zero cost of operation, and this causes nuclear curtailment. Google it. Nuclear had higher marginal cost. Renewables compete with everything higher than 0 marginal cost because they compress the dispatch stack’s value and depress marginal prices causing curtailment of higher cost sources.
@@timwoodruff5728 that doesnt change the fact that fossile fuels are flexible and nuclear is just baseload even if there is enough renewable capacity there
Historically, every town had their own power station with private profitable ownership. Centralisation was to gain cost benefit from much larger and fewer power stations within Government ownership. Large Nuclear power, reprocessing spent fuel and public safety had to be government. This all became too much for Governments. Governments eventually sold power plants and distribution to private ownership. Now, private owners want to revert to town local nuclear power plants, seeing profits. Progress is cyclic.
Want a nuclear plant in your backyard? Store waste for thousands of years after 30 years of energy? Insulation doesn’t melt down-neither does solar or wind or pumped hydro or…
If the proposed SMR is of 2nd generation, I agree with you. But technology has advanced and 4th generation nuclear power plants are using nuclear waste from the past as fuel, producing only a fraction as waste, and don’t need “fresh” uranium to work. In addition, by not using fresh water to cool but molten salt, as in example, there is no more possibility for meltdowns.
That's the description of 70s technology (the world moved on since then btw) and even by that standard during those years, nuclear triumph all tech solar, wind, geothemal, etc.
Nuclear waste is not that big of a deal: we produce it in very small quantities and we know how to safely and effectively deal with it. Plus, it won't be dangerous forever, unlike other toxic waste from several industries that we just "throw away" without even treating. And btw, nuclear power plants usually operate for more than 60 years. In many cases their licenses get extended to 80 or even more. 80 years of abundant, safe and clean energy.
What do you think of these small modular reactors?
cool if they will scale
The price of kilowatt per hour for them are too high, and it is rarely taken into account.
Don't work.
@@borystsolinthe hope is that being small, they can be made modular and thus reduce the cost significantly. Of course, if only one or two are built, then the price won't come down.
It's a bad idea. Better to develop solar, wind, and power storage - as well as energy efficiency standards.
Showing footage from a Boeing factory and emphasizing quality control is funny.
Really??? You don't think Boeing have good quality control?!!!
@@jamesgreig5168not anymore, they don’t. Unlike in the 1970s or ‘80s.
@@jamesgreig5168they killed a guy for speaking up about their quality
@@JohnGeorgeBauerBuis Maybe that was sarcasm. A plug door flying out due to someone forgetting to put some bolts in and inspection failing to catch missing bolts is quite the epic double-fail.
Pretty on brand for the nuclear industry actually. The nuclear industry has perhaps the most captured regulatory body of any energy technology on the planet. If regular people had any idea what actually goes on inside the worlds nuclear plants, they would demand that they all get shut down yesterday.
The comparison to airplane construction is unsettling with all the cost-cutting measures and skimping on safety that whistle-blowers are getting killed over...
Which whistle blowers have been killed? That sounds like another conspiracy theory sigh...
Airbus doing pretty good
@@kilo4911unlike Boeing.
airbus is a government company. a bit different than the other company
In as much as what you're saying is true you are just highlighting one particular manufacturer and trying to push the whole thing into some kind of conspiracy when in reality if you compare the amount of death from playing compare to the cars and other form order mobility airplane has achieved greater safety than most means of transportation the history of passenger airline proves it because any plane crash is a major headline and from search headline engineers learn and create safety and improved the reliability of air crafts.
What makes me crazy is that Three Mile Island was the nuclear disaster that could have been. But its always reported as a disaster that was. The incident caused a scare for sure with evacuations and concerns about released radiation but the containment building held and did its job of containing anything that escaped the reactor.
> But its always reported as a disaster that was.
That's because it is, for this type of reactor.
It was a nuclear incident, it most certainly wasn't a nuclear disaster.
You don't get to redefine words or domain terms, that is criminally stupid especially in a field that does some have inherent dangers to it and you should get no say on the topic if you cannot even agree to describe things as they are over what you fear or hope they ought to be
Then maybe look up the insane amount of negligence in both building and running it that resulted in the meltdown. We got lucky with 3 mile island. Safety rules were massively upgraded afterwards for a reason.
A meltdown is a complete loss of control and should never happen. If it happens there is no way of being certain if the structure will actually hold or just delay the inevitable.
My dear friend, you are talking logic to the ignorant, uneducated, and willfully illogical masses. We know nuclear is better and safer over the lifetime than fossil fuels - from extraction to consumption. Unfortunately the PR image that doomed it would require a strong leader to say to your average idiot voter, “We’re doing this whether you like it or not” and we don’t have any strong leaders like this anymore.
Yeaj, i watched the documentary series on netflix…mostly nothing, but a PR disaster. The china syndrome
Nuclear carrier reactors are comparable to SMRs. They have an outstanding safety record and probably billions of dollars have gone into studies and designs. Ford class output 700 megawatt but much of that energy is diverted to propulsion. But it seems a sound starting point instead of starting from scratch.
A previous potential safety feature of SMRs wasn't mentioned here. Yes, build them in factories, but install them in suitable holes. If one goes critical it's small effort to use remote control bulldozers to simply push dirt into the hole and seal off the radiation leakage.
Technically these are well within reach. The real problem is we can't get anything done anymore. It's all talk and arguments.
the real problem is money. nobody wants to loose money, and thats what happens if you invest in nuclear.
@@tjeulinknobody but the military. They would power their machines by literally burning money given an opportunity.
@@m1k3y_m1 i can get the military, they have different priorities than making money.
Problem with naval reactors is also that they usually use highly enriched Uranium, which is much more expensive and really not needed for a "simple" power plant. It's also weapons grade, so safety really is a concern there. I don't think these reactors by themselves would work in a stationary civilian setting, but they would probably be a good starting point if their design wasn't classified. That being said, the easiest and cheapest way of producing nuclear power is just like we are doing it now.
Nuclear reactors on ships are also manned by trained personnel just like in the big power plants. Having and managing the necessary personnel that would be scattered all over the place may be a big issue. Even if reactors can be mass produced, getting enough trained personnel is whole other issue.
DW mentions civilication ending disaster as a possibilility. That is hyperbole in the extreme.
That's the typical confusion between nuclear power and nuclear weapons.
its fear mongering, as if building 400 acres of wind farms to power a city the size of new york isn't gonna fuck the ecosystem
@@falsemcnuggethopenuclear weapons is a nuclear reactor that goes to fast.. or just the waste of a reactor spread to the environment
@@SunShine-xc6dhThat's just so wrong. Nuclear fuel is just so far from refinement needed for nuclear bombs so it's impossible for actual nuclear explosion to happen.
@@SunShine-xc6dh a nuclear weapon is a bomb that will explode. A nuclear reactor won't do that, because it's not a bomb. Nuclear power is statistically one of the safest ways to generate power.
The problem for Nuscale is its hideously expensive pool, not the reactors themselves. The reactors are modular ... but the pool is not.
Why is its pool so expensive?
@@theDaNi0 ua-cam.com/video/twMZJSMTqBo/v-deo.html
@@theDaNi0 google "nuscale new problems, decouple media"
@@theDaNi0 sensors + earthquake measurements + overflow measurements + leakage protection + heat protection + protection from potential airstrike (yes all nuclear plants have this) and so on
Nuscale is a pressurized light-water reactor. In other words, junk.
I'm no expert but here in the USA after Three Mile Island Congress enacted such difficult regulations to comply with that nobody could build a new power plant without violating the law somehow. I worked in the industry briefly in the 90s at a place that built power plants and it was if time had stopped after TMI. All the outstanding orders for new power plants were cancelled, most people quit or were laid off and a skeleton crew carried the load. The company eventually collapsed. I'd love to see new nuclear power plants in the USA but we need to change the laws so its possible and economical to build and operate them.
Stop being scared of nuclear energy!
Nuh uh
stop being scared period. Thorium reactor are safe and could immediately end all of our psyop agendas related to the fake climate change naradigm, designed to enslave humanity to the demonic forces of hell.
Hey there! We actually took a closer look at Thorium nuclear energy some months ago. Check out our video 👉 ua-cam.com/video/Km6kqykX900/v-deo.html We are curious to hear what you think.
I look at the people building nuclear and then I think of the dimwits that will end up in charge of safety so no I'm fine with my radiophobia just where it is.
Problem with people is that most of them are to lazy to start using their own brain. They just think on the foundation that mass media though them. Farm animals pretty much. No critical thinking, no evaluation of potential and risk, no strive for individual growth .
There are almost 200 small modular reactors operating with a 100% safety record for 65 years, all over the world. Huh? Yes, on ships, almost all military. No one thinks twice about getting aboard a nuclear ship or having one in port.
But oh, the Chicken Littles!
Some are nuclear powered... And nuclear armed!
If you like some horror look into Abandoned Sovjet nuclear batteries (RTG's).
Except those are not designed to be cost effective. Which is why they are only used for submarines and the largest of aircraft carriers. There are hints that the newest A1B reactor might have potential for civilian power production, but good luck getting Bechtel and the USN to share.
@@anticarrrot Jesus Krist. My point was that we already have hundreds of small reactors in long, successful service. Cost effectiveness is not in the conversation.
@frequentlycynical642
Well actually... The video is about cost effectiveness
Well actually... A lot of those reactors quite famously don't have 100% safety record
Well actually... Nations have barred nuclear vessels from their ports, and lots of people think twice before boarding one - mostly because of the 'ticket price'.
And great Flying Noodly Spaghetti Monster, watch the fucking profanity
The reason SMRs are so expensive is that the development costs are being paid for by just a few units. If the designs work and are reliable, then many more SMRs can be built spreading the development costs over many more units. Government research grants to pay the development costs make sense.
If only the worlds military budget is used for science and innovation. (Ex. $30B Nasa vs $815B US military, 27x of nasa’s budget. )
We already terraformed mars by now and stopped human climate change/Global Warming through clean energy.
The true cost should include the safe storage of nuclear waste for 100s of years and the decommissioning costs which are probably around the same or more as building them in the first place. In the UK renewables (mostly wind and solar) account for between a third and half the generated electricity for much of the time. Thankfully coal is zero to 1.5%. Amazing progress from the days when most power was from coal.
There are 4 of them being built right beside each other not far from Toronto. The first one will be be finished by the end of the decade. So come 2030 it'll start being feasable to scale them.
@@Katniss0000stop living in a fantasy 🤣 your able to fantasies like this because military keeps you safe.
SMRs are most practical in space (moon and mars), and in desolate environments. Unlike their bigger counterpart, they can more easily be 'automated'. With SMRs you can quite easily build a reliable power source in desolate environments like the moon and Mars, etc (Titan - Saturn's moon).
Nuclear Waste can be recycled! SMR's can produce power, heat, and hydrogen. The technology for decarbonization exist, you just have implement it.
You have to think about the money. Imagine holding a billion dollars... and betting that "solar/wind + storage" is going to be more expensive in 10-15 years than your nuclear technology (an industry know for massive time and cost over-runs). You honestly wouldn't do it.
The waste has to be modified to work. It's not like a trash bin lorry where you can put everything in and you are good to go.
yes and plastic can be recycled too, yet we have the great ocean garbage patch. that somthing is theoretically possible has nothing to do with it being practically possible.
All 4 generation reactors can use or recycle more than 50% of nuclear waste to the nuclear fuel.
All of them can use at least twice recycled nuclear fuel.
All fast reactors can produce more nuclear fuel than got
It's basics.
@@1968ChristiaanFrance decarbonized electricity in 15 years with 1970s reactor technology and has the cheapest electricity in Europe. You're nuts.
I am strongly against not pursuing nuclear out of fear. That is just nuts. There is zero chance we reach climate goals without the consistent energy from nuclear
I broadly agree, but when I start hearing folks in the nuclear industry talk about "unesscessary regulatory burdens" it's difficult to trust. People forget that nuclear power workers aren't just neutral experts here to provide the best opinions, they are financially invested in the success of nuclear power even if it means making something that isn't safe. The problem is the margin of error is such that, if those cost inflating regulations aren't followed, even small disasters can leave radioactive products that are really expensive to clean up. Honestly, I think people forget that other industries with similar environmental impacts like chemical processing plants or former mining operations really ought to have had these kinds of regulations too, but we see what happens when companies can just pull out and leave their trash behind, and the results are horrifying even when it's not radioactive byproducts causing the environmental impact. The sad part here is that these non nuclear impacts often go ignored. We're not doing ourselves any favors if we replace one shitty polluting system of energy and industry with another that just pollutes differently. Honestly, this is why I think that any kind of green energy initiative that fails to also address the problems of late stage capitalism (i.e. needing to run a profit on carbon neutral energy) isn't going to work out. That's the piece that I think some nuclear power advocates miss out on. It becomes a sort of tunnel vision that is honestly just as driven by the fear of climate change, which is a valid fear to be sure, but which ignores the possibility of substituting one shitty future for another. Let's just not pick shitty futures? Socialize energy production.
Fourth generation Nuclear power plants, small, reliable. No meltdowns, re-usage of nuclear waste from the past, small and modular. These are the goals for a return of nuclear as power source. You are right, the public may reject the technology out of fear, from past disasters. But they don’t think that the Superphenix has been working for 30/40 years now, and there are 54 active Nuclear power plants in the US
@@saturationstation1446 Mind you, from the known nuclear disasters, there were zero (0) casualties in Fukushima. The other tragedies happened due to human error or cost saving measures. On average, water dams do more harm than nuclear, and people don't seem to fear them?
@@cavemann_ I fear water dams. I definitely wouldn't want to live downstream from one.
ITs fine .I have one across the road about a mile away-- Darlington - 3 reactors and a SMR under construction, 35 years and no problems.@@saturationstation1446
"Rigorous quality control" when speaking of aircraft manufacturing. That quote didn't age very well :D
for airbus sure, not for boing lol
Actually it did. Flying is by far the safest mode of transport.
@@steinarnielsen8954boeing
"You Must Construct Additional Pylons!"
"Not enough minerals."
"Nuclear launch detected"
"Thank god for cold fusion."
I'm still banking on Last Energy being the ones to break the SMR barrier first. Using mostly off-the-shelf parts from mature oil/gas industry supply chains is brilliant, and should finally allow for true enough standardization to actually get the cost per reactor way down.
SMRs are everywhere as we speak, how many ships and subs are nuclear powered ?
Not to mention how many are planned or under construction? Dozens...
Many ports and countries ban nuclear vessels from docking, or only docking at designated areas.
@@adamdavies6248True. But I think this is misguided considering the excellent safety record of nuclear powered ships. What really should be banned is filthy oil-burning ships - especially cruise ships - that produce a huge amount of local pollution.
So, how much do they cost per megawatt?
@@SocialDownclimbercan you share more about the differences?
In case of nuclear power economy of scale means lots of output power. SMRs need everything a large reactor has, so the savings are not there. Same counts for wind energy as well, so we see wind turbines get bigger and bigger.
The reason wind turbines get bigger and bigger is the higher and more stable wind speed at greater height.
thanks for your report, I find it balanced for the short timeframe. I believe that bigger nuclear power plants are the way to make an impact (both in terms of energy baseline and low CO2 emissions), while, as you pointed out, SMRs can have a niche application to energy-intensive industries that need additional energy capabilities (e.g. for steel production). All in all, the implicit good news is that investment is rising after decades of negligence - and with high investments comes high innovation, just as it was for solar and wind. Perhaps in the next video you can highlight the investments in EU and the Countries that plan to start or expand their civilian nuclear fleet. Thanks!
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“In any system of energy, Control is what consumes energy the most.
No energy store holds enough energy to extract an amount of energy equal to the total energy it stores.
No system of energy can deliver sum useful energy in excess of the total energy put into constructing it.
This universal truth applies to all systems.
Energy, like time, flows from past to future” (2017).
A good all round analysis. Thanks for this presentation
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"like airplanes with high safety regulations" Boeing 👀👀👀👀 😂
The fact that ensuring profit seems to be seen as more important than stopping global warming is quite sad.
That is true and continues to be true for fossil fuel industry. But there are much cheaper and safer alternatives than nuclear for the grid. Like the giant fusion reactor we get for free in the sky.
@@beyondfossil I too am a big fan of solar energy but as long as we are not able to store solar energy long term we are reliant on backup power plants and for places where hydro and geothermal aren't an option nuclear energy could come into play.
@@mrkokolore6187 Sure, and the grid scale problem is actively being worked on.
Furthermore, the more renewables production that comes online, then the more research & investments will be put into accelerating the growth of grid storage industry -- a positive feedback loop.
At 99.9% the mass of the solar system and 173,000 terawatts peak energy flux to the Earth, the sun daily provides several orders of magnitude we use every day. Less than 1% of the world's land surface covered in current generation solar panels could power all the grids. There is enough offshore wind to power the world several times over. There is always some combination of sun and wind in most places where most of world's populations tend to be located.
Keep nuclear for military and special scientific applications. Because the next 10 years will be pivotal to change course in our fossil fuel dependency. Whereas a single nuclear power plant can take 10+ years from inception to becoming online and operational. Pursuing nuclear at this critical juncture will have negative impacts on timeline.
@@mrkokolore6187 The grid storage problem is being actively worked on. Plenty of information on that online. The more renewables that come online, the more the grid storage industries grows.
(Looks like UA-cam failed to post my other reply)
@@beyondfossil Yeah, I am aware of the continuous work on energy storage. For me pumped hydro and thermal energy storage(i.e., sand or molten salt) seem to be the most promising solutions. Perhaps also sodium-ion batteries. I also heard of a method where you convert iron oxide into iron metal with excess energy and burn it back to iron oxide when you need more power. All interesting and cool concepts. Don't know if they will be ready soon enough tho. Especially with fossil fuels still being dirt cheap. The problem is the focus on profit and fossil fuels sadly seem to still be very profitable.
Smaller grids would be more efficient too. What about Navy reactors?
Imagine if energy was free or at least extremely extremely cheap. Life would be so less stressful
Too bad we have to pay for the sun. The plants and trees must be rich to pay that bill.
@@markae0 It's the lithium miners and their neighbors in developing countries who are paying :/
Well, not for energy sector execs 👍🏼
This is a great solution for grid balancing and remote locations, hopefully we will see it more and more 😊❤❤
Do you know how crazy effective this would be for farmers? I live in Canada. It’s cold. Can’t grow anything 1/4 of the year even tho I’m in one of the warmest zones.
With those reactors as a power supply, you can run massive greenhouses. Large enough to grow things like bananas, citrus, custard apples, tropical plants that normally can’t be grown anywhere near Canada. All at a large scale. Large enough to make the food cheaper, with the benefit of being fresh.
I am not sure if you watched the video, but it clearly said the energy from those is more expensive than current sources
Definitely worth continued experimentation. Not just for our immediate energy needs today, but also for space explorations of tomorrow. Many NASA probes (such as Curiousity) are powered by nuclear energy, and I can imagine many ships humanity sends (crewed or non-crewed) will absolutely require nuclear energy sources out in the infinite void where we won't have anything else.
Very cool! :)
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Who are "people"? I wouldn't want to live anywhere near one of these things. Nuclear fission is a very poor way to make electricity, and today it's also one of the most expensive means of electricity production.
Some other people. 😜 What about, would you consider fusion? We made a video on it you can watch here 👉 ua-cam.com/video/eyHovWQ49MI/v-deo.html
We could straight up solve our energy problems if we built more nuclear power plants. It’s 100% green energy.
Not 100% green if you consider the energy required to build them and the toxic nuclear waste that has to be stored for 100s of years and the energy used in mining and processing the uranium fuel etc
I know you want to be part of the conversation but if you are just repeating the talking point of the video without even Googling if what you are repeating is true or not then you are just wasting time.
@@Alphachewei nuclear fission power could greatly solve much of our world’s energy needs. It doesn’t require nearly as much mining and extraction as coal and fossil fuels, it emits zero greenhouse gasses, and all of the waste products it produces are all stored in containers. Whereas fossil fuel waste is vented into the atmosphere. Unfortunately the hurdle for nuclear power is political and a scientifically ignorant population of people. As for the video, it’s saying that rather building huge costly nuclear facilities that can take a decade to permit and develop, large energy-consuming businesses can build a new generation ultra efficient on-site reactor for their energy needs.
@@ralpharmsby8040 Nuclear waste isn't a yellow barrel full of green goo, by the way.
Better than fossil fuels coal is terrible for the environment
Pretty weird looking fusion core, probably couldn’t power my power armor
The problem with SRMs is that they don't have the economics of scale of traditional larger nuclear plants. So the energy production from them needs to be subsidized
energy production from nuclear already has to be subsidized, for SMR its just even more. wind and solar are economically viable on their own.
Thsts why we need large modular reactors and loans guaranteed at the government bond rate.
@@gregorymalchuk272 sounds a lot like socialism
@@tjeulink It sounds like vertically integrated public utilities.
That's not true, there is no need for subsidies you are clearly a European though lol. SMR's (Not SRMs) are still cheaper then fossil fuel and provide reliable backbone power, you can over build it and dump the waste energy into CO2 collectors to recapture the CO2 we've released. The thing keeping their costs up is the fact nuclear power especially SMR's aren't the mainstream thus they don't have the economics of scale. All we gotta do is build SMR factories and get the fuel cheap. Thorium SMR's are my favorite as they're physically resistant to meltdowns without needing active cooling.
Safe by design, in most cases means liquified metal (like lead) not water. Because it nearly impossible to heat up lead to make it waporize and even when lead leaves reactor it will get solid fast. Also, rods in the ractor are moving down (stoping the ractor) without power application to maintain its position.
As much as I support nuclear energy SMRs never seemed a too bright idea. You have great economy of scale with the normal size, the site has to be specially monitored and defended wheter it produce 300MW or 3-4GW. Same with the infrastructure. Also they use more material, the same capacity may requires more personnel. As long as they plan to install many of them at the same site it isn'treally worth it, and if they don't then there is the problem of botth the nuclear waste, and vulnerable infrastructure being too disperesed.
I think the best advantage is the modularity.
Who's going to put down billions in investment and wait at least 5 years to see an NPP running.
MSRs allow piecemeal expansion. Oh, your energy needs expanded by a few hundred MW? Just add one more reactor to the plant.
As opposed to adding gigawatts and spending billions for every reactor.
@@anxiousearth680 Only in theory. In practice, you end up needing a bigger turbine, possibly more power line, and other equipments. You also shut down the facility cause you "install an upgrade", regulators has to check the new parts, you need instrumentation, controlls and ppl for the new reactor. You have to prove with tests that the new one did not change the current characteristics of your installation significantly, and now you have to run all of them on a capacity that justifies the new one, with its added costs, manifacture, maintenence extra staff and permitting. The problem is, you end up redoing everything for addign like 50-100MW which in many case can be done as a major upgrade on an existing higher capacity plant. And while at it, you better just build another big one, jump through the hoops once and add another 1000-1200 MW.
I love A SMR!
In Australia SMRs are already widely employed specifically to extend the life of coal and gas generation - miners, media & right wing politicians tell the punters that SMRs are almost available and will deliver cheap, hassle free electricity and so renewable projects should be handbraked to leave the market open until such time as we can build them all.
Rubbish. They are not employed in Australia. Name one place they are 'employed in Australia.
11:30 Absolutely nightmare scenario...
Here is one issue I have with these SMR related videos. Virtually none of them, including this one, had pointed out that SMRs absolutely work and we have decades of experience. Just look at all the nuclear submarines and aircraft carriers. Since the 50's there have been over 160 nuclear naval vessels built, and every single one of them is powered by a SMR.
@@astebbin I shall argue the 2 points you made are perhaps erroneous.
1. Enrichment Levels:
Naval nuclear reactors runs on military grade enriched fuels of over 93% enrichment. The proposed SMRs run on HALEU grade of no more than 20% enrichment. It is simply far too low to be weapons grade. The much lowered enrichment level also serves as an extra level of safeguard to the already stellar safety records of naval SMRs.
2. Proliferation:
This seems to be the go-to argument for much of the anti-nuclear energy crowd, but it is simply incorrect. As a matter of fact, commercial nuclear energy generation is the best proven way to denuclearize one's military arsenal. To prevent Soviet nukes falling into the wrong hands after the collapse of the USSR, the Megatons to Megawatts Program was put in place from 1993 till the Russian invasion of Crimea. The program decommissioned an equivalent of 20,008 or 45% of total stockpiled nuclear warheads by the USSR. The decommissioned warheads were then downblended into commercial reactor fuel. During those 20 years, 10% of total US electricity generation came from those "recycled" Soviet warheads. If anything, it should be argued that commercial nuclear energy generation has greatly served the propose of anti-proliferation.
@@astebbinthat isn’t a requirement, though, and that fuel is currently used for supply-chain reasons.
And at least hundreds of navy soldiers lose their hairs
They should look into reactors that use thorium instead of uranium. Thorium cannot be used for bombs.
Also, the SNR concept includes burying the reactor to begin with. A thief trying to steal the nuclear material could be stopped long before the reactor has been unearthed.
@@astebbin 57% of global carbon emissions come from countries that already have nuclear weapons and aren't a proliferation concern.
In Canada we have a pilot SMR in production. It is a pilot project heavily focused on safety and it's current price is estimated at CAD$2.5Billion and produces 10MW of power. It is estimated that the price can drop to 1 tenth ie: CAD$250Million for 10MW of power.
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Now for comparison, we have recently (2024) completed a 10MW solar farm for CAD$16million. We also have a project that includes Battery Electric Storage System(BESS) and 40MW solar farm for about CAD40 to 50million and guarantee at least 10MW 24/7.
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No way SMR can ever compare to a solar/BESS combo. Most importantly keep in mind that the SMR is still over the Billion Dollar mark. and 'projected to drop'.
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We have the means to a clean future.... the only reason SMRs are entertained is the clear fear that solar can quickly become mini-grids or even home scale use... meaning large corporations will not be able to make money out of mega scale energy as they do today. This is happening today in Spain and there is currently mega political turnoil as a consequnce..
What are the cause and effect if something goes wrong?
What do you mean in specific thats a vague question. Im going to assume you mean what are the cause and effects interms of negative consequences in the event of a critical emergency or other hazardous incident causing a nuclear radiation leak. The most obvious solution is that because the smr radioactive components are inside the smr then it would be super easy to just take it offline and then take it to a nuclear disposal site (which is safe since we have solved alot of the issues around when the famous disasters happened and when nuclear energy was being debated to replace fossil fuels)
Besides progress in nuclear powers safety which make anything like like the famous incidents like chernobyl & fukishima. Now we have systems that have many failsafes and such.
But in specific to smrs their design is so that the risk is minimized in the first place but if and when something goes wrong they are both not big enough sources of radiation to be more than a local incident, as well as many of them being underground and shielded by concrete. If that fails its very very easy to shut the smr off and then move the entire thing to a nuclear waste disposal site. If youarent aware already we have actually solved the issue of nuclear waste watch kyle hill's video titled "weve already solved nuclear waste" since they can explain it much better than i could. But the smr is designed so that the whole unit can be easily moved so that means if it becomes problematic it can be moved to a safe disposal site where it wont pose any dangers to humanity or even that local area wher it went wrong or even the workers at the disposal site. In fact, in the video I recommended kyle hill literally kisses nuclear waste containers and stands rigjt by them because he knows its safe. No protective equiptment either just plain clothes.
I can try and specifically answer any questions you might have if you specify what you mean but i hope this eas enough of an answer for you. Also i hopeyou check out the video so you arent just relying on my word and you can see for yourself.
@@anarcho.femboyism wow. This is what I wanted to know 👍😀. Thanks for this long wonderful explanation. I have seen the video from kyle after you asked me to and yes. I will complete the video. No me it is bit worrying when everytime governments are involved and funding projects. Most of the time they see their own interest and make compromises. This is usually a red flag in such projects. I think this to me is like a rocket science, where we theoretically apply things but when it come to real life anything can go wrong. Sometime we oversee something minor in nature. That is what I meant by my comment above.
a cause will be the thing to blame, if an effect appears ofc! 🤔🤫
Just like any nuclear power plant. Nuclear meltdown and end up like Chernobyl where the land is not usable for decades.
@@AkihikoJunichi sarcasm?
SMRs that consume waste, such as molten salt reactors designed by Copenhagen Atomics. might be a good solution for dealing with waste. Excellent video, but let's keep thinking positively.
Couldnt we just convert coal plants that are planned to be shut down into nuclear energy plants to recoup costs
Hey there! This is possible and currently studied/considered in some places. It can obviously save costs by using existing infrastructure. Not all coal plants are suitable but according to a study by the Department of Energy it would be about 300 existing and retired coal power plant sites in the US that could be converted.
@@DWPlanetA wen kümmert die usa?! deutsche kraftwerke!
@DWPlanetA okay that's fucking awesome thanks for the info i really appreciate
I think the first discussed option is better from a long term perspective. Having an entity on which the whole of production is dependent is exactly what the two example countries are - soft authoritarian regimes
"the quality control are the same as airliners".
well at least in this case doors won't fall from the sky.
Airbus has a high quality control standard compared to the airplanes of the US ;)
Unlike wind turbines and solar panels, that are sources of electricity in themselves, the reactor, modular or otherwise, is only the heat source that applies to the high temperature and pressure of the steam plasma required to drive the steam turbines that spin the alternators that feed the transformers that connect to the electricity grid.
One key advantage that wasn't mention in the video is their relation with the grid. A typical nuclear plant will need high voltage cables to serve a huge area while snr could work on lower voltage, smaller grids with no problem. great for small islands or energy intensive companies that don't want to rely on the grid like data enters
One of the reasons France's nuclear energy program has been so successful is that France developed a good design and then refined and improved the design over may units. The majority of France's nuclear power plants are the same basic design. Moderate in size and reliable.
On the other hand the US industry had a race to build bigger and bigger reactors. The industry would make a few of a design and then jump to a new larger design. No feedback for the old design to improve. Just a race to the next bigger design.
Glad this video explained the cost side heavily. The promise of SMRs has essentially already failed--they've shown that they're no better cost-wise than our old nuclear plants which was always the problem. The simple fact of the matter is that wind/solar + batteries is already a cost-effective solution that's proven and available today, albeit in need of ramping capacity. SMRs likely still have a niche long term (e.g. commercial shipping, remote outposts), but it really doesn't make sense for the grid when wind/solar + batteries are already cheaper than fossil fuels, let alone nuclear.
what are you talking about, batteries are insanely expensive, to power a city when there is not sun/wind is either nuclear or fossil fuels
@@mggaming4624 thats what grid interconnects are for. it barely happens that there is no sun or wind.
All wind and solar energy have only 3% of accumulators power per MW of "green" power.
That's change all.
13-15% is the transmission to another time zones.
20% is hydro energy balancing.
50% is fuel (gas, oil or coal) balancing.
Only french nuclear reactors can change their power from 50% to 100% up to 200 times per year, but cost of that is 1.5x times more uranium for that.
@@astebbinCivilian reactors can't produce weapons grade plutonium. They produce contaminated reactor grade plutonium.
Considering what's happening in Ukraine these small modular reactors makes a country less vulnerable to attacks.
Also nuclear energy is way better for our health. Fossil power plants cause way more deaths every year.
I honestly find it hard to understand how subhumanly evil people have to be to think it's only worth protecting the planet and humanity if it makes a profit.
They are world class grifters so they know a grift when they see one..
So why haven't you done anything for society?
@@edenassosbecause they're not a billionaire
@@kaden-sd6vbthat would require making profits, which aren't important apparently
@@edenassos deranged thing to say to someone
We use small nuclear reactors in naval vessels. I can imagine converting or replacing the merchant fleet of giant cargo and cruise ships to nuclear. At least they should connect to the local grid when at port so their existing fossil fuel reactors don't pollute the city.
Everything is built from scratch doesn't matter if it's big or small it's built from something - that does not determine its danger
The danger comes from giving profiteers access to the power of the sun.
As a Sputh African, this would be big for us.
South Africa has one functioning SMR at phelindaba we are actually the leaders in this space but this people don't even mention it because they always want to be seen as first on everything but in actual fact not clever enough.
SMR’s are inevitable, in small quantities, but they need to figure out how to bring the costs down as they’re far too expensive, especially compared to solar and wind + battery storage, to realize any mass scale. Solar + battery storage is so crazy inexpensive and reliable, nothing else can compete.
3:39 aircraft manufacturing has high QC,
Boeing : what is QC 😂😂😂
We can put them inside cities and use the exhaust steam for heating, process heat, and refrigeration.
The biggest mistake in the Fukushima accident was that the emergency battery was installed underground, and seawater got into it.
So I don't think all nuclear power generation is dangerous.
I understand that Germany, which is close to Russia, has abolished nuclear power plants, but it is also true that CO2 is a stable gas, so it is very troublesome.
Until a small nuclear reactor that can ensure safety is completed, we need to reduce electricity consumption at night when solar power is not generated.
We must raise up energy consumption at night to reduce energy losses in generation and transmission.
Because of that at least 30% of cars will be electric or plugin electric after 2050
@doesnotcompute6078 you are taking about NEW cars, not ALL cars.
It's impossible to exchange half billion old cars to new cars so fast.
At least half of new cars will be hybrid
@doesnotcompute6078 no one will ban hybrids.
Discounts will be decline after electric cars will reach limit 15% of all cars.
There's not enough power and charging stations to serve 100% of electric cars.
Limit is 30%. After that - electricity system will be unstable.
ENTSO-E in Europe must be one piece of cake, not 6 pieces as now on. It means that every country must have at least 2-3 giant power cables to +/-2 time zones and 30% of backup power without any combusted fuel.
It's impossible in 2050.
Science and industry must get an incredible combination of accumulators and power generation in one piece, that can replace all parts of traditional generation.
I can't believe that.
Best strategy is "one quarter".
1/4 is new generation of nuclear reactors wich 50-100% regulated power more than 300 times per year (now there's no any in the world even in the project)
- 25% is renewable energy generation (except hydro)
- 25% is combined gas turbines / generators (20-30% hydrogen, 70-80% methane)
- 25% is hydro energy
@doesnotcompute6078 so on with cars.
Some countries like Brazil have methanol hybrid cars.
Other have methane and propane/ butane (LPG) cars.
Some concepts of ammonia cars are better than hydrogen cars.
Some electric cars use sodium batteries
So we can't define future of cars in 2050 only "electrical"
It's just dreams
Europe, especially Germany, is in very bad shape.
SMRs are more like cars, the first ones cost way more than the end product but once mass produced, they become very cheap, and have the potential to undercut all other options. Unlike renewables that struggle to integrate with the grid, need constant maintenance, need major parts replaced every 10-20 years, SMRs over the lifetime could actually be cheaper. The main issue is people still think of nuclear as bad, but if the truth was told, I think you’ll find nuclear is the greenest energy available. There is nothing green about Solar or wind if you look at what goes into them, and how often they need replacing.
Why not build 10 of these SMRs on the same land? You make profits and probably reduce risks🤷🏾♂️
because it isn't profitable.
Because cost per MW is 120$ and higher.
It's good for Alaska or Island but not for other world
I get it though. I believe the more SMRs built, the cheaper their components are gonna cost. And in the long run become profitable.
1) Water cooling implies high pressure steam. And the need for a thick containment vessel to contain any cooling failure (high pressure steam == explosive failures). This choice is the #1 problem in legacy nuclear. Using ambient pressure cooling should be required (molten salt or equivalent).
2) In the US, we used-up our uranium decades ago. Uranium fuel comes from Russia. Does this sound like a good place to source your energy from?
3) The problem for SMRs is they are still too big. A typical Tesla can DC charge at 200 kilowatts. This should the target. 200 kilowatts electric means 300 kilowatts thermal. In Florida, have the charging throttle down automatically when the home air conditioning kicks-in.
4) The SMR building block should include electrical generation. I want a PNR (Personal Nuclear Reactor) available. Two pieces, each the size of a 50 gallon water heater. One piece is the reactor, the other piece is the electrical. Make this a building code requirement for any building, residential or commercial, over 5000 square feet.
5) Design and manufacture a much smaller 5000 watt electrical version PNR. Then pass a law that bans the use of portable gasoline generators on food trucks.
The energy produced from SMR literally available all year round. SMR + Molten salt battery is the best way forward for this time. Lithium battery and solar is the legacy systems of renewables. These are the future.
The waste and risk will not just be "available all year round", but for many generations to come.
@@mavigogunwrong
@@SocialDownclimber it’s not for personal use. A small reactor can still power hundreds or more homes. Your roof solar panel won’t do that.
@@SocialDownclimber you’re not the only person who needs power
@@SocialDownclimber roof panels do not provide enough for the entire grid, sorry. Fact. Your local grocery store isn’t going to power itself from solar panels. My apartment isn’t going to power itself from solar panels
Grid size Storage is also a major issue.
We need reliable consistent energy from somewhere and nuclear is the answer.
I’m not against solar. I just recognize we need more
I have a PhD in Physics. This is a good idea as a short term stop gap while we ramp up renewables and eventually get fusion up and running to save ourselves from screwing up our planet. However, there needs to be very rigorous safety procedures and no one has said what they are going to do with the inevitable nuclear waste from fission reactors that will be around for hundreds of thousands of years after we produce it.
The newer gen 4 waste only requires 500 years to cool down to ambient radiation levels. Some can go 30 years without changing fuel rods and have just one significant moving part using helium. They are small enough so their underground position can naturally cool the reactor if needed.
The salient point here is no-one has managed to build one economically yet.
Fusion Power has been only a decade away since 1950, and despite billions in investment, we haven't made that either.
One 300MW reactor could power an island. It would be great for many of the island nations. Or an island such as Guam, who buys diesel fuel to power the island. Or countries such as Belize who buy all their power from Mexico.
How to spot a scam/money grab 101:
"it promises to fix all the problems with..."
8:40 The caption is wrong, she correctly says "per kilowatt-hour", but it's incorrectly captioned as "per kilowatt/hour". We typically measure energy in kWh, 1 kWh = 3600000 J.
Good eye! Thanks for the correction! 😊
1:36 "Civilization ending disasters"? Sounds a little dramatic when you see Chernobyl already being a tourist hotspot and Fukushima having people living near the power plant.
Chernobyl is a hotspot alright.
Fool.
@@saturationstation1446 Are you ok?
Hyperbole is the only thing DW excels at these days...
@doesnotcompute6078 you act like its the only polluted place in earth, and there not a million other inhabitable places that are toxic from mining or what not.
This is a good idea !
South Africa has a very advanced nuclear capability having tested and produced 6 atomic bombs which were declared and dismantled at the end of apartheid. In addition South Africa was the first country in the world to start research on SMR s about 30 years ago and is the worlds leading expert in this field. This research was done by the South African Nuclear Energy Corporation at Pelindaba Pretoria a government owned and one of the oldest nuclear research organisations in the world.
Stratek Global has followed up on this research and has just signed up with an investor to manufacture a number of small privately owned nuclear reactors in SA the first probably at Pelindaba.
In addition therr is a facility at Pelindaba that manufactures and supplies nuclear fuel that has already produced and will be supplying the nuclear fuel it would require to operate.
According to the announcement two days ago construction is said to be going to start shortly.
I am surprised that this was not mentioned in this report.
Great we'll see how it works out!
Nobody going to replace "big reactors" with SMRs. SMRs are for places where you have a distant city that require power. Even with all disadvantages of SMR in comparison to "big reactors" they are still better option if you simply don't have suitable ground to build a reactor or if you would like to add power generation gradually during developing of the region.
The comparison to airliners hasn’t aged well
Actually it did. Airliners are the safest mode of transport.
@@steinarnielsen8954 safest, but as monopolistic companies put profit before safety. I wouldn’t trust nuclear with a safety track record of say, Boeing
@@brianschwarm8267 Compare the safety track record of Boeing with any car manufacturer. Talk about profit before safety.
When Australia started building Snowy 2.0, a hydro storage facility, it was priced at around A$2bn. The price tag currently sits at around A$14bn, and there is no completion date, or if it will ever be finished. The fact the current opposition party is wanting to build SNR's if they win power, the say party that commissioned Snowy 2.0, pardon me for not believing them.
It's never going to have the energy to cause an accident and can be used in remote locations to generate a lot of power efficiently, while being very easy to quarantine in case of an accident.
Seems perfect to me, outside of maybe economics of scale.
Economic investigator Frank G Melbourne Australia is following this informative content cheers Frank 😊
There is a lot pressure from big oil against clean energy such as this.
As is this whole video and channel it seems. Everything is BS designed not to inform but to introduce dour FUD aka Fear, Uncertainty, Doubt... It's the only thing DW traffics in these days...
@@timwoodruff5728 you know what. You are probably right :-) ... but, small self contained low bureaucracy nuclear reactors have the potential to disrupt petrol industry, but you are right they are probably not lobbying against it at this point.
Fossil fuel companies like SMRs right now because right wing governments and politicians are using the prospect of them coming “soon” to hold off on other renewable energy projects. The politicians say that solar or wind farms may wait or don’t have to happen because SMRs will be a silver bullet to solve the climate change problem and let us live our extravagant lifestyles.
"With a Geiger Counter in my hand, I'm going out to stake me some government land.
Uuuuran-ium feeever has done and got me down"
Japanese people don't want new one anymore. Where will it be going to build?
SMRs can also easily be integrated with technologies that are energy consuming, e.g. SMR powered nuclear submarine. The SMR component can easily be automated (alone with the droned, nuclear powered submarine).
If anyone but China can deliver a Nuclear Power plant in time and budget even remotely close to the lifecycle kw cost of solar I might consider Nuclear Power to be viable, but even SMRs are way to expensive to be a good investment compared to solar + energy storage.
Solar energy and storage are more expensive than the most expensive nuclear electricity ever.
We've been promised "neighborhood" reactors for a while and we need these things up and running ASAP
Nuclear plants are too expensive, take too long, are too fraught with uncertainty. Uncertainties as; cost overruns, delays, cancellations, accidents, natural disasters, war & terrorism. While solar, wind are cheap & growing very fast. Worldwide solar grew equal to 53 nuke plants in 2023. Even SMRs are 4 times more than the cost of energy now. Legacy nuclear is about 10 times more than solar and wind right now. Tax dollars should not be used to build SMRs. Private equity doesn't want to invest it because of all the uncertainty. The idea that reduced regulatory control is a way to make SMRs cheaper is just playing with fire.
Go with solar and wind. It is what the market is doing. This year the US is not building any new coal plants, one nuclear plant and only a small amount of natural gas is being added. The rest, that is 96.5% of additions to electric generation, is wind and solar renewables, or renewable related, namely batteries. Putting 66.7 GW of wind, solar and batteries capacity online in one year is going to retire a lot of fossil fuel plants, as well as negate the need for nuclear. Nuclear at this junction is simply too slow, too expensive and too fraught with uncertainty to implement.
You can't fully substitute fossils with renewables, since they're not stable sources. When you have too much renewable power it doesn't actually provide any benefit, since its going to add even more energy during peak moments of the day but still be useless at night, for instance.
You need some backup source that can cover the base load. And you can do that either with fossils or nuclear. Since we want to abandon fossils, the solution needed is pretty clear
@timwoodruff5728 yes of course, I wasn't saying renewable don't have any place in the energy sources cake graph. We need them, and we still have a pretty wide margin of deployment, but we can't hope to phase out fossils going 100% renewable. That base load must be covered by a stable and reliable source
Batteries are filling the gap that used to be occupied by base load power stations. There has always been a mismatch between demand cycles and generation. The graph that plotted demand was called the duck because of the way it looked. It showed low demand at night and the early morning rising up when people woke up, it dropped a little when people were at work and then would rise up again when people got home and turned on TVs, air conditioners, ovens etc. Most electricity used peaked in the evenings after work and then would go down again as people slept. This represents intermittency of demand. Power plants were built to meet peak demand with the rest of the time the plants were being underutilized. Utilities don't want demand to go beyond peak because that would mean they would have to build a new plant to meet demand that wouldn't be its most profitable until demand reached near peak again. Utilities would employ fast turn on peaker gas powered power plants to cover when demand would pass peak periodically. This was always very expensive. Peaker plants would just be standing by until needed and then they would charge the utilities lots of money so they could stay in business when they weren't needed. This was the old model. Base load barely existed since it was only viable for the amount of demand that electricity would drop to at night.
Wind and solar plus batteries has created a new paradigm. With batteries power can produced at anytime as long as it is enough to cover all the demand for a few days. Demand can be anytime since matching that demand with batteries can be almost instant, unlike gas peaker plants that need time to start up. Right now places like California and Texas are producing more wind and solar than can be used during the day. Ever see wind turbines not turning? That is the utility curtailing wind turbine generation because there is too much electricity on the grid. The same happens with solar. With batteries all this curtailment can be stopped and the energy can be stored in batteries to be used when it is needed. It also can grow incrementally as demand grows without needing to spend the time and billions to build a whole new power plant.
So, to answer your comment. Wind and solar can and does substitute for fossil fuels right now. New generation of wind and solar with batteries is set to be some 50 plus gigawatts in the US this year. Batteries matches both demand intermittency as well as generation intermittency. Wind and solar with batteries are winning the day.
If economics are the issue, why not use them for heat generation too? A lot of industrial processes need insanely high temperatures as part of the manufacturing process. It's a very good way of decarbonising industry while providing a revenue stream for the company researching and constructing them.
Exaclty. Sell the exhaust steam for space heating, process heat, and absorption refrigeration.
Using the gamma rays to bake bread or what?
@@JeermynRex No? How is that the first thing that comes to your mind when there is the obvious application of using the heat from nuclear fission to process metals, synthetic fuels and desalination, and the generated neutrons to dope semiconductors?
I'm putting an SMR in my bathroom 😂
Just make a 50% larger model, smaller than full scale reactor bigger than these SMR, should be more cost efficient while being small and easy to work on than large reactors
So too large for serial production, but too small to make a profit when built one by one. Bright idea!
Being afraid of nuclear power is like being afraid of airplanes.
I don't see what the big deal is. We manufacture small reactors for years that are put in our submarine and ships. Reinventing the whole thing commercially vs government continuing with what they have been using safely for years is questionable. Allowing many to use the technology is an issue that I believe should be kept , at this point, under direct government control. Having power for the country is a matter of national security and should be controlled by the military [even if it's just the security of the plant]. Use an existing micropowerplant design and have the government install and operate. Keep our need to be dependent on outside countries fuel to power the country. When the units age we control scraping them vs private companies going bankrupt and leaving us to flip the bill anyway.
As good as that plan would be having that many reactors that the military have to monitor would be almost impossible with the personnel that are trained and training.
It’s sad that the US and EU cant change their view on profitability and just invest and subsidize SMRs.
Actually the nuclear industry has been massively subsidised from the very start in many countries...France, UK, USA, Germany etc.. often through military strategic cross-subsidies like Calder Hall in the UK. If they had to work strictly "by the market" and pay adequate insurance and put money aside for the decomissioning of old plants and waste storage, I doubt a single plant would have been built.
@@1968Christiaan oh I didn’t know that, thank you. Still though, it’s imperative to surviving and fighting climate change that we actually build more.
I still think the biggest part of smaller reactors is the effect on public perception. If they can literally SHOW you a map that says, even if this WERE a reactor that could go critical, and it DID go that bad, the radiation and damage would literally only hit the government land around it, then every old person I know would be on board THAT DAY. And i do mean that literally. There is a coffee table in the farming town where I grew up, and my dad still goes there every morning. This conversation happened.
The reason this isn't happening is US petrodollar hegemony.
I've wondered why people's reactions to nuclear is to question its safety but nuclear powered warships have been criss crossing the earth for 50 years with barely a handful of incidents, and most of them in the early years. I've imagined for decades ship reactors on land, it's like following a bouncing ball.
Imagine if humanity eventually don't exist anymore, and what outcome/s may occur when all the backups fails to keep the reactors nice and cool?......🤔
SMRs are safer than you think. The mistakes you point out are learning curves. This one is smaller safer and better.
Canada knows how to keep the fuel cool. We have decommissioned several reactors due to age. And replaced them,. Yes, there have been incidents but spilling heavy water certainly cant be compared to a meltdown .CANDU reactors are very safe in the business of heavy power generation. We have about 3 Stations on the Great Lakes --Bruce 6.61 MW on Lake Huron, Pickering 3.1 MW ,Darlington 3.1MW on Lake Ontario.@doesnotcompute6078
not much honestly
If humanity doesn't exist nothing matters anymore.
i think smaller nuclear plants may assist if there is an area to make a larger plant but there needs to be that a equal of those investing to have a consences of working together for the benefit and not for the money. Though they will need to see and have some part of control, it needs the old control to be balance so that all concerned are not tripping over each other's feet.
SMRs suck. Dirtier, more dangerous, more expensive and more nuclear targets everywhere. Renewables and efficiency for the win.
Smaller footprint than renewables, reliable, no CO2, helps with diversity of energy sources... You can add it to renewables, efficiency for the win as well
You have a lot to say about something you clearly know nothing about
The energy produced from SMR literally available all year round. SMR + Molten salt battery is the best way forward for this time. Lithium battery and solar is the legacy systems of renewables. These are the future.
@@multienergico9299 Oh, ya, sure- great if you just ignore all the liabilities that have gone unconfronted for almost every nuclear power plant, ever. Nuclear power has a fatal flaw- people.
You need some statistics to prove your point .Nuclear is safer than you say. nobody has died from a properly built nuclear reactor. Chernobyl was built by the Russians from stolen plans for the CANDU reactor that were rejected because it was flawed and dangerous.. The Russians didn't care about quality and built it anyway.
Forget SMRs. Just build full size ones. Especially if it's going to be cheaper and more efficient
We need to focus on renewable instead of technologys that does not even exist nowadays
Nuclear does not compete with renewable. They simply have different purposes.
Our electric base load can't be covered by renewables, since they're not stable and reliable. The choice then is between fossils or nuclear. Since we want to abandon fossils, the solution looks pretty evident.
@@bose9618 false. Fossile Fuels are not for baseload but for peak times. So dont write before knowing anything about the topic
@@bose9618 inaccurate. Renewables and nuclear do compete. Cheap RE reduces profitability of nuclear when nuclear’s marginal price is above RE and is curtailed by grid operators. This is a problem in Europe currently. Please Google to find relevant news.
@@bose9618 *sigh* nuclear and renewables do compete. All tech in a grid competes because they bid in at their cost of operation plus a marginal profit which is regulated in each grid operators territory. In the EU, renewables bid in at $0 because they have zero cost of operation, and this causes nuclear curtailment. Google it. Nuclear had higher marginal cost. Renewables compete with everything higher than 0 marginal cost because they compress the dispatch stack’s value and depress marginal prices causing curtailment of higher cost sources.
@@timwoodruff5728 that doesnt change the fact that fossile fuels are flexible and nuclear is just baseload even if there is enough renewable capacity there
Historically, every town had their own power station with private profitable ownership.
Centralisation was to gain cost benefit from much larger and fewer power stations within Government ownership.
Large Nuclear power, reprocessing spent fuel and public safety had to be government.
This all became too much for Governments.
Governments eventually sold power plants and distribution to private ownership.
Now, private owners want to revert to town local nuclear power plants, seeing profits.
Progress is cyclic.
Want a nuclear plant in your backyard? Store waste for thousands of years after 30 years of energy? Insulation doesn’t melt down-neither does solar or wind or pumped hydro or…
If the proposed SMR is of 2nd generation, I agree with you. But technology has advanced and 4th generation nuclear power plants are using nuclear waste from the past as fuel, producing only a fraction as waste, and don’t need “fresh” uranium to work. In addition, by not using fresh water to cool but molten salt, as in example, there is no more possibility for meltdowns.
That's the description of 70s technology (the world moved on since then btw) and even by that standard during those years, nuclear triumph all tech solar, wind, geothemal, etc.
Nuclear waste is not that big of a deal: we produce it in very small quantities and we know how to safely and effectively deal with it. Plus, it won't be dangerous forever, unlike other toxic waste from several industries that we just "throw away" without even treating.
And btw, nuclear power plants usually operate for more than 60 years. In many cases their licenses get extended to 80 or even more.
80 years of abundant, safe and clean energy.
What if a team of security will be needed 24×7×52, for 30 years. to hinder green terrorist, from attacking the plant, eg tesla plant in Germany
How fear of nuclear power is hurting the environment. ( Michael Shellenberger at TEDSummit )