Many years ago I had a neighbor, Paul Kunming, who was a retired Westinghouse nuclear power engineer. He said Westinghouse made a major error by not incorporating desalination plants with nuclear power plants. If coastal cities could have a water supply, they'd want nuclear power plants.
It totally makes sense to use waste heat from the cooling system to power the desalination process. The solution for excess heat being dumped from nuclear plants on the ocean was right there ! use it to remove the salt, and have fresh drinking water.
Utilities would have retired them if they were included. The vast majority of US based Nukes have water purification plant. They are very rarely used and most plant have abandoned their purification systems. Instead most nuke sites rents RO trailers from GE or other 3rd party companies and use city water for the feed.
@@mikeall7012 I'm not referring to the small water purification systems have for use by their processes. I mean large scale plants to supply water for domestic and agricultural use. As in, the power plant would be the municipal supply.
Had 3 separate msf plants on the cruise ship I worked on. It utilized waste heat from the main engines, so our water production would scale with ship speed(engine load)
Three days after leaving Sydney on a cruise ship we noticed our cups of tea tasted slightly salty. That was because the fresh water taken on in Port Jackson had been used up and we were now using desalinated water. No problem, we changed over to coffee and didn't notice a salty taste again.
One fact in favor of nuclear power should be pointed out: radioactivity is very easy to measure. Much easier than any other contaminant in water. It's a non issue.
A very helpful fact when one of your nuclear plants goes full Fukushima and you can tell the world exactly how much contaminated seawater you have released into the ocean 😄
@@BuddyLee23 Try to measure how many lives were lost due to Germany switching off their nuclear reactors and ramping up their coal and gas stations, fuelled with stuff bought from tyrannical countries around the world, who then went on to invest their euro profits in to guns, wars, murder and genocide - pretty hard to measure.
@@BuddyLee23 no much after a while because of how humongous the ocean is actually. The waters are constantly moving as well. The average levels lowers down to an insignificant one not too long afterwards.
@@BuddyLee23 If you believe that Fukushima made a meaningful impact in contaminating our oceans in the topic of making drinking water, you have a lot to learn about the amount of contamination released by Fukushima. Sure a part of ocean sealife suffered from the contamination, but it is far from the catastrophe the media has painted.
One interesting note, dedicated desalination reactors can be MUCH cheaper than energy-generating reactors. That's because they don't need to pressurize the water to keep it liquid at very high temperatures. A desalination reactor can just pressurize water to just 4 atmospheres, raising the boiling point to about 140C. 4 atmospheres is easy to work with, it's less than the pressure in your faucet.
@@AlexBesogonov If people keep pushing towards electric vehicles for short range travel and commute, the transition can cause more strain to the power grid than green energy can keep up and have to resort to other fuel sources for on-demand power or baseline power. Hybrid systems are never cheap, but they make efficient use of resources by not letting the work go to waste. Using nuclear or other waste heat generating sources made for other purposes to desalinate water is more useful than you think. We don't get to have geothermal power or desalination unlike some countries, so best you count your blessings before you lose them.
Alex and Aereto, you are both correct. We need both water and power. If we can push the use of nuclear for water product and have plant operate cheaply and with out issue, we can finally maybe change the public relation of nuclear is bad. Then we can talk about getting nuclear power online which is the only way to get off fossil fuels.
"...pressure in your faucet" uh, maybe in your country, but not in mine. only 2 ATM. sucks too, cause it used to be higher before "water saving measures"
I've been saying this for years - In California, PG&E should work with the sate water agencies to repurpose Diablo Canyon for desalination. Pump the fresh water generated up over the coastal range and into the California Aqueduct.
@@davidlangford1165 they won't. They are useful idiots to push half baked technologies that wouldn't and couldn't stand on their own yet, and increase energy profits.
They still have San Onofre sitting there doing nothing. A couple new small modular reactors and a desal plant instead of the old broken steam generators and they'd be in business. Then pump the brine up and over the mountains and store it in the Salton Sea. The containment buildings are still in place at San Onofre, just need the reactors to stick inside.
@@blastermanr6359 kind of. The pumping requirements are not trivial. It takes a lot of electricity to do it, but the engineering part is pretty well established at this point. It's more a political and financial problem.
Our rejection of Nuclear power was a massive mistake, and the environment has payed dearly for it as we continue to rely on fossil fuels for our electricity
There needs to be a solution for the waste. Burying it isn’t good enough. Reactors that re use the waste that results in a shorter half life seems to be just talk.
@@TheBooban nuclear waste is still much better than all the fossil fuel waste we've had. There's also a lot of research into nuclear fuel reprocessing such as hollow fiber ionic liquid reduction exchange process.
fun thing about historical fictions is that you never actually know what the outcome would have been if history played out differently. To assume there would be no issues with nuclear if we fully embraced it, I think is naive.
@@thefbat5847 only reason nuclear waste isn't as big a deal as fossil fuel waste is that nuclear only accounts for a small fraction of our total energy consumption.
I used to operate an MED for the purpose of concentrating grape juice. Kinda bothered me that we dumped millions of gallons of process water from the juice, as well as thousands of gallons of Ethanol down the drain. It costs a fairly good amount in wastewater treatment and i just think its stupid to dump fuel down the drain. This type of inefficiency is everywhere across food industry and i hope it gets some attention.
Another exceptional video, with excellent dictation. Your mastery of English is better than most native English speakers. Keep doing what you do in your style, its very much appreciated. Thank you.
@@Asianometry You're not a native English speaker? I knew you lived in Taiwan but I thought that English must be your first language because you have no accent at all (that I can recognise at least)
@@Asianometry There is another desalination technology - Humidification-Dehumidification. Here is a video - how it works and how it is better than traditional desalination tech. Would you like to talk about new tech on your channel? ua-cam.com/video/NzdNwKBVXT8/v-deo.html
I'm surprised in countries that have deserts there aren't even an prototype of concentrated solar desalination plant. Edit: I see in the replies many people miss understood what i mean, i don't mean solar panels. Concentrated solar is made with mirrors pointed to an object in this example massive glass dome filled with water.
Are you talking direct evaporation from concentrated solar, or are you talking about using concentrated solar to high yield solar cells? The energy needed to evaporate a cubic meter of water is 627kWh. This figure ignores heating the water, as you need only 91kWh to get from 20 to 100degrees, and that figure is dwarfed by the energy needed to evaporate the water. The energy needed to create 1 cubic meter of desalinated water from seawater through reverse osmosis is 2.5-4.0kWh. This is at least 150x times better. Why you need nuclear for this is beyond me, any country that needs desalinated water has excellent solar irradiation, and RO can happily be run only when excess energy is available.
@@luc_libv_verhaegen problem is water systems have to run 24-7 so you need a baseline, not strictly a deal breaker though, plus ideally you'd be desalinating to fill reservoirs to help with shortages
@@luc_libv_verhaegen I think, start/stop cycles will destroy the equipment. Or at least make it really hard to pay off, since "excess" is only a few hours per day.
It's a no-brainer. The inherent safety and compactness of MSRs, along with their very high heat output, make them ideal for all sorts of industrial processes. Much of industry like steel etc needs heat rather than electricity
I wish we could split the planet for pro nuclear and anti nuclear people. The pro nuclear side would quickly go to a lot more fresh water, probably cheaper energy over the long run, generally progress... let's add hydrogen production to that and move to hydrogen cars while we're at it. Then a while after we can leave the planet with the anti-nuclear peeps...
Newer Molten Salt Reactors operate at higher temperatures, 450-650 range. Combining this with CO2 gas generators, which have as intake temperatures roughly around the same temperatures 500+ degrees, also means that the temperatures of the output of these generators is around 250 to 300 degrees. This allows for a even higher energy transfer efficiency than older PWR reactors. Furthermore, even the temperatures that come out of an MSR are warm enough as is to generate Hydrogen without first having to turn the heat into electricity (eliminating the efficiency loses related to heat to electricity process) so high water production, and, large hydrogen production (which is emissions-free), Now the hydrogen can be used as is for hydrogen based transport, however, going one step further and implementing Carbon Capture, and combining CO2 and Hydrogen can allow you to make synthetic fuels (pure, gasoline, kerosene, diesel). And this let me tell you is a holy grail moment. While still producing CO2, this synthetic fuel burns cleanly (no impurities based from refinement) and burns more potently, critically, it is cyclical in nature, you take CO2 out of the atmosphere (or out of the oceans) and then release it back into the atmosphere, it is net-zero. And the key difference is simple and highly attractive; we don't need to reinvent anything to make it work. This Fuel can be used in our current infrastructure as is... Airplanes, Shipping boats, Public Transport, personal transportation; all of this becomes carbon-neutral overnight, without the necessity or expenditure to change the entire fleet of transportation methods (which in itself constitutes a burden in the form of emissions and pollution, as we are retiring the older fleet before its lifecycle ends) Another fundamental win from this is opening up a market to which we can base our Carbon Capture too... Currently, we can capture tons and tons of CO2 from the atmosphere... but there is no market large enough to sell it too... meaning the Carbon Capture will never be a profit driven industry... however synthetic fuels however flip this... creates a market, allows Carbon Capture companies sell their CO2 to fund the construction of more carbon capture... once we have displaced all fossil fuels from the transport industry alone (fossil fuel power plants make no sense to convert to synthetic fuels) (at this point also technology and scale also has driven down the cost of Carbon Capture) governments can impose a carbon storage quota, 70% of what is captured is destined for synthetic fuel production, and the remaining 30% is for storage; thus now motivating the construction of more carbon capture and finally beginning the process of CO2 reduction in the atmosphere. Carbon Capture is energy intensive, and thus requires a large quantity of stably available electricity which is emissions-free, which again leads perfectly into the hands of Nuclear Energy...
@@victorhopper6774 why isnt it sustainable? I mean the ICC and most other reputable scientists already stated that simple reduction and complete net zero carbon emissions isnt going to be enough anymore. In essence weve started a chain reaction already as is where Carbon capture is the only way to reverse and undo the chain reaction... Actually i have 2 questions; Why do you think it isnt sustainable? And, what do you understand with unsustainable?
@@Merreck0 beause life for humans requires oxygen at least 19% or we get goofier. we are at about 21 now.you have to keep freeing up the 02 for animals to survive so don't ''lock'' it up.
@@victorhopper6774 who says we would go beyond that? There are about 200 years worth of industrial CO2 in the sky, and the first stage is to make it net-zero... which is the cyclical nature of synthetic fuel. If we dont store any of it at all, then we break even because we release it again... Only when we decide to store it do we capture and lock it down, the reality is your right, but we do need to remove atleast the 200 years of CO2 from the industrial revolution from the atmosphere... and noone said we would push beyond that, we dont have too, we are balancing our intake of CO2 with our output.
The thing is the tritium limits are just decided randomly without any scientific basis. Even with australian levels they haven't proved tritium is dangerous to health.
Salt cooled nuclear in 1973, well I didn't know the tech was that old. They are working full speed on the molten salt reactors now. Definitely the best method of desalination.
Just to underline kokofan's point: Sodium does not equal salt. Sodium here refers to pure, metallic Sodium, not a compound that includes Sodium such as Sodium-Chloride a.k.a tablesalt. That being said, the US operated the world's first Molten-Salt Reactor in the 1960's at Oak Ridge, Tennessee.
Modern desal plants are up to 90% water recoveries these days - very impressive. That minimises the input flow as well as the sea critters it effects. You then combine the brine outflow with the treated sewage outflows and bingo bango. Let's roll.
@@nealtauss1715 Every city and it's surround catchment is a significant surface area. A great majority of a modern city is covered with concrete/bitumen/smooth surfaces that have minimal water take-up. That means a lot of rainfall tends to end up as storm surge or in the associated seaward discharge systems of that city. Probably all of that water is not good enough quality to drink however it is ideal to dilute any saline/brine from a desal plant with some simple storage/surge capacity. Thus you should be able to offset the brine production through dilution from sewage/water runoff systems.
@@AstroGremlinAmerican don’t joke, this is a real environnemental concern arround the dessalanisation plants. But yes of course n1 priority is still global warming.
No mention of graphene or graphene oxide desalination? This relatively new technology basically stacks layers of graphene or graphene oxide close enough together for water molecules to pass through but block virtually everything else, without the high pressure required for reverse osmosis.
He did make a passing reference to "other membranes technologies". From an energy magnitude perspective this in probably equivalent to RO in terms of power infrastructure?
He did make a passing reference to "other membranes technologies". From an energy magnitude perspective this in probably equivalent to RO in terms of power infrastructure?
Nuclear desalination makes great sense. Nuclear generates lotsa heat and can be used to boil water... cools down the vapor and get clean water, rinse repeat.
Nuclear power does make great sense as well, the problem is the handling and damage potential. With two prime examples and a lot less or unknow near catastrophic events I am happy not to have to rely on this option.
@@Monsterpala You will see a bigger catastrophe when war happens because of Energy... New reactors are made in a way where things like those two cases are impossible to happen....
@@Monsterpala 2 ejemplos buenos mis huevos, uno era un reactor militar pesimo (Chernobil) y el accidente de fukushima fue un evento sin precedentes, no este mamando. Buenas tardes.
It's rich in metals we need. Sodium is a promising new metal for battery tech that could replace lithium and is ubiquitous. Magnesium is a great building material similar to titanium. And other trace materials and chemicals can be harvested and sold to industry, such as chlorine.
@@Anenome5 Very expensive to take high saline desalination brine down to extraction of solutes. Then the salt needs to run an industrial process to separate the eg magnesium, Lithium and Sodium from the chlorine and each other. Very expensive, energy intensive. Dry salt deposits all over western N. And S. America's, very little mineral separation happening due to cost.
thank you for great work, i know this video took lots of your time to develop, thank you for your great work & all the great info in this video, god bless you.
Video doesn’t mention what happens to the salt after desalination.. if dumping it back in the ocean it increases the concentration and wrecks the ecosystem. It is another issue that needs to be addressed when these projects hit scale.
Good point, why not harvest the salt, we have a company here in SA that farms table salt from salt pans and exports brine. I have thought that if you were to cover the salt pans with glass houses you could have solar desalination by collecting the condensation and salt harvesting in one industry.
Worth considering, most domestic and industrial would end up back in the water waste stream. In most cases you would be looking at a net neutral salinity.
The desalination comes at a low price if it is thermally coproduced with electricity. The efficiency of the powerplant is only slightly reduced but you get the water for it.
Good video, I hope more people can design reactors to slowly but eventually replace coal and petroleum so they are only really used for plastics or classic cars.
I remember Jacque Fresco exhibiting a solar desalination plant that used a clear canopy over a canal to collect moisture from the evaporation off of water as it is heated by the sun, perfect for most equatorial zones. No energy plants required.
If not mistaken, based on what I read. The by-product produced by desalination is a concentrated salt water. Since we harvested the "fresh" water component, the by product which is the super salty water gets discharged into the sea. Eventually, the sea will become a "dead sea" and there goes our seafood.
No it won't for one simple reason. The water cycle. All the water we take from the ocean through desalination will eventually make it's way back to the ocean.
Yet another of my ideas has already been thought of but I was planning to send it into the middle of the desert to just be dumped there (that’s the only purpose (and free salt))
I think Finland follows now the EU directive mandating 100 Bq/l Tritium limit. It only make sense considering Finland is in EU the number of 30 000 is outdated.
There’s another environmental concern you haven’t mentioned. Desalination obviously doesn’t remove all the water from seawater and at the end of the process you have leftover brine. This brine typically gets pumped back into the seawater source which significantly increases local salinity at the region of the outflow but also in theory could increase the entire source’s salinity over time. Besides the obvious, immediate impacts this can have on complex sea life there’s reason to be concerned about the impact of creeping salinity on phytoplankton, which globally account for 50-80% of the world’s photosynthetic conversion of CO2 to O2.
What about using nuclear power to generate electricity to run a heat pump based desalination plant? Should be very efficient. The condenser side boils the water and the evaporator side of the heat pump condenses it back up. Probably very expensive though.
in any steam power plant, nuclear or coal, the condenser needs cooling water, and will heat the cooling water by 10-20F? I don't recall a ship-based plant tapping the hot-side of the condenser cooling water as source for desalination. There is a caveat, for plant water, desalination can occur at the lowest possible temperature and pressure (120-140F?). For drinking water, the desalination should occur at higher temp (180F?) and should tap seawater from further out.
For countries with excessive renewable power wouldn't it be cool to use the extra power for desalination instead of using battery storage? This creates water while reducing costs since you don't need batteries!
@@Planet_Xplorer I've seen more comments on batteries being used for excess power production, which is only a problem for coal/gas and apparently nuclear plants that take ages to react to changes in demand and need to keep running even when there is no demand. My understanding is that batteries are used to stabilize the grid if there is an outage like the one we had in SA when a tornado took out a main transmission line. The state government was ousted because of a perceived over reliance on renewable energy, when it came down to the Victorians not closing their interconnector. Elon Musk stepped up to the plate with the worlds biggest battery in Jamestown SA which helps stabilize the grid when you have a lot of wind and solar power which is intermittent.
Great Stuff! I was wondering if a ship based nuclear reactor could be used to provide energy for a mobile de-sal plant, for example on humanitarian missions via an form of deep-hulled vessel such as an amphibious assault ship? Would such a facility be effective, or even feasible?
Combing flash distillation with nuclear would be a good combo. In flash distillation, the brine is heated, not boiled. The brine would be at a higher pressure than the steam heating it, so any leaks will be from the seawater to the secondary loop, excluding tritium transfer from the secondary loop to the brine. Not so great for the plant now getting brine in the secondary loop, but great for keeping the product water radiation free.
Perhaps useful to think of a nuclear reactor + desalination plant as equivalent to a "peaker" power generation unit that can be operated 24/7 "for free" (uranium fuel and nuclear waste disposal being relatively inexpensive operating costs) with the electrical power that isn't needed by the electrical grid being put to productive use. Compare for example to a nuclear reactor + hydro power storage facility, feed nuclear reactor electricity into the grid when needed and use that electricity to pump water uphill the rest of the time. Such a combination is even more useful, but only works where the nuclear reactor can be built near a good site. Or compare to the notion of building dams in remote locations with the intention of using the electricity generated to smelt aluminum. The aluminum smelting plant and the desalination plant are similar: they both represent productive ways of using electricity where the nuclear power operator can control demand.
Good job analyzing the water problem from a stand point of current engineering. I think you made the case that thermal desalination powered by nuclear energy is doable right now, no break throughs required. However, I have my doubts that this will be significantly advanced in the near to medium term. There is too much fear of nuclear power. "Nuclear water" is not a tagline that sells. This is a shame because sea water desalination can be cost competitive with many current dam and irrigation projects. For perspective, the minimum theoretical energy required is less than 1 Kw/hr per M^3. Stated differently, reverse osmosis of sea water requires a pressure head of ~ 300 M. For comparison the California water project pumps water up 400 M over the Tehachapi mountains. Yes, pre-treatment is currently expensive. Yes, practical osmotic systems may require multiples of theoretical pressure. But, desalination is not that much more expensive than other alternatives.
It’s even better than dams. You’re yoinking a little water (relatively speaking) from the ocean, vs destroying hundreds to thousands of hectares of land… I dunno why environmentalists would ever be for such projects over nuclear-powered desalination but…welp.
You covered much of the same information that was in my senior project, the main difference was that I focused on the use of SMRs to reduce overnight cost and more specific to the task of water scarcity to meet climate change issues. I enjoyed your video, happy to see good information for a positive use for nuclear energy.
I probably missed this, but can these powerplants also generate power? Is the desalination only a byproduct of cooling down steam or these dont even contain turbines and generators?
It's easy to get caught up with scary sounding things like tritium, but it's important to remember the reason there is such wildly different environmental standards for it is that these are basically guesswork. We have no evidence for harm from it at low doses so they just pick a number that sounds good. We only have evidence of harm from extremely high doses and no one has ever had enough to kill them.
Risk factors are based upon statistical analysis, not guesses. Each tritium atom has the to potential to emit beta particles which are capable of damaging DNA if they collide. Cells with damaged DNA can turn cancerous. Statistical analysis is used to determine the probability of this event, and this is compared to an acceptable risk factor to determine the concentration of tritium, or any other potential toxin, will be allowed.
@@EDesigns_FL Sure but this is theoretical, if you take in to account DNA repair mechanisms and the lack of real evidence that these low doses actually cause cancer then the number they choose is still just a guess plucked from the air, extrapolated from high dose numbers without evidence.
@@EDesigns_FL I've heard several talks by Prof Geraldine Thomas who heads something called the Chernobyl Tissue Bank, and researches the toxicology of nuclear materials. She's quite adament that it's practically harmless in the concentrations that we could be talking about. The jist of her explanation is that: - The biological half-life of Tritium is around ten days (with some variation), while the nuclear half-life of Tritium is 14 years, so the chance that a given Tritium atom decays while inside your body is very low. - Not all beta emissions are created equal. Tritium's beta particles have particularly low energy. So even if it does decay inside your body, its damage is limited. Here's one of her appearances on the Decouple podcast: ua-cam.com/video/-KRthSSs370/v-deo.html
@@kokofan50 It might seem like that to someone who is not acquainted with how the analysis is conducted, but it's not. Physical testing is often done to verify models, but the advent of computer simulations has rendered this unnecessary for most work. That's how we were able to abolish testing of nuclear weapons. Likewise, computational flow dynamics and finite element analysis software and has rendered wind tunnel and physical testing unnecessary. It's all math.
Man, u're channel is awesome! Keep it going! The topics, the delivery. Not a typical "playing around" popular science channel :DI think I would l like to hear on Russia's perspective in the semiconductor industry since sanctions. Will it be able to do something with its Elbrus or not. And the breeder-reactors on fast neutrons. Just telling some (maybe) interesting ideas on future videos. Thanks!
Desalinated water is a solution to a lot of the worlds problems. It's a shame it hasn't become more widespread. People say it's too expensive, but the more we invest the cheaper it gets. I've seen proposals of solar powered Desal plants. Could even be used to change water tables and water cycles of otherwise dry regions. Just build water pipelines and pump excess fresh water.
Desalinated water is still very salty, unless perhaps you're to do the process several times until it's good enough to drink...but then it would make the water very expensive to produce. I worked in Saudi Arabia ang nobody drinks from the tap as the water is salty, we just used the water for bathing, cooking, washing clothes and other household needs.
@@Jarms48 I doubt you desalination plant produces as much volume as the Saudi plants do. As I have said the more you try to remove the saltiness, the more expensive is the process.
@@rap3208 Australia has 46 desalination plants across the country, we have more plants than Saudi but less production. Australia’s desalination process is more expensive than Saudi’s, which I presume is because it’s far more heavily treated. As I said, I never even tasted a difference here.
People are going to have to wake up about nuclear. It's far safer and pollution wise it's a no brainer. Yes when safety protocols and site placements are an afterthought, bad things happen. Those incidents while severe, are few and far between. Maybe someday we will find a better alternative but until then much like the fallout series, the future is the ⚛️!
@@TheHiddenPearl well to my recollection jobs were coming back to this country and gas wasn't 6 USD a gallon so ease enlighten me as to what facts were ignored and belittled? Thinking small minded people just spout and regurgitate info that is intellectually dishonest, but hey, what do I know, I'm just the chemically induced evil alter ego of a victorian scientist.
Amendment - in 1973, Kazakhstan was a Kazakh Autonomous Republic within the USSR and could not independently build a nuclear sodium reactor. This reactor was built by the USSR. The city was called Shevchenko in Soviet times, Aktau is a renaming after the independence of Kazakhstan. Kazakhstan became an independent country at the end of 1991. It still cannot build nuclear reactors. It is very surprising to see such blunders in the video.
The big problem with desalination is the host of imponderables-- like corrosion in the reactor coolant loops and corrosion in the brine loops. Everything looks fine from the outside until a pipe corrodes through or a valve gets stuck open or shut and then EVERYTHING has to be shut down for weeks, months, years, or forever. It's especially bad with sodium loops as the sodium remains radioactive for a very long time.
But the corrosive water won't be in the primary cooling loop of the reactor it will prob be in the secondary just like pressurised water reactors so how will the primary cooling loop of the reactor corrode ?
And in nuclear plants everything has back ups so if a valve gets stuck open or a pipe corrodes they can use backup valves and secondary other loops temporarily until the main ones are fixed that is just how Nuclear power plants in general work
@@alexandrosandreou8585 "Everything" has backups? Nope. I don't know of any reactor that has backup heat exchangers or main valves. Sometimes, there are dual pumps and dual generators but that's about it.
I thought this was a good idea 25 years ago. Seems a sensible use of excess power needs while simultaneously cooling reactors. In theory it would combat rising sea levels which just simply adding people (95% water) would not be enough to limit effects of melting ice. It all helps.
"In theory it would combat rising sea levels" My gut feeling is and guess (I've not checked the numbers) is the scale of the predicted sealevel rise far exceeds the amount of water we use/need. And it would just be a drop in the bucket.
@@Riskninjaz The sea level would sink about 0.0027778 mm with 10 billion extra people each containing 100 liters of water. With an average sea level rise of 2.3mm in a year that's about 10.5 hours worth of sea level rise that is prevented.
Have to start somewhere. A lot of water will be required for irrigation of crops needed to feed us all and for animal husbandry. Yet I can see the anti nuclear crowd having a problem with this.
If sea levels start to demonstrably rise then this withdrawal won’t be sufficient to counter it. But fortunately that doesn’t yet appear to be observably happening.
Regarding the risk of nuclear contamination of the drinking water, would it be possible to just use the electricity generated from a nuclear power plant to power the desalinization plant eliminating all risk of nuclear contamination, as the nuclear components would never come into contact even remotely with the water?
i'm very curious if anyone has looked into using concentrated solar (mirrors, heat tower and molten metal) to conduct desalination. Seems very viable in any dry, hot desert region with access to the coast. The middle east and baja california come to mind.
Concentrated solar required a lot of area outside and exposed to temperature fluctuations and weather. Because many working parts are outdoor and spread out, it cost a lot of maintenance cost. That's why people put machine indoors and close together, because stuff will degrade slower, easy to travel when fixing, less money spent buying sparepart and hire less workers.
@@ImaskarDono Concentrated Solar is very strong and all the energy required comes from the Sun. Solar power towers can heat salts up to 1000DegC which can then be pumped to evaporation ponds or green houses to distill salt water.
Crazy to me how nuclear is coming back to the energy debate, seeing how much safer things have become and watching the whole fossil fuel thing play out. I do hope for our future that serious thought is given to going nuclear in a bigger way.
Why do you need multiple stages for a multistage flash? Once water is boiled and condensed, it is pure right? It seems to me one stage would be sufficient.
It's a winning combination. I used to be a nuke on a US Navy submarine. The reactor is just a heat source that doesn't require hydrocarbons like oil, gas or coal. Under pressure, the very hot water from the nuclear plant is pumped inside the tubes of a steam generator that makes the steam and sends it out of the reactor compartment in secondary piping (WITHOUT radioactivity) to drive turbines to make electricity. It's a simple thing to branch off some auxiliary steam to make fresh water from sea water as we did underway. We could produce about 10 thousand gallons of fresh water daily in the 1970s which was more than enough for the power plant and potable water for a crew of 140 men. Nuclear plants should be built in seismically quiet coastal areas with associated desalinization plants to make surrounding communities and regions plenty of fresh water. By the way, when you see those big cooling towers emitting huge plumes of environmentally safe steam, remember that all this heat energy is just being wasted to the atmosphere when instead, just a small portion of this non-utilized energy resource could be used in auxiliary capacities like desalinization that could benefit the utilities as a secondary but significant source of revenue in terms of the overall nuclear power plant's business model.
What happened to the waste brine? I know for large industrial desalination there's enough to throw off local salinity levels if it's dumped back into the ocean
@@hotmailcompany52 at sea, obviously this isn't a problem for a submarine BUT you bring up a good point for a stationary desalination plant onshore. I'm not an expert but it does seem reasonable to engineer an undersea pipe for about 2/3 km as long as depth is acceptable before reaching a discharge point where the salinity of the excess brine would diffuse naturally. Of course, experts and ecologists can get together to come up with a good X km if 2/3 km isn't far enough or unnecessarily far but I'm just giving it a guess here. Besides, this important issue that you raise is certainly being addressed by the environmental impact report which would be done before plant construction in most jurisdictions. After all, there are more than 19 thousand desalination plants in operation all over the world now.
There was a plan in the early 1970's to build artificial islands off the coast of California, place nuclear power plants on them, and incorporate a large water desalination process. The selling points were pollution-free electricity and copious amounts of fresh water sent through undersea pipes to southern California. The islands would have had earthquake safety measures incorporated. The plan was not used for various reasons, but if it had worked as planned, it could have solved quite a few problems California suffers from now.
the whole hydrological cycle is nuclear powerd anyway - since time immemorial. only difference: its fusion, not fission. on a serious note: why cant we collect precipitation going down over the ocean?
We could, but off the top of my head one issue might be the sea state when it rain is terrible. Collection vessels going into storms seems like a bad idea.
Here in New Zealand we do the opposite to desalination. At the Manapouri hydro power station, we take 510m3 of fresh water per second and dump it into the sea to produce 800MW of electricity. That's 44 million cubic meters of fresh water per day. Makes that Soudi desalination plant look tiny in comparison.
It gets crazier. There is a tunnel (9. 2 meters in diameter, 10km long) that is used to discharge the fresh water into the sea. Once operational, they realised it was too small to be used to operate the power station at full capacity. So they tunneled another one at 10 meters diameter. Just try and imagine how much fresh water flows through those two tunnels.
@@TheBooban no. In normal dams, the water continues along the river, as you pointed out. At Manipouri, the water is diverted away from the river, through the mountain, and directly into the sea.
One thing is darned sure, you cannot desalination seawater economically with pressurized water reactors. The value comes when you have the higher temps of molten salt reactors. Especially when you use only nuclear waste from pressurized water reactors with the fuel incorporated into the molten salt. Iridium is like burning gold to make energy, sure you can do it but why would you?
PWR is not the ideal rectors we want to even consider when Thorium Salt Reactors have proven to be better in most aspects compared to PWR…we just need the power to operate RO water purification, the other methods of desalination are energy intensive and are quite dangerous in when paired to PWRs
Thank you, nice video! Please consider listing sources of information ( most do it below video ) so viewers can verify that this is information not entertainment..
Solar thermal can help to boil the water in either oil, gas or nuclear desalination plants. It can be a pre heater or cycled through a heat pump to heat the water and save other fuels/ improve output with nuclear. Also sea salt is useful, why not keep it rather then dumping it back in the ocean? That could be a good side business. I also think that ocean thermal heat pumps could use heat from surface sea water to boil the water too. Waves could help to pump the water...
I've heard about Thorium salt cooled nuclear reactors and the possibility of using the waste brine from desalinization as the coolant for those Thorium reactors so there won't be any waste
Do the thorium salt nuclear reactors need to have the salt refreshed? I thought once they have the salt, they can just keep using it and don't need anymore.
No you don't want to use the brine as the coolant. At all. Straight up NaCl/KCl already is a kinda lousy medium for the neutronics but it's not even pure stuff if its coming from the ocean.
You've got some wires crossed there. It's the waste heat from the reactor after thermo-mechanical conversion used to heat the saltwater for desalination purposes.
You're confusing different types of salt. The salts in the ocean are dissolved in water, while when you hear Molten-Salt Reactors, it refers to dry, completely water-free salt being heated to the point of melting -- and it's additionally a different type of salt than the type you find in the ocean.
Something missing here. Usually MSF heat source is waste heat from a thermal generating plant. Heat that is of low grade and wouldn't generate much electrical power in turbines. Also does the elec energy number for RO include energy recovery of the brine. That can really change the energy balance of RO.
The use of reactors for desalination is only hampered by current reactors that produce very nasty waste and weapons materials. Using thorium reactors would eliminate the waste and weapons materials issue as well as be capable of desalination as part of their cooling system. The concentrated brine can be pumped into evaporation ponds and the resulting salt used for other industrial purposes or diluted with raw seawater and returned to the ocean/sea it was taken from. By building multiple plants in areas where earthquakes and tsunamis are less likely and/or building facilities able to withstand them, water and power can be provided safely and in great quantities. The cost of running thorium reactors would be much less than uranium plants due to their inherent safety and lower radiation fuels and waste.
Actually current designs produce a very small volume of dangerous waste. It’s said that over 90% of all nuclear waste has already been produced and most of that was from government nuclear weapons programs, not civilian power generation.
Could you imagine if we had put in all that alternative energy money in nuclear? We’d be carbon neutral by now with no rolling blackouts and perhaps not be in such worry of these droughts.
very interesting. I spent ten years in Saudi Arabia and used to frequent the beach near their desalt plant on the East Coast. We had two waters piped into our house, one was salty and the second 'sweet'. The sweet water was only available in the kitchen sink. that was all 20 years ago so not sure what they have now. Thank you for sharing your research.
@@judgeomega I do not know the ppm of the salty water and also did not know the source, but it was very noticeably salty to the taste and would not be suitable for cooking with, for many people. there was a type of grass that could survive it, and so we did have grass in the yards. also, the Arabian Gulf water is noticeably salter, especially the restricted bays and inlets, than open ocean water. Scuba diving in Arabian Gulf required more weights than diving in (for example) Philippines, because of that extra salinity. The situation is similar (but not as extreme) to what we read about the Dead Sea and how easy it is to float there.
I thought he said kazakistan. Still wrong and a bit jarring though. Like how Chinese speakers love to "localize" the pronunciation of foreign names, making it completely unrecognizable.
At 08:09 I would have to disagree with the graphic. At least for the current PWRs, The main steam enters both high pressure and low-pressure turbine to remove as much energy from the steam to turn the generator. Once it exits the turbine, the vacuum from a condenser is what pulls the exit steam and the secondary cycle once again starts over. With your graphic, it seems to suggest that some energy be used for power and the rest would be for desalinization. The problem I see with that is you now introduce two potentially variable outputs in your secondary loop that likely result in more significant power level variations in the reactor. This is not very good from both a Nuclear Physics standpoint nor Nuclear safety. What would probably be the solution is that the power production side and desalinization side would be two separate trains and the nuclear operators would control the direction of steam through some sort of bypass valve. You actually see these discussions with some of the SMRs being developed. The big picture is that you want as little change to the reactor as possible, so the best bet is to change the direction of what the heat dissipates to versus bolting on an additional outpoint on one train.
I am not sure I get your point - Only super heated steam goes through the turbines, right? So at some point after the turbine you need to condense the steam (for the next cycle) which is where the desalination plant comes in. I don't think it uses some steam for power and some for desalination, rather the desalination plant is the condenser. Anyway, that is how I am reading the graphic A thermal desalination plant is just a cooler, it doesn't even need to be steam, as vacuum is being applied to the desalination chambers so salt water will boil of at less than 40 degrees.
Fill the world with Nuclear Desalination plants, solve water and energy problems. Seems like the best long term solution to these problems with current technology.
Please help me here with my understanding. (which is still limited). Desalination plants seem to be all the rage right now, and indeed, drinking water security is critical. But I am concerned with what happens to the salts that are removed from the saline sea water, is this slurry (Brine Discharge) pumped back into the oceans whence it came? have there been many (any) impact studies on what this effect has on the immediate ocean life near the location, or does it diffuse out quickly, as the ocean is vast. But I have to wonder about if this is scaled up around the globe, and the long-term effects of no only increased global temperatures, but potentially the increased salt percentage of the oceans.
Chernobyl was due to bureaucracy, incompetentce and general retardation. If you look at 3 mile island in the late 70s and windscale in the early 50s, they are the only legit nuclear accidents, and they weren't that bad. In places like Fukushima, they build a nuclear power plant in tsunami prone areas. And had the reserve batteries below the tsunami level, so water leaked out. There have only been 4 notable large scale accidents, and 2 weren't that bad.
One of the challenges with nuclear power is that with their costs skewed towards being upfront, and their fixed life-span, you don't want to load-follow the grid, but instead you want to run at full capacity at all times, except during maintenance, and let hydro or gas power plants do the load-following instead. How skewed towards the initial investment are the costs of desalination? Could it make technical and economic sense for a nuclear desalination plant to divert power away from desalination, and onto the grid during peak hours, and then go back to producing potable water, once demand falls again, later in the evening? Does desalination have a significant thermal inertia, meaning it's hard to run the production in a stop-and-go manner?
As an electrician who has worked on US nuclear, combined cycle, solar, and wind energy plants, I feel that nuclear power is one of the greatest boondoggles ever perpetuated on humanity. It is by far the highest cost for electricity, and that is with the highest level of direct taxpayer subsidies. In the US, taxpayers have spent in inflation adjusted average, 3.5 billion dollars a year on nuclear energy since 1948, yet costs $131 to $204 per mega Watt hour, not including decommissioning, long term waste storage, security, and public insurance costs. While other power production does have some corollaries with toxic wast cleanup and security, they are minuscule compared to nuclear power. In contrast, renewable energy has received 0.38 billion in taxpayer subsidies since 1994, and costs between $26 to $50 per mega Watt hour. The major myths about nuclear power that have been perpetuated since the 1950's is that it is clean, safe, and will be to cheap to meter. None of that is true. Many electricians will tell stories about having limited work times due to radioactive releases, and when we work, we have to have one other electrician watching everything we do to ensure that no mistakes are made, and the amount of redundancy is ridiculous, yet necessary. Last time I worked at the Humboldt Bay power plant that closed down in the mid 1970's, it still employed hundreds of people in decommissioning and working to contain the plume of radioactive groundwater from reaching out into the bay. There are military guards with automatic rifles with shoot to kill orders for anyone without proper access. You never ever take your badge off. This is the same in all US nuclear plants. As to it being needed for its "low carbon electricity," it is like an electric vehicle in that it does not have a tailpipe or a smokestack that releases pollution at its point of use, but the entire supply chain for a nuclear power plant is very CO2 intensive. From the large mining equipment for the materials and fuel, to the refining and transporting of astounding amounts of metal and concrete to build the plant, and to the ongoing fuel supply, and then the temporary dry cask storage containers that are made out of 100 to 150 tons of steel and concrete, and will need to be replaced every 25 to 100 years for tens of thousands of years, it has been estimated by independent of industry and non aligned studies that nuclear power produces about the same amount of CO2 as natural gas. And when decommissioning and the increasing difficulty of extracting the deeper and less desirable uranium ores, it is now approaching that of coal. To be fair to EV's they do offset their CO2 production compared to an ICE vehicle after about 6000 miles of driving, and only continue to produce less over time, especially as the electricity mix continues to contain more renewables. Some very interesting ways of disposing of radioactive metals has been found, called "Dilution in the Consumer Stream" where the radioactive metals are shipped to foundries, chopped up into small bits, and then added a little at a time into larger batches for consumer goods and building materials. The amount of construction materials it takes to build a nuclear plant compared to a conventional plant just boggles the mind, and having worked there, I would not trust my life on them. Since no insurance company will insure nuke plants, the US government requires them to carry 450 million of insurance for each reactor, with another 13 billion available from all of other nuke plants kicking in extra money. Any more cost for "accidents" would be picked up by the US taxpayers via congressional approval. As Fukushima is expected to pass the one trillion dollar mark soon, that would leave the US taxpayers on the hook for 987 billion dollars for the same type of accident. That is a lot of money to gamble with, and would go a long way towards paying for the renewable energy to replace nuclear power.
Many years ago I had a neighbor, Paul Kunming, who was a retired Westinghouse nuclear power engineer. He said Westinghouse made a major error by not incorporating desalination plants with nuclear power plants. If coastal cities could have a water supply, they'd want nuclear power plants.
It totally makes sense to use waste heat from the cooling system to power the desalination process. The solution for excess heat being dumped from nuclear plants on the ocean was right there ! use it to remove the salt, and have fresh drinking water.
Utilities would have retired them if they were included. The vast majority of US based Nukes have water purification plant. They are very rarely used and most plant have abandoned their purification systems. Instead most nuke sites rents RO trailers from GE or other 3rd party companies and use city water for the feed.
Good point.
@@mikeall7012 I'm not referring to the small water purification systems have for use by their processes. I mean large scale plants to supply water for domestic and agricultural use. As in, the power plant would be the municipal supply.
Ocean going ships use the heat from the engines to make fresh water by lowering the pressure in a tank. It therefore boils at a lower temperature.
Had 3 separate msf plants on the cruise ship I worked on. It utilized waste heat from the main engines, so our water production would scale with ship speed(engine load)
Three days after leaving Sydney on a cruise ship we noticed our cups of tea tasted slightly salty.
That was because the fresh water taken on in Port Jackson had been used up and we were now using desalinated water.
No problem, we changed over to coffee and didn't notice a salty taste again.
@@MaxB6851 personally I think once you can taste any salt in the water that is not good
@@1mezion I am not an expert but I think the same.
@@MaxB6851 the whole point of desalination water is that's its not meant to taste salty
@@Alucard-gt1zf exactly
One fact in favor of nuclear power should be pointed out: radioactivity is very easy to measure. Much easier than any other contaminant in water. It's a non issue.
A very helpful fact when one of your nuclear plants goes full Fukushima and you can tell the world exactly how much contaminated seawater you have released into the ocean 😄
@@BuddyLee23 Try to measure how many lives were lost due to Germany switching off their nuclear reactors and ramping up their coal and gas stations, fuelled with stuff bought from tyrannical countries around the world, who then went on to invest their euro profits in to guns, wars, murder and genocide - pretty hard to measure.
@@BuddyLee23 no much after a while because of how humongous the ocean is actually. The waters are constantly moving as well. The average levels lowers down to an insignificant one not too long afterwards.
@@BuddyLee23 If you believe that Fukushima made a meaningful impact in contaminating our oceans in the topic of making drinking water, you have a lot to learn about the amount of contamination released by Fukushima.
Sure a part of ocean sealife suffered from the contamination, but it is far from the catastrophe the media has painted.
ROFL. "Easy to measure", impossible to clean up once it goes boom.
One interesting note, dedicated desalination reactors can be MUCH cheaper than energy-generating reactors. That's because they don't need to pressurize the water to keep it liquid at very high temperatures. A desalination reactor can just pressurize water to just 4 atmospheres, raising the boiling point to about 140C. 4 atmospheres is easy to work with, it's less than the pressure in your faucet.
Or you could use high temperature gas cooled reactors or molten salt reactors to generate electricity and use the waste heat to desalinate the water.
@@thegreyghost5846 Sure. But then the reactor cost will be dominated by the energy-generating part.
@@AlexBesogonov
If people keep pushing towards electric vehicles for short range travel and commute, the transition can cause more strain to the power grid than green energy can keep up and have to resort to other fuel sources for on-demand power or baseline power.
Hybrid systems are never cheap, but they make efficient use of resources by not letting the work go to waste. Using nuclear or other waste heat generating sources made for other purposes to desalinate water is more useful than you think.
We don't get to have geothermal power or desalination unlike some countries, so best you count your blessings before you lose them.
Alex and Aereto, you are both correct. We need both water and power. If we can push the use of nuclear for water product and have plant operate cheaply and with out issue, we can finally maybe change the public relation of nuclear is bad. Then we can talk about getting nuclear power online which is the only way to get off fossil fuels.
"...pressure in your faucet" uh, maybe in your country, but not in mine. only 2 ATM. sucks too, cause it used to be higher before "water saving measures"
I've been saying this for years - In California, PG&E should work with the sate water agencies to repurpose Diablo Canyon for desalination. Pump the fresh water generated up over the coastal range and into the California Aqueduct.
Excellent informative video. The “greens” should pay attention.
@@davidlangford1165 they won't. They are useful idiots to push half baked technologies that wouldn't and couldn't stand on their own yet, and increase energy profits.
They still have San Onofre sitting there doing nothing. A couple new small modular reactors and a desal plant instead of the old broken steam generators and they'd be in business. Then pump the brine up and over the mountains and store it in the Salton Sea. The containment buildings are still in place at San Onofre, just need the reactors to stick inside.
"Just pump over the costal range." That a major challenge by itself.
@@blastermanr6359 kind of. The pumping requirements are not trivial. It takes a lot of electricity to do it, but the engineering part is pretty well established at this point. It's more a political and financial problem.
Thanks for making all these videos they are very unique and always very interesting topics. I learn so much from them
Our rejection of Nuclear power was a massive mistake, and the environment has payed dearly for it as we continue to rely on fossil fuels for our electricity
There needs to be a solution for the waste. Burying it isn’t good enough. Reactors that re use the waste that results in a shorter half life seems to be just talk.
@@TheBooban nuclear waste is still much better than all the fossil fuel waste we've had. There's also a lot of research into nuclear fuel reprocessing such as hollow fiber ionic liquid reduction exchange process.
@@TheBooban ahhh putins shill are already here
fun thing about historical fictions is that you never actually know what the outcome would have been if history played out differently. To assume there would be no issues with nuclear if we fully embraced it, I think is naive.
@@thefbat5847 only reason nuclear waste isn't as big a deal as fossil fuel waste is that nuclear only accounts for a small fraction of our total energy consumption.
I used to operate an MED for the purpose of concentrating grape juice. Kinda bothered me that we dumped millions of gallons of process water from the juice, as well as thousands of gallons of Ethanol down the drain. It costs a fairly good amount in wastewater treatment and i just think its stupid to dump fuel down the drain. This type of inefficiency is everywhere across food industry and i hope it gets some attention.
@@SubvertTheState Did the ethanol not have a value? Even burning it as a fuel to run the plant operations
Another exceptional video, with excellent dictation. Your mastery of English is better than most native English speakers. Keep doing what you do in your style, its very much appreciated. Thank you.
This helps me feel better after all the pronunciation corrections
@@Asianometry You're not a native English speaker? I knew you lived in Taiwan but I thought that English must be your first language because you have no accent at all (that I can recognise at least)
General Disaster ...Is the name inherent when talking about the nuclear industry
@@Asianometry There is another desalination technology - Humidification-Dehumidification. Here is a video - how it works and how it is better than traditional desalination tech. Would you like to talk about new tech on your channel? ua-cam.com/video/NzdNwKBVXT8/v-deo.html
@Amethyst amercans do not speak English
you lot speak pidjin english
I'm surprised in countries that have deserts there aren't even an prototype of concentrated solar desalination plant.
Edit: I see in the replies many people miss understood what i mean, i don't mean solar panels. Concentrated solar is made with mirrors pointed to an object in this example massive glass dome filled with water.
Are you talking direct evaporation from concentrated solar, or are you talking about using concentrated solar to high yield solar cells?
The energy needed to evaporate a cubic meter of water is 627kWh. This figure ignores heating the water, as you need only 91kWh to get from 20 to 100degrees, and that figure is dwarfed by the energy needed to evaporate the water.
The energy needed to create 1 cubic meter of desalinated water from seawater through reverse osmosis is 2.5-4.0kWh. This is at least 150x times better.
Why you need nuclear for this is beyond me, any country that needs desalinated water has excellent solar irradiation, and RO can happily be run only when excess energy is available.
@@luc_libv_verhaegen problem is water systems have to run 24-7 so you need a baseline, not strictly a deal breaker though, plus ideally you'd be desalinating to fill reservoirs to help with shortages
These countries usually wait for western or south Asian Asian countries to invent stuff.
@@luc_libv_verhaegen I think, start/stop cycles will destroy the equipment. Or at least make it really hard to pay off, since "excess" is only a few hours per day.
Desert environments, particularly in the Middle East and the Sahara, have crazy sandstorms that would destroy/bury solar panels.
It's a no-brainer. The inherent safety and compactness of MSRs, along with their very high heat output, make them ideal for all sorts of industrial processes. Much of industry like steel etc needs heat rather than electricity
No brainer, if you don't have a brain, just like Justin Bieber
I wish we could split the planet for pro nuclear and anti nuclear people.
The pro nuclear side would quickly go to a lot more fresh water, probably cheaper energy over the long run, generally progress... let's add hydrogen production to that and move to hydrogen cars while we're at it.
Then a while after we can leave the planet with the anti-nuclear peeps...
Until there is a war or a flood or an earthquake it's safe....
@@rickcostin
Basically, California.
1. Switch from nuclear to solar in Germany where engineers are abundant and sun is scarce
2. Construct nuke plants in deserts
3. ???
4. Profit!
Newer Molten Salt Reactors operate at higher temperatures, 450-650 range. Combining this with CO2 gas generators, which have as intake temperatures roughly around the same temperatures 500+ degrees, also means that the temperatures of the output of these generators is around 250 to 300 degrees. This allows for a even higher energy transfer efficiency than older PWR reactors.
Furthermore, even the temperatures that come out of an MSR are warm enough as is to generate Hydrogen without first having to turn the heat into electricity (eliminating the efficiency loses related to heat to electricity process)
so high water production, and, large hydrogen production (which is emissions-free), Now the hydrogen can be used as is for hydrogen based transport, however, going one step further and implementing Carbon Capture, and combining CO2 and Hydrogen can allow you to make synthetic fuels (pure, gasoline, kerosene, diesel). And this let me tell you is a holy grail moment.
While still producing CO2, this synthetic fuel burns cleanly (no impurities based from refinement) and burns more potently, critically, it is cyclical in nature, you take CO2 out of the atmosphere (or out of the oceans) and then release it back into the atmosphere, it is net-zero. And the key difference is simple and highly attractive; we don't need to reinvent anything to make it work. This Fuel can be used in our current infrastructure as is... Airplanes, Shipping boats, Public Transport, personal transportation; all of this becomes carbon-neutral overnight, without the necessity or expenditure to change the entire fleet of transportation methods (which in itself constitutes a burden in the form of emissions and pollution, as we are retiring the older fleet before its lifecycle ends)
Another fundamental win from this is opening up a market to which we can base our Carbon Capture too... Currently, we can capture tons and tons of CO2 from the atmosphere... but there is no market large enough to sell it too... meaning the Carbon Capture will never be a profit driven industry... however synthetic fuels however flip this... creates a market, allows Carbon Capture companies sell their CO2 to fund the construction of more carbon capture... once we have displaced all fossil fuels from the transport industry alone (fossil fuel power plants make no sense to convert to synthetic fuels) (at this point also technology and scale also has driven down the cost of Carbon Capture) governments can impose a carbon storage quota, 70% of what is captured is destined for synthetic fuel production, and the remaining 30% is for storage; thus now motivating the construction of more carbon capture and finally beginning the process of CO2 reduction in the atmosphere.
Carbon Capture is energy intensive, and thus requires a large quantity of stably available electricity which is emissions-free, which again leads perfectly into the hands of Nuclear Energy...
Hmm yes I agree...
co2 capture is not sustainable.
@@victorhopper6774 why isnt it sustainable? I mean the ICC and most other reputable scientists already stated that simple reduction and complete net zero carbon emissions isnt going to be enough anymore.
In essence weve started a chain reaction already as is where Carbon capture is the only way to reverse and undo the chain reaction...
Actually i have 2 questions;
Why do you think it isnt sustainable?
And, what do you understand with unsustainable?
@@Merreck0 beause life for humans requires oxygen at least 19% or we get goofier. we are at about 21 now.you have to keep freeing up the 02 for animals to survive so don't ''lock'' it up.
@@victorhopper6774 who says we would go beyond that? There are about 200 years worth of industrial CO2 in the sky, and the first stage is to make it net-zero... which is the cyclical nature of synthetic fuel. If we dont store any of it at all, then we break even because we release it again...
Only when we decide to store it do we capture and lock it down, the reality is your right, but we do need to remove atleast the 200 years of CO2 from the industrial revolution from the atmosphere... and noone said we would push beyond that, we dont have too, we are balancing our intake of CO2 with our output.
As an Australian. Im just like WTF is with our tritium drinking limit
The thing is the tritium limits are just decided randomly without any scientific basis. Even with australian levels they haven't proved tritium is dangerous to health.
@@SamSam-qk5zr They aren't random. They are deliberately chosen for ideological reasons to make it impossible to use nuclear energy.
"The Australian blood is probably full of tritium. This is a valuable resource. How can we extract it?" -Count Dracula
you guys also have really high levels of arsenic in your ground water as well with no apparent adverse effects
@@SamSam-qk5zr tritium is radioactive, retained like water inside our body if ingested and cause cancers, especially to our organs.
Salt cooled nuclear in 1973, well I didn't know the tech was that old. They are working full speed on the molten salt reactors now. Definitely the best method of desalination.
Back to the 1950s in fact,
That’s a sodium metal cooled reactor
Just to underline kokofan's point: Sodium does not equal salt. Sodium here refers to pure, metallic Sodium, not a compound that includes Sodium such as Sodium-Chloride a.k.a tablesalt.
That being said, the US operated the world's first Molten-Salt Reactor in the 1960's at Oak Ridge, Tennessee.
@@eckligt fair enough mate.
pure metalic sodium, I remember seeing that being thrown to body of water and then BOOOM, lots of dead fish.
Modern desal plants are up to 90% water recoveries these days - very impressive. That minimises the input flow as well as the sea critters it effects. You then combine the brine outflow with the treated sewage outflows and bingo bango. Let's roll.
I wonder what ratio of brine to treated sewage are needed
@@FrankGarcia24 Don't forget stormwater runoff. That is not a zero figure.
@@FrankGarcia24 That can also be used for dilution. It starts to balance out yeah?
... how does 'dilution' NOT fail.... at Scale.....
@@nealtauss1715 Every city and it's surround catchment is a significant surface area. A great majority of a modern city is covered with concrete/bitumen/smooth surfaces that have minimal water take-up. That means a lot of rainfall tends to end up as storm surge or in the associated seaward discharge systems of that city. Probably all of that water is not good enough quality to drink however it is ideal to dilute any saline/brine from a desal plant with some simple storage/surge capacity. Thus you should be able to offset the brine production through dilution from sewage/water runoff systems.
Most informative. Thanks for the video!
Great video as always! Would've loved a little more coverage of the Indian plants though
Congratulations 👏 for such a wonderful presentation ❤️
Thanks!
Very good job, Molten Salt Reactors are a promising producer of heat with general less tritium production.
You did a great job with this. Awesome channel...
The biggest environmental concern is what to do with the salt-enriched waste water. Great video otherwise, but you didn't even touch upon this.
Oh, dear how would extra salty water behave in salty water? We need to study saltiness while CO2 acidifies the oceans.
American fast food chains:" did you say unused extra salt ? I'll take the entire stocks"
Mine for lithium and other useful minerals?
@@ronmaximilian6953 directly producing Na-ion cells for industrial storage of electricity.
@@AstroGremlinAmerican don’t joke, this is a real environnemental concern arround the dessalanisation plants. But yes of course n1 priority is still global warming.
12:00 "up to 10-30% of fish embryos are being affected" .... at what scale ? Around the reactor ? You can't mean worldwide.
around the desalination plant.
No mention of graphene or graphene oxide desalination? This relatively new technology basically stacks layers of graphene or graphene oxide close enough together for water molecules to pass through but block virtually everything else, without the high pressure required for reverse osmosis.
He did make a passing reference to "other membranes technologies". From an energy magnitude perspective this in probably equivalent to RO in terms of power infrastructure?
He did make a passing reference to "other membranes technologies". From an energy magnitude perspective this in probably equivalent to RO in terms of power infrastructure?
Nuclear desalination makes great sense.
Nuclear generates lotsa heat and can be used to boil water... cools down the vapor and get clean water, rinse repeat.
Nuclear power does make great sense as well, the problem is the handling and damage potential. With two prime examples and a lot less or unknow near catastrophic events I am happy not to have to rely on this option.
@@Monsterpala You will see a bigger catastrophe when war happens because of Energy... New reactors are made in a way where things like those two cases are impossible to happen....
@@Monsterpala 2 ejemplos buenos mis huevos, uno era un reactor militar pesimo (Chernobil) y el accidente de fukushima fue un evento sin precedentes, no este mamando.
Buenas tardes.
@@Monsterpala Natural gas plant accidents and pollution kill more every year than nuclear ever did
@@UmbraWeiss You mean when war happens and they drop a bomb on your failsafe nuclear power plant?
What to do with brack water that is left over? It can damage ocean habitats.
It's rich in metals we need. Sodium is a promising new metal for battery tech that could replace lithium and is ubiquitous. Magnesium is a great building material similar to titanium. And other trace materials and chemicals can be harvested and sold to industry, such as chlorine.
It can also be added at the right times of day and locations to improve the habitat.
@@Anenome5 Very expensive to take high saline desalination brine down to extraction of solutes. Then the salt needs to run an industrial process to separate the eg magnesium, Lithium and Sodium from the chlorine and each other. Very expensive, energy intensive. Dry salt deposits all over western N. And S. America's, very little mineral separation happening due to cost.
@@lengould9262 is energy the greatest expense? If so, using the same nuclear power plant for these processes could keep costs low?
Couldn't we just continue evaporating it and use the dried salt?
thank you for great work, i know this video took lots of your time to develop, thank you for your great work & all the great info in this video, god bless you.
Video doesn’t mention what happens to the salt after desalination.. if dumping it back in the ocean it increases the concentration and wrecks the ecosystem. It is another issue that needs to be addressed when these projects hit scale.
Good point, why not harvest the salt, we have a company here in SA that farms table salt from salt pans and exports brine. I have thought that if you were to cover the salt pans with glass houses you could have solar desalination by collecting the condensation and salt harvesting in one industry.
Just don't dump it in the ocean then. Duh.
@@Kalikus808 Dumping it in the ground wouldn't be any safer. It would pollute the surrounding land and water supply.
Worth considering, most domestic and industrial would end up back in the water waste stream. In most cases you would be looking at a net neutral salinity.
Put it out 20 miles into the ocean, now we dump it 1 mile out?
The desalination comes at a low price if it is thermally coproduced with electricity. The efficiency of the powerplant is only slightly reduced but you get the water for it.
Good video, I hope more people can design reactors to slowly but eventually replace coal and petroleum so they are only really used for plastics or classic cars.
The effort you make to proper pronunciation is noticed, and extremely rare. I appreciate your dedication to proper aducation.
I remember Jacque Fresco exhibiting a solar desalination plant that used a clear canopy over a canal to collect moisture from the evaporation off of water as it is heated by the sun, perfect for most equatorial zones. No energy plants required.
If not mistaken, based on what I read. The by-product produced by desalination is a concentrated salt water. Since we harvested the "fresh" water component, the by product which is the super salty water gets discharged into the sea. Eventually, the sea will become a "dead sea" and there goes our seafood.
No it won't for one simple reason. The water cycle. All the water we take from the ocean through desalination will eventually make it's way back to the ocean.
Are you a comedian or something? The salt in the ocean is constantly diluted by rain.
Yet another of my ideas has already been thought of but I was planning to send it into the middle of the desert to just be dumped there (that’s the only purpose (and free salt))
Your Chanel is awesome. Congratulations from Spain.
I love the style of your vids. So unbiased and to the point. Very informative and insightful. Thank you!
Highly biased in this case, almost like it was paid for by the nuclear industry
@@richardscathouse you mean the only realistic solution to meet climate goals industry?
The Korean SMART is a copy of the Argentine CAREM... which was designed for water desalination too. So no surprise there
I think Finland follows now the EU directive mandating 100 Bq/l Tritium limit. It only make sense considering Finland is in EU the number of 30 000 is outdated.
There’s another environmental concern you haven’t mentioned. Desalination obviously doesn’t remove all the water from seawater and at the end of the process you have leftover brine. This brine typically gets pumped back into the seawater source which significantly increases local salinity at the region of the outflow but also in theory could increase the entire source’s salinity over time. Besides the obvious, immediate impacts this can have on complex sea life there’s reason to be concerned about the impact of creeping salinity on phytoplankton, which globally account for 50-80% of the world’s photosynthetic conversion of CO2 to O2.
What about using nuclear power to generate electricity to run a heat pump based desalination plant? Should be very efficient. The condenser side boils the water and the evaporator side of the heat pump condenses it back up. Probably very expensive though.
in any steam power plant, nuclear or coal, the condenser needs cooling water, and will heat the cooling water by 10-20F? I don't recall a ship-based plant tapping the hot-side of the condenser cooling water as source for desalination.
There is a caveat, for plant water, desalination can occur at the lowest possible temperature and pressure (120-140F?). For drinking water, the desalination should occur at higher temp (180F?) and should tap seawater from further out.
For countries with excessive renewable power wouldn't it be cool to use the extra power for desalination instead of using battery storage? This creates water while reducing costs since you don't need batteries!
we do, in South Australia
@@rickcostin I'm Aussie too but didn't know that. Aussie Aussie Aussie 😊
@@Planet_Xplorer I've seen more comments on batteries being used for excess power production, which is only a problem for coal/gas and apparently nuclear plants that take ages to react to changes in demand and need to keep running even when there is no demand. My understanding is that batteries are used to stabilize the grid if there is an outage like the one we had in SA when a tornado took out a main transmission line. The state government was ousted because of a perceived over reliance on renewable energy, when it came down to the Victorians not closing their interconnector. Elon Musk stepped up to the plate with the worlds biggest battery in Jamestown SA which helps stabilize the grid when you have a lot of wind and solar power which is intermittent.
Thorcon plan to build MSRs on barges or off shore platforms built in shipyards.
Wish Australia would stop being scared and build some bloody reactors. great video dont how you explain this shit so well.
Yep we are thinking of putting one in your back yard.....
@@rickcostin clearly, you know fuck all about the subject
nice video mate
just got a big question to ask you
has anyone tryed to use desall water useing geothermal power greration?
There's a Wikipedia page under the title "geothermal desalination"
Great Stuff! I was wondering if a ship based nuclear reactor could be used to provide energy for a mobile de-sal plant, for example on humanitarian missions via an form of deep-hulled vessel such as an amphibious assault ship? Would such a facility be effective, or even feasible?
Combing flash distillation with nuclear would be a good combo. In flash distillation, the brine is heated, not boiled. The brine would be at a higher pressure than the steam heating it, so any leaks will be from the seawater to the secondary loop, excluding tritium transfer from the secondary loop to the brine. Not so great for the plant now getting brine in the secondary loop, but great for keeping the product water radiation free.
Perhaps useful to think of a nuclear reactor + desalination plant as equivalent to a "peaker" power generation unit that can be operated 24/7 "for free" (uranium fuel and nuclear waste disposal being relatively inexpensive operating costs) with the electrical power that isn't needed by the electrical grid being put to productive use.
Compare for example to a nuclear reactor + hydro power storage facility, feed nuclear reactor electricity into the grid when needed and use that electricity to pump water uphill the rest of the time. Such a combination is even more useful, but only works where the nuclear reactor can be built near a good site.
Or compare to the notion of building dams in remote locations with the intention of using the electricity generated to smelt aluminum. The aluminum smelting plant and the desalination plant are similar: they both represent productive ways of using electricity where the nuclear power operator can control demand.
Never knew so many were in operation, great video.
Good job analyzing the water problem from a stand point of current engineering. I think you made the case that thermal desalination powered by nuclear energy is doable right now, no break throughs required. However, I have my doubts that this will be significantly advanced in the near to medium term. There is too much fear of nuclear power. "Nuclear water" is not a tagline that sells.
This is a shame because sea water desalination can be cost competitive with many current dam and irrigation projects. For perspective, the minimum theoretical energy required is less than 1 Kw/hr per M^3. Stated differently, reverse osmosis of sea water requires a pressure head of ~ 300 M. For comparison the California water project pumps water up 400 M over the Tehachapi mountains. Yes, pre-treatment is currently expensive. Yes, practical osmotic systems may require multiples of theoretical pressure. But, desalination is not that much more expensive than other alternatives.
Fear has to give way to fear of not having power and water. The moms of America need to get over their fears.
It’s even better than dams. You’re yoinking a little water (relatively speaking) from the ocean, vs destroying hundreds to thousands of hectares of land…
I dunno why environmentalists would ever be for such projects over nuclear-powered desalination but…welp.
Sadly the mob mentality is that nuclear = bad. Is harder to remove this fear from people than solve water crisis.
Wait until the small modular plants come into operation, everyone's working on it right now!
Correct me if I'm wrong, but you did not mention one of the most problematic issue with desalination... the brine!
Yeah, totally unmentioned. It’s a huge issue with these plants - they create enormous dead zones wherever the brine is dumped.
Yeah, totally unmentioned. It’s a huge issue with these plants - they create enormous dead zones wherever the brine is dumped.
You covered much of the same information that was in my senior project, the main difference was that I focused on the use of SMRs to reduce overnight cost and more specific to the task of water scarcity to meet climate change issues. I enjoyed your video, happy to see good information for a positive use for nuclear energy.
Your time would be better spent focused on MSRs instead of tiny LWRs.
I probably missed this, but can these powerplants also generate power? Is the desalination only a byproduct of cooling down steam or these dont even contain turbines and generators?
You keep mentioning "Kazakastan" in this video. Do you mean Kazakhstan?
So what about the brine? Does it get dumped back to the ocean? Does "salinating" the bay waters have any consequences?
It's easy to get caught up with scary sounding things like tritium, but it's important to remember the reason there is such wildly different environmental standards for it is that these are basically guesswork. We have no evidence for harm from it at low doses so they just pick a number that sounds good. We only have evidence of harm from extremely high doses and no one has ever had enough to kill them.
Risk factors are based upon statistical analysis, not guesses. Each tritium atom has the to potential to emit beta particles which are capable of damaging DNA if they collide. Cells with damaged DNA can turn cancerous. Statistical analysis is used to determine the probability of this event, and this is compared to an acceptable risk factor to determine the concentration of tritium, or any other potential toxin, will be allowed.
@@EDesigns_FL Sure but this is theoretical, if you take in to account DNA repair mechanisms and the lack of real evidence that these low doses actually cause cancer then the number they choose is still just a guess plucked from the air, extrapolated from high dose numbers without evidence.
@@EDesigns_FL statistics based on models with little evidence are guess work
@@EDesigns_FL I've heard several talks by Prof Geraldine Thomas who heads something called the Chernobyl Tissue Bank, and researches the toxicology of nuclear materials. She's quite adament that it's practically harmless in the concentrations that we could be talking about. The jist of her explanation is that:
- The biological half-life of Tritium is around ten days (with some variation), while the nuclear half-life of Tritium is 14 years, so the chance that a given Tritium atom decays while inside your body is very low.
- Not all beta emissions are created equal. Tritium's beta particles have particularly low energy. So even if it does decay inside your body, its damage is limited.
Here's one of her appearances on the Decouple podcast: ua-cam.com/video/-KRthSSs370/v-deo.html
@@kokofan50 It might seem like that to someone who is not acquainted with how the analysis is conducted, but it's not. Physical testing is often done to verify models, but the advent of computer simulations has rendered this unnecessary for most work. That's how we were able to abolish testing of nuclear weapons. Likewise, computational flow dynamics and finite element analysis software and has rendered wind tunnel and physical testing unnecessary. It's all math.
Man, u're channel is awesome! Keep it going! The topics, the delivery. Not a typical "playing around" popular science channel :DI think I would l like to hear on Russia's perspective in the semiconductor industry since sanctions. Will it be able to do something with its Elbrus or not. And the breeder-reactors on fast neutrons. Just telling some (maybe) interesting ideas on future videos. Thanks!
"Agricultural use" means that at least some Co2 is removed & replaced with O2. Not a bad trade off.
Lol that would make nuclear energy a net negative for greenhouses :Ddd epic
Dude thanks for this
Desalinated water is a solution to a lot of the worlds problems. It's a shame it hasn't become more widespread. People say it's too expensive, but the more we invest the cheaper it gets. I've seen proposals of solar powered Desal plants. Could even be used to change water tables and water cycles of otherwise dry regions. Just build water pipelines and pump excess fresh water.
Desalinated water is still very salty, unless perhaps you're to do the process several times until it's good enough to drink...but then it would make the water very expensive to produce. I worked in Saudi Arabia ang nobody drinks from the tap as the water is salty, we just used the water for bathing, cooking, washing clothes and other household needs.
@@rap3208 we have it here in Australia. In several major cities. Can't taste the difference.
@@Jarms48 I doubt you desalination plant produces as much volume as the Saudi plants do. As I have said the more you try to remove the saltiness, the more expensive is the process.
@@rap3208 Australia has 46 desalination plants across the country, we have more plants than Saudi but less production. Australia’s desalination process is more expensive than Saudi’s, which I presume is because it’s far more heavily treated. As I said, I never even tasted a difference here.
Desalinated water should have no salt at all by definition. If it's distilled then it will be completely pure.
Really excellent documentary! Outstanding!
People are going to have to wake up about nuclear. It's far safer and pollution wise it's a no brainer. Yes when safety protocols and site placements are an afterthought, bad things happen. Those incidents while severe, are few and far between. Maybe someday we will find a better alternative but until then much like the fallout series, the future is the ⚛️!
The scared mothers of America need to be told about the dead birds and what happens to children when the power goes out. Sick of dumb people.
@Zaydan Naufal people are almost ALWAYS confused because of ignoring and belittling knowledge! Ex. Trump
More people died from coal pollution than nuclear pollution
Everybody knows about it
But it's kill more slowly so the news reporter aren't interested
@@TheHiddenPearl well to my recollection jobs were coming back to this country and gas wasn't 6 USD a gallon so ease enlighten me as to what facts were ignored and belittled? Thinking small minded people just spout and regurgitate info that is intellectually dishonest, but hey, what do I know, I'm just the chemically induced evil alter ego of a victorian scientist.
@B well put
Amendment - in 1973, Kazakhstan was a Kazakh Autonomous Republic within the USSR and could not independently build a nuclear sodium reactor. This reactor was built by the USSR. The city was called Shevchenko in Soviet times, Aktau is a renaming after the independence of Kazakhstan. Kazakhstan became an independent country at the end of 1991. It still cannot build nuclear reactors. It is very surprising to see such blunders in the video.
The big problem with desalination is the host of imponderables-- like corrosion in the reactor coolant loops and corrosion in the brine loops. Everything looks fine from the outside until a pipe corrodes through or a valve gets stuck open or shut and then EVERYTHING has to be shut down for weeks, months, years, or forever. It's especially bad with sodium loops as the sodium remains radioactive for a very long time.
But the corrosive water won't be in the primary cooling loop of the reactor it will prob be in the secondary just like pressurised water reactors so how will the primary cooling loop of the reactor corrode ?
And in nuclear plants everything has back ups so if a valve gets stuck open or a pipe corrodes they can use backup valves and secondary other loops temporarily until the main ones are fixed that is just how Nuclear power plants in general work
@@alexandrosandreou8585 "Everything" has backups? Nope. I don't know of any reactor that has backup heat exchangers or main valves. Sometimes, there are dual pumps and dual generators but that's about it.
no discussion of the concentrated brine waste outflow of desal plants? how does this get dealt with safely?
I thought this was a good idea 25 years ago. Seems a sensible use of excess power needs while simultaneously cooling reactors. In theory it would combat rising sea levels which just simply adding people (95% water) would not be enough to limit effects of melting ice. It all helps.
"In theory it would combat rising sea levels"
My gut feeling is and guess (I've not checked the numbers) is the scale of the predicted sealevel rise far exceeds the amount of water we use/need. And it would just be a drop in the bucket.
@@autohmae yes agree. But as people reproduce they contain water. Well it’s a step in the right direction for balancing human impacts on the earth.
@@Riskninjaz The sea level would sink about 0.0027778 mm with 10 billion extra people each containing 100 liters of water. With an average sea level rise of 2.3mm in a year that's about 10.5 hours worth of sea level rise that is prevented.
Have to start somewhere. A lot of water will be required for irrigation of crops needed to feed us all and for animal husbandry.
Yet I can see the anti nuclear crowd having a problem with this.
If sea levels start to demonstrably rise then this withdrawal won’t be sufficient to counter it. But fortunately that doesn’t yet appear to be observably happening.
Regarding the risk of nuclear contamination of the drinking water, would it be possible to just use the electricity generated from a nuclear power plant to power the desalinization plant eliminating all risk of nuclear contamination, as the nuclear components would never come into contact even remotely with the water?
Kazakhstan is not pronounced "Kazak-i-stan" (4:16)
I suspect it's an in-joke, but ... you're right of course.
I scrolled down forever to find this comment
Are you saying Kazakhstan?
i'm very curious if anyone has looked into using concentrated solar (mirrors, heat tower and molten metal) to conduct desalination. Seems very viable in any dry, hot desert region with access to the coast. The middle east and baja california come to mind.
Should be something the world bank could perhaps finance for Somalia or Mauretania.
Imagine having a 1 GW solar park for a desalination plant.
Nope, too much energy is needed this way. CSP is very weak.
Concentrated solar required a lot of area outside and exposed to temperature fluctuations and weather.
Because many working parts are outdoor and spread out, it cost a lot of maintenance cost.
That's why people put machine indoors and close together, because stuff will degrade slower, easy to travel when fixing, less money spent buying sparepart and hire less workers.
@@ImaskarDono Concentrated Solar is very strong and all the energy required comes from the Sun. Solar power towers can heat salts up to 1000DegC which can then be pumped to evaporation ponds or green houses to distill salt water.
@@motimobo check the actual economics of such projects. So far they are not working out. The materials are very expensive per kWh produced.
Congratulations on crossing 200k!
Crazy to me how nuclear is coming back to the energy debate, seeing how much safer things have become and watching the whole fossil fuel thing play out. I do hope for our future that serious thought is given to going nuclear in a bigger way.
Never should have gotten rid of San Offeree Nuclear plant. Calf. could use as much fresh water as possible
I really hope they start using nuclear power to desalinate water. People need fresh water at a low cost.
That the major problem though. The technology is there. But not the economics.
@@blastermanr6359 do you know what the words you are saying mean?
Why do you need multiple stages for a multistage flash? Once water is boiled and condensed, it is pure right? It seems to me one stage would be sufficient.
It's a winning combination. I used to be a nuke on a US Navy submarine. The reactor is just a heat source that doesn't require hydrocarbons like oil, gas or coal. Under pressure, the very hot water from the nuclear plant is pumped inside the tubes of a steam generator that makes the steam and sends it out of the reactor compartment in secondary piping (WITHOUT radioactivity) to drive turbines to make electricity. It's a simple thing to branch off some auxiliary steam to make fresh water from sea water as we did underway. We could produce about 10 thousand gallons of fresh water daily in the 1970s which was more than enough for the power plant and potable water for a crew of 140 men. Nuclear plants should be built in seismically quiet coastal areas with associated desalinization plants to make surrounding communities and regions plenty of fresh water. By the way, when you see those big cooling towers emitting huge plumes of environmentally safe steam, remember that all this heat energy is just being wasted to the atmosphere when instead, just a small portion of this non-utilized energy resource could be used in auxiliary capacities like desalinization that could benefit the utilities as a secondary but significant source of revenue in terms of the overall nuclear power plant's business model.
What happened to the waste brine? I know for large industrial desalination there's enough to throw off local salinity levels if it's dumped back into the ocean
@@hotmailcompany52 at sea, obviously this isn't a problem for a submarine BUT you bring up a good point for a stationary desalination plant onshore. I'm not an expert but it does seem reasonable to engineer an undersea pipe for about 2/3 km as long as depth is acceptable before reaching a discharge point where the salinity of the excess brine would diffuse naturally. Of course, experts and ecologists can get together to come up with a good X km if 2/3 km isn't far enough or unnecessarily far but I'm just giving it a guess here. Besides, this important issue that you raise is certainly being addressed by the environmental impact report which would be done before plant construction in most jurisdictions. After all, there are more than 19 thousand desalination plants in operation all over the world now.
This would be an interesting use for Small Modular reactors...
There was a plan in the early 1970's to build artificial islands off the coast of California, place nuclear power plants on them, and incorporate a large water desalination process. The selling points were pollution-free electricity and copious amounts of fresh water sent through undersea pipes to southern California. The islands would have had earthquake safety measures incorporated. The plan was not used for various reasons, but if it had worked as planned, it could have solved quite a few problems California suffers from now.
the whole hydrological cycle is nuclear powerd anyway - since time immemorial.
only difference: its fusion, not fission.
on a serious note: why cant we collect precipitation going down over the ocean?
We could, but off the top of my head one issue might be the sea state when it rain is terrible. Collection vessels going into storms seems like a bad idea.
Here in New Zealand we do the opposite to desalination. At the Manapouri hydro power station, we take 510m3 of fresh water per second and dump it into the sea to produce 800MW of electricity. That's 44 million cubic meters of fresh water per day. Makes that Soudi desalination plant look tiny in comparison.
wtf this is lunacy!!
It gets crazier. There is a tunnel (9. 2 meters in diameter, 10km long) that is used to discharge the fresh water into the sea. Once operational, they realised it was too small to be used to operate the power station at full capacity. So they tunneled another one at 10 meters diameter. Just try and imagine how much fresh water flows through those two tunnels.
@@debochch its just a dam. Without it, its just a river doing the same thing.
@@TheBooban no. In normal dams, the water continues along the river, as you pointed out. At Manipouri, the water is diverted away from the river, through the mountain, and directly into the sea.
@@debochch either way, it is going into the ocean right?
One thing is darned sure, you cannot desalination seawater economically with pressurized water reactors. The value comes when you have the higher temps of molten salt reactors. Especially when you use only nuclear waste from pressurized water reactors with the fuel incorporated into the molten salt. Iridium is like burning gold to make energy, sure you can do it but why would you?
PWR is not the ideal rectors we want to even consider when Thorium Salt Reactors have proven to be better in most aspects compared to PWR…we just need the power to operate RO water purification, the other methods of desalination are energy intensive and are quite dangerous in when paired to PWRs
this is for sure a great video, and I enjoyed watching ! subbed and liked ! a fellow creator
I'm a social justice warrior.
Thank you, nice video! Please consider listing sources of information ( most do it below video ) so viewers can verify that this is information not entertainment..
Molten salt/thorium reactors are far safer from meltdowns compared to uranium reactors
Let's consider all the things that could go wrong while things are already going wrong but you find no fault with them.
Normal reactors are safe already. Just take a look at the deaths per kwh, only solar and wind are better than nuclear
Most MSRs are designed to use uranium, and thorium can and is being used in pressurized water reactors
Not really safer, but they achieve it in a different way that is easy for the lay public to grasp -- "already molten, so can't melt down".
Solar thermal can help to boil the water in either oil, gas or nuclear desalination plants. It can be a pre heater or cycled through a heat pump to heat the water and save other fuels/ improve output with nuclear. Also sea salt is useful, why not keep it rather then dumping it back in the ocean? That could be a good side business. I also think that ocean thermal heat pumps could use heat from surface sea water to boil the water too. Waves could help to pump the water...
I've heard about Thorium salt cooled nuclear reactors and the possibility of using the waste brine from desalinization as the coolant for those Thorium reactors so there won't be any waste
Do the thorium salt nuclear reactors need to have the salt refreshed? I thought once they have the salt, they can just keep using it and don't need anymore.
I think that might clog or erode the pipes.
No you don't want to use the brine as the coolant. At all. Straight up NaCl/KCl already is a kinda lousy medium for the neutronics but it's not even pure stuff if its coming from the ocean.
You've got some wires crossed there. It's the waste heat from the reactor after thermo-mechanical conversion used to heat the saltwater for desalination purposes.
You're confusing different types of salt. The salts in the ocean are dissolved in water, while when you hear Molten-Salt Reactors, it refers to dry, completely water-free salt being heated to the point of melting -- and it's additionally a different type of salt than the type you find in the ocean.
Something missing here. Usually MSF heat source is waste heat from a thermal generating plant. Heat that is of low grade and wouldn't generate much electrical power in turbines. Also does the elec energy number for RO include energy recovery of the brine. That can really change the energy balance of RO.
The use of reactors for desalination is only hampered by current reactors that produce very nasty waste and weapons materials. Using thorium reactors would eliminate the waste and weapons materials issue as well as be capable of desalination as part of their cooling system. The concentrated brine can be pumped into evaporation ponds and the resulting salt used for other industrial purposes or diluted with raw seawater and returned to the ocean/sea it was taken from. By building multiple plants in areas where earthquakes and tsunamis are less likely and/or building facilities able to withstand them, water and power can be provided safely and in great quantities. The cost of running thorium reactors would be much less than uranium plants due to their inherent safety and lower radiation fuels and waste.
American is out of control - mercenaries to assassinate
ua-cam.com/video/xQR5WyTKB3s/v-deo.html
He didn't mention nuclear waste because only fools think it's any sort of problem.
Actually current designs produce a very small volume of dangerous waste. It’s said that over 90% of all nuclear waste has already been produced and most of that was from government nuclear weapons programs, not civilian power generation.
Was just thinking about it! And then the video dropped.
Could you imagine if we had put in all that alternative energy money in nuclear? We’d be carbon neutral by now with no rolling blackouts and perhaps not be in such worry of these droughts.
very interesting. I spent ten years in Saudi Arabia and used to frequent the beach near their desalt plant on the East Coast. We had two waters piped into our house, one was salty and the second 'sweet'. The sweet water was only available in the kitchen sink. that was all 20 years ago so not sure what they have now. Thank you for sharing your research.
just how salty was the water?
@@judgeomega I do not know the ppm of the salty water and also did not know the source, but it was very noticeably salty to the taste and would not be suitable for cooking with, for many people. there was a type of grass that could survive it, and so we did have grass in the yards. also, the Arabian Gulf water is noticeably salter, especially the restricted bays and inlets, than open ocean water. Scuba diving in Arabian Gulf required more weights than diving in (for example) Philippines, because of that extra salinity. The situation is similar (but not as extreme) to what we read about the Dead Sea and how easy it is to float there.
It’s Ka-zak-stan not kazakastan
I thought he said kazakistan. Still wrong and a bit jarring though. Like how Chinese speakers love to "localize" the pronunciation of foreign names, making it completely unrecognizable.
At 08:09 I would have to disagree with the graphic. At least for the current PWRs, The main steam enters both high pressure and low-pressure turbine to remove as much energy from the steam to turn the generator. Once it exits the turbine, the vacuum from a condenser is what pulls the exit steam and the secondary cycle once again starts over. With your graphic, it seems to suggest that some energy be used for power and the rest would be for desalinization. The problem I see with that is you now introduce two potentially variable outputs in your secondary loop that likely result in more significant power level variations in the reactor. This is not very good from both a Nuclear Physics standpoint nor Nuclear safety. What would probably be the solution is that the power production side and desalinization side would be two separate trains and the nuclear operators would control the direction of steam through some sort of bypass valve. You actually see these discussions with some of the SMRs being developed. The big picture is that you want as little change to the reactor as possible, so the best bet is to change the direction of what the heat dissipates to versus bolting on an additional outpoint on one train.
I am not sure I get your point - Only super heated steam goes through the turbines, right?
So at some point after the turbine you need to condense the steam (for the next cycle) which is where the desalination plant comes in.
I don't think it uses some steam for power and some for desalination, rather the desalination plant is the condenser.
Anyway, that is how I am reading the graphic
A thermal desalination plant is just a cooler, it doesn't even need to be steam, as vacuum is being applied to the desalination chambers so salt water will boil of at less than 40 degrees.
Fill the world with Nuclear Desalination plants, solve water and energy problems. Seems like the best long term solution to these problems with current technology.
A good nuclear Desalination plant is a nuclear power plant first, and provides fresh water as a byproduct.
Please help me here with my understanding. (which is still limited). Desalination plants seem to be all the rage right now, and indeed, drinking water security is critical. But I am concerned with what happens to the salts that are removed from the saline sea water, is this slurry (Brine Discharge) pumped back into the oceans whence it came? have there been many (any) impact studies on what this effect has on the immediate ocean life near the location, or does it diffuse out quickly, as the ocean is vast. But I have to wonder about if this is scaled up around the globe, and the long-term effects of no only increased global temperatures, but potentially the increased salt percentage of the oceans.
But Chernobyl… the world will end if we increase the use of nuclear energy
/s
Chernobyl was due to bureaucracy, incompetentce and general retardation. If you look at 3 mile island in the late 70s and windscale in the early 50s, they are the only legit nuclear accidents, and they weren't that bad.
In places like Fukushima, they build a nuclear power plant in tsunami prone areas. And had the reserve batteries below the tsunami level, so water leaked out. There have only been 4 notable large scale accidents, and 2 weren't that bad.
More people have died in other energy production methods mostly from much higher pollution or mining
@@flatsurfaces1913 Pretty sure it was sarcasm.
Iran: we support using more nuclear energy
USA: no
Is this comment a Joke or is it real?
One of the challenges with nuclear power is that with their costs skewed towards being upfront, and their fixed life-span, you don't want to load-follow the grid, but instead you want to run at full capacity at all times, except during maintenance, and let hydro or gas power plants do the load-following instead.
How skewed towards the initial investment are the costs of desalination? Could it make technical and economic sense for a nuclear desalination plant to divert power away from desalination, and onto the grid during peak hours, and then go back to producing potable water, once demand falls again, later in the evening?
Does desalination have a significant thermal inertia, meaning it's hard to run the production in a stop-and-go manner?
As an electrician who has worked on US nuclear, combined cycle, solar, and wind energy plants, I feel that nuclear power is one of the greatest boondoggles ever perpetuated on humanity. It is by far the highest cost for electricity, and that is with the highest level of direct taxpayer subsidies. In the US, taxpayers have spent in inflation adjusted average, 3.5 billion dollars a year on nuclear energy since 1948, yet costs $131 to $204 per mega Watt hour, not including decommissioning, long term waste storage, security, and public insurance costs. While other power production does have some corollaries with toxic wast cleanup and security, they are minuscule compared to nuclear power. In contrast, renewable energy has received 0.38 billion in taxpayer subsidies since 1994, and costs between $26 to $50 per mega Watt hour.
The major myths about nuclear power that have been perpetuated since the 1950's is that it is clean, safe, and will be to cheap to meter. None of that is true. Many electricians will tell stories about having limited work times due to radioactive releases, and when we work, we have to have one other electrician watching everything we do to ensure that no mistakes are made, and the amount of redundancy is ridiculous, yet necessary. Last time I worked at the Humboldt Bay power plant that closed down in the mid 1970's, it still employed hundreds of people in decommissioning and working to contain the plume of radioactive groundwater from reaching out into the bay. There are military guards with automatic rifles with shoot to kill orders for anyone without proper access. You never ever take your badge off. This is the same in all US nuclear plants.
As to it being needed for its "low carbon electricity," it is like an electric vehicle in that it does not have a tailpipe or a smokestack that releases pollution at its point of use, but the entire supply chain for a nuclear power plant is very CO2 intensive. From the large mining equipment for the materials and fuel, to the refining and transporting of astounding amounts of metal and concrete to build the plant, and to the ongoing fuel supply, and then the temporary dry cask storage containers that are made out of 100 to 150 tons of steel and concrete, and will need to be replaced every 25 to 100 years for tens of thousands of years, it has been estimated by independent of industry and non aligned studies that nuclear power produces about the same amount of CO2 as natural gas. And when decommissioning and the increasing difficulty of extracting the deeper and less desirable uranium ores, it is now approaching that of coal.
To be fair to EV's they do offset their CO2 production compared to an ICE vehicle after about 6000 miles of driving, and only continue to produce less over time, especially as the electricity mix continues to contain more renewables.
Some very interesting ways of disposing of radioactive metals has been found, called "Dilution in the Consumer Stream" where the radioactive metals are shipped to foundries, chopped up into small bits, and then added a little at a time into larger batches for consumer goods and building materials. The amount of construction materials it takes to build a nuclear plant compared to a conventional plant just boggles the mind, and having worked there, I would not trust my life on them. Since no insurance company will insure nuke plants, the US government requires them to carry 450 million of insurance for each reactor, with another 13 billion available from all of other nuke plants kicking in extra money. Any more cost for "accidents" would be picked up by the US taxpayers via congressional approval. As Fukushima is expected to pass the one trillion dollar mark soon, that would leave the US taxpayers on the hook for 987 billion dollars for the same type of accident. That is a lot of money to gamble with, and would go a long way towards paying for the renewable energy to replace nuclear power.
What about brine? Raising up salt concentration to like 162637282916262718kg/L nearby the plant
not the first comment!!