Solar module prices reached a new low this week, says Leen van Bellen, business development manager Europe for Search4Solar, a European purchasing and selling platform for solar products. He tells pv magazine that prices will remain low in the short term.
$60k per MW or $210M for a nuclear reactors worth (3.5GW). Sure… the reactor will go 24/7 (between maintenance and refuelling down times, and will use less land (1.75km² Vs ~40km²) but at 1% of the cost, why are we still talking about nuclear.
(I’m using the UKs Hinckley Point C power station as reference)
Because there are nights there are winters there are cloudy and rainy days, and there are no batteries capable of balancing all of these issues. Also when you account for those batteries the cost is going to shift a bit. So we need to invest in nuclear and renewables and batteries. So we can start getting rid of coal and gas plants.
But Germany has no space for nuclear waste. They haven’t been able to bury the last batch for over 30 years. And the one that they buried most recently began to leak radioactivity into ground water.
And… why give Russia more military target opportunities?
I’m not a rabid anti-nuclear, but there are somethings that are often left out of the pricing. One is the exorbitant price of storage of spent fuel although I seem to remember that there is some nuclear tech that can use nuclear waste as at least part of it’s fuel (Molten salt? Pebble? maybe an expert can chime in). There is also the human greed factor. Fukushima happened because they built the walls to the highest recorded tsunami in the area, to save on concrete. A lot of civil engineering projects have a 150% overprovision over the worst case calculations. Fukushima? just for the worst case recorded, moronic corporate greed. The human factor tends to be the biggest danger here.
Another example that gets skimmed over or ignored is the massive cost of decommissioning a nuclear power plant. It typically ranges from $280 million to $2 billion, depending on the technology used. More complex plants can be up to $4 billion. And the process can take 15 to 30 years to complete.
Those are less competitive, and salt reactor attempts have historically caused terminating corrosion problems. The SMR “promise” relies on switching extremely expensive/rare/dangerous plutonium level enriched fuel, that rely on traditional reactors for enrichment, for slightly lower capital costs.
Not an expert, but molten salt reactors are correct. MSRs are especially useful as breeder reactors, since they can actually reinvigorate older, spent fuel using more common isotopes. Thorium in particular is useful here. Waste has also been largely reduced with the better efficiency of modern reactors.
Currently, Canada’s investing in a number of small modular reactors to improve power generation capacity without the need to establish entire new nuclear zones and helps take some of the stress off the aging CANDU reactors. These in particular take advantage of the spent fuel and thorium rather than the very expensive and hard to find Uranium more typically used. There’s been interest in these elsewhere too, but considering how little waste is produced by modern reactors, and the capacity for re-use, it feels pike a very good way to supplement additional wind and solar energy sources.
If France can find space, surely Germany can.
If Finland could find space, Germany definitely can.
Finland with it’s vast swathes of frozen tundra.
We don’t have vast swaths of Frozen Tundras. This isn’t Alaska.
And it’s actually stored south not north.
Idk, Finland has a much lower population density vs Germany. France is something like 1/2 the population density, but they also have >50 reactors, so surely Germany can find room for a few…
Finland smaller tho.
Where do you want to put your hazardous waste again?
Yup, but population density should be what matters, because that implies how much usable space there is for waste disposal.
And Sweden.
You better be bringing units if you’re going to be claiming this.
Still less than half of the LCOE of nuclear when storage is added: https://www.statista.com/statistics/1475611/global-levelized-cost-of-energy-components-by-technology/
Given that both solar and storage costs are trending downwards while nuclear is not, this basically kills any argument for nuclear in the future. It’s not viable on its face - renewables + storage is the definitive future.
And cheaper solar and batteries permits cheaper Hydrogen which provides unlimited and 100% resilient renewable power, and still cheaper than nuclear.
I have a generally negative impression of hydrogen because many of the intended use-cases seem to be a cover story for the gas industry to keep existing, which it very much should not be any more.
Do you know any use-cases where hydrogen is truly warranted, outside for example steel production, which I think might be legit?
The case for an H2 economy is one entirely based on Green H2 made from surplus renewables which are needed most days to have enough renewable energy every day.
That gas companies know how to build pipelines, distribution, and make metered gas sales to customers is a path for them/employees to remain useful without destroying the planet.
Commercial vehicles has legitimate benefits of lower cost from H2 FCs than batteries. Quicker refuel times. Aviation especially benefits from redesigning planes for H2 for the weight savings. Trains/ships need the power/range. Trucks/cars can use the range extension, and could use H2 as removable auxiliary power for extended range.
Those vehicles can also charge the grid, and as hybrids, EVs or grid can be charged from static H2 FCs. For building energy, a FC can provide the usual fraction of domestic hot water from its waste heat. The electric monopoly problem is an opportunity for both producers and consumers to bypass their high rates and fees. Ammonia and fertilizer is traditional use for H2. There needs to be a carbon tax to move away from giant fosil H2 plants powering next door giant ammonia/fertilizer plants.
Hydrogen electrolysis is just one form of electro chemistry. Other fertilizers can be made from simpler versions of the process. It’s not so much that H2 is essential in unlimited quantities, it is that electro chemistry is possible ultra cheaply when there is an abundance of renewables that provides enough energy every day to power their locality. H2 is special as a chemical for being transportable/convertable as mobile or other elecricity/heat.
Wouldn’t it be more compelling to store it in other types of batteries instead of H2 primarily?
I honestly don’t think H2 is a good idea for these use-cases. H2 distribution is a different beast than natural gas distribution, on top of gas combustion just generally not being particularly good compared to common household electrical counterparts (induction for stoves, electric for ovens, heat pumps for heating buildings and water).
I imagine refueling times is not necessarily going to be critical for all types of commercial use-cases.
Aviation struggles with the relatively low energy density in H2.
Trains should essentially always be running on catenaries.
Boats might be able to make use of H2, I’m not super familiar with the issues affecting them.
Long-hail trucking should broadly be replaced by the much more efficient rail shipping.
Cars run pretty much fine on electric as is, I’m not sure the case for making H2 cars is compelling enough to be warranted.
This might be a good niche for H2 to fill.
All in all, I’m still not convinced that large-scale H2 buildouts is a good use of our resources, but there are definitely a few compelling niches that it can fill. We need to be wary of them being co-opted by blue hydrogen fossil fuel companies though, which often seems to be the case today.
The economics of batteries are that they must be fully charged and discharged daily to pay off. A 2 day average cycle is double the cost of energy in using them.
In spring and fall we get positive happy headlines that “all electricity was provided by solar/renewables” during 1 hour or so during a day, or that electricity prices went negative. These seasons are low demand with good enough sun. Batteries get let those days/seasons get to 24 hour power from renewables, but then summer heatwaves won’t fill demand even with more sun, winter will not charge up the batteries enough. H2 electrolysis is needed to have enough solar and batteries to cover all those needs, and then use H2 to cover winter supplemental needs. H2 supports not just more solar, but also more batteries. Makes sure batteries can always discharge before the sun comes up.
Commercial vehicles, need to pay operators for downtime, and downtime is time not earning revenue. it is a bid deal to them.
At $4/gallon diesel/kerosene, a plane will cost 100x in fuel as its purchase costs. We can already produce green H2 at $2/kg compressed. Which is equivalent to $1/gallon gasoline fuel when used in a FC. Redesigning planes, and delta wing for long range specifically, for H2 is worth liquifying the H2 for the weight savings and range over compressed. It’s also that price that can compete well with commercial EV charging.
You’re using factors of less than 10 to argue against a factor of 100.
The batteries needed are a lot less than you might think. Solar doesn’t work at night and the wind doesn’t always blow, but we have tons of regional weather data about how they overlap. From that, it’s possible to calculate the maximum historical lull where neither are providing enough. You then add enough storage to handle double that time period, and you’re good.
Getting 95% coverage with this is a very achievable goal. That last 5% takes a lot more effort, but getting to 95% would be a massive reduction in CO2 output.
I think there’s a contingent of people who think nuclear is really, really cool. And it is cool. Splitting atoms to make power is undeniably awesome. That doesn’t make it sensible, though, and they don’t separate those two thoughts in their mind. Their solution is to double down on talking points designed for use against Greenpeace in the 90s rather than absorbing new information that changes the landscape.
And then there’s a second group that isn’t even trying to argue in good faith. They “support” nuclear knowing it won’t go anywhere because it keeps fossil fuels in place.
What isn’t sensible about nuclear? For context, I’m coming from the US in an area with lots of empty space (i.e. tons of place to store radioactive waste) and without much in the way of hydro (I’m in Utah, a mountainous, desert climate). We get plenty of sun as well as plenty of snow. Nuclear should provide power at night and throughout the winter, and since ~89% of homes are heated with natural gas, we only need higher electricity production in the summer when it’s hot, which is precisely what solar is great for.
So here’s my thought process:
If we had a nuclear plant in my area, we could replace our coal plants, as well as some of our natural gas plants. If we go with solar, I don’t think we have great options for electricity storage throughout the winter.
This is obviously different in the EU, but surely the nordic countries have similar problems as we do here, so why isn’t nuclear more prevalent there?
Because it makes no sense, environmentally or economically speaking. Nuclear is, as you said, base load. It can’t adjust for spikes in demand. So if there’s more energy in the grid than needed, it’s gonna be solar and wind that gets turned off to balance the grid. Investments in nuclear thus slow down the adoption of renewables.
Solar is orders of magnitude cheaper to build, while nuclear is one of the most expensive ways to generate electricity, even discounting the waste storage, which gets delegated the the public.
Battery technology has been making massive gains in scalability and cost in recent years. What we need is battery arrays to cover nighttime demand and spikes in production or demand, combined with a more adaptive industry that performs energy intensive tasks when it’s abundant. With countries that have large amounts of solar, it is already happening that during peak production, energy cost goes to zero (or even negative, as traded between utilities companies).
About the heating: gas can not stay the main way to heat homes, it’s yet another fossil fuel. What we need is heat pumps, which can have an efficiency of >300% (1kWh electricity gets turned into 3kWh of heat, by taking ambient heat from outside). Combined with large, well-insulated warm-water reservoirs, you can heat up more water than you need to higher temperature during times of electricity oversupply, and have more than enough to last you the night, without even involving batteries. Warm water is an amazing energy storage medium. Batteries cover electricity demand as well as a backup in case you need uncharacteristically much water. This is a system that’s slowly getting adopted in Europe, and it’s great. Much cheaper, and 100% clean.
You bring up heated water as a method of storage, and it reminds me of a neighborhood in Alberta, Canada that uses geothermal + solar heated water storage for 52 homes. They’ve been able to successfully heat the entire neighborhood with only solar over the winter in 2015-2016 and have gotten > 90% solar heating in other years.
https://en.wikipedia.org/wiki/Drake_Landing_Solar_Community
There’s a huge number of new storage technologies being developed, and the fact that some even work on a seasonal basis for long term storage is amazing.
That’s pretty cool! Still seems to have some issues, but as the technology matures, that seems like a promising technology. I didn’t know seasonal warm water storage was a thing
We also should consider HVDC lines. The longest one right now is in Brazil, and it’s 1300 miles long. With that kind of range, wind in Nebraska can power New York, solar in Arizona can power Chicago, and hydro all around the Mississippi river basin can store it all. We may have enough pumped hydro already that we might not even need batteries, provided we can hook it all up.
HVDC is much more expensive than Hydrogen pipelines, which doubles as storage and transmission, and can provide continent wide resilience, even when local renewables provide much cheaper power when it is available than either long distance electric or H2 power.
The studies on hydrogen pipelines tend to assume there’s some existing reservoir of hydrogen. Making hydrogen in a green way is expensive, and that completely ruins its economic viability.
The expense part gets taken care of with OP’s solar prices. Battery costs help too.
Not at all. Hydrogen electrolysis efficiency is about 70-80%. When turning it back into electricity, fuel cells are 40-60% efficient. That means your electricity costs are about double for the complete round trip.
Conversely, lithium batteries (and most other types) are over 90% efficient and directly give you electrons.
I absolutely agree. My support for nuclear is not instead of renewables, but in addition to it. Nuclear is a proven technology, and at least in the US, we have a lot of space where we can store waste relatively inexpensively (nobody’s going to care about a massive landfill in Nevada).
The problem with going for 100% renewables is that I don’t think we can really keep up with battery production, and if we push for dramatically increasing our energy storage capacity (whether that’s chemical batteries, pumped hydro, etc), it’s going to cost a ton to transition. Solar is cheaper than nuclear, but solar + battery backup currently is not, especially if it needs to run over the winter when solar generation is much lower.
I’m not saying we should stop installing battery-backed solar projects, but that we should add nuclear to the list. Our electricity demand will only continue to increase, so we need multiple solutions to replace coal and eventually natural gas. One of the major cost and time limitations for nuclear is construction, and that’s because we don’t build many of them. If we line up multiple plant projects at the same time, we can make better use of our engineering resources (it’s a lot easier to build 10 of something back to back than 10 of something months or years apart), which will make nuclear more attractive compared to other options.
Agreed, and I’ve actually been looking into heat pumps for my own home. I already have an external AC unit, so theoretically the transition shouldn’t be that hard (air ducts already exist).
The problem is that, in my area, winters get pretty cold, and heat pumps are a lot less efficient at heating when it’s cold. The solution is to dig a deep hole to bury the heat exchangers so they get a more consistent temperature to maintain efficiency, and that’s a really expensive project for existing structures (not bad for new construction). The transition to heat pumps is going to be very slow because of that large upfront cost/poor efficiency in winter.
Even if this wasn’t an issue, there’s still the massive problem of existing electricity production (in my area) being fueled by coal and natural gas. If I switch to a heat pump, I may be polluting more than if I stuck with gas (it’s pretty close last I checked). My state (ignoring transportation) gets something like 1/3 of its energy from coal, about half from natural gas, and most of the rest comes from solar (and a little from wind). We need something to handle that base load supply, and installing batteries is going to be expensive (esp. since hydro isn’t really an option in our desert) and probably take many years regardless. Nuclear can be built today, and in my area, it can be built on the other side of a mountain range from the bulk of the population.
I doubt we have enough water here in the desert to handle that. We already have problems with our existing inconsistent water supply for regular users, locking up even more water is going to be a really tough sell.
I agree it’s going to be a challenge. But I’m sceptical nuclear is going to help there; from historical experience, it takes upwards of 20 years to build a reactor. Even if that gets expedited through modern technologies, we’re still talking something like 15 years until they come online, and you’re still paying all the upfront costs throughout that time. Whereas solar can go from concept to grid in 2 years, and batteries aren’t much worse.
The desert indeed makes large-scale warm water storage infeasible, but the kind of home setups I mentioned first should still be good to go, it’s basically only your preexisting heating loop times 2 or 3, that’s negligible compared to farming demands, and it stays in the loop forever (except for leakage). Storing warm water that you’d use anyways also doesn’t increase demand.
The desert has the benefit that solar can be really well calculated, since you (mostly) need to consider seasonal changes in sunlight, not cloud cover. That can be planned around
You got a point about the heat pump efficiency though. For new communities there should be a trend towards centralized heating that provides for a whole city block, to make use of economy of scale and raise efficiency beyond what is reasonable for a single home. But that’s dreaming to far, probably
From some reading, it seems a lot of that is bureaucracy (non-safety related), construction delays, and lawsuits. I wouldn’t be surprised if we could get that down to 10 years average with a concerted effort, assuming we can build multiple in parallel.
Sure, on a small-ish scale. A nuclear plant will put out way more electricity than a typical solar project will. So while the time to getting value from it will be a lot shorter w/ solar, they tend to chip away at existing infrastructure instead of completely replacing plants.
Oh yeah, solar is incredibly effective here, the main problem is storage. Hydro isn’t really a thing since our dams are intended to keep water for summer use, and they refill when we’d want to be generating power. Warm water also isn’t feasible at scale, and promising technologies still aren’t proven. I’m especially interested in hydrogen storage, since it could be really useful for long-haul trucking (we’re a pretty big hub for that) in addition to storage for winter generation.
I was interested in EVs being used for overnight power storage (basically recharge during the day while at work), but it seems like that hasn’t materialized.
I don’t think we’d need to go that far, putting in buried heat exchangers on new construction isn’t that expensive, and I’d expect coordinating billing and whatnot would be more annoying than it’s worth (need an HOA, and HOAs can really suck).
The better option, IMO, is to create mixed-use zoning near transit hubs, which would encourage use of mass transit and allow for those economies of scale you’re talking about without annoying planned communities w/ HOAs (i.e. business below you could pay your heating/cooling bill). Maybe that’s what you were getting at, my point is that it doesn’t make as much sense for residential areas IMO, but it could make sense for mixed zoning areas.
I do want to point out that I’m not obsessed w/ nuclear or anything, I just think it’s a good option to replace existing base-load plants running on coal and natural gas.
I’m very much in the first camp and need to remind myself whenever I think about arriving due nuclear
The land thing isn’t anywhere near enough of a concern for me, especially when dual uses of land are quite feasible.
24/7 is just about over commissioning and having storage. Build 10x as much and store what you generate. At those sorts of levels even an overcast day generates.
Using the remaining 99% of the cost to bury batteries underground would seem reasonable.
Batteries can be containerized in modules, with a turnkey connection that remains mobile. Solar can use those containers as support structure. Hydrogen electrolyzer/fuel cells can also be built in same containers.
Underground construction generally isn’t cost effective. It costs way more to get dirt and rock out of the way than just building a frame upwards. There might be other reasons to do it, but you want to avoid it if possible.
The underground suggestion was only to counter the argument of space usage.
There’s a million other ways to go. Solar on every parking lot, over every irrigation canal, and along every highway. Some farming can be done under solar panels, as well; some commercial crops prefer shade, such as strawberries.
The US uses about 30% of its land for cows. One simple plan is that we all eat one less burger a week. Which would be a good idea, anyway.
Land usage is so not a problem as soon as you open up the dual use possibilities.
For dual use, I’m particularly partial to the solar fence
Because grid level power delivery is about FAR more than just raw wattage numbers. Momentum of spinning turbines is extremely important to the grid. The grid relies on generation equipment maintaing an AC frequency of 60 hz or 50hz or whatever a country decides on. Changing loads throughout the day literally add an amount of drag to the entire grid and it can drag the frequency down. The inverse can also happen. If you have fluctuating wind or cloud cover you can bring the whole grid down if you can’t instantly spin up other methods to pick up the slack.
reliable consistent power delivery is absolutely critical when it comes to running the grid effectively and that is something that solar and wind are bad at
Ideally we will be able to use those technologies to fill grid level storage (batteries, pumped hydro) to supply 100% of our energy needs in the not too distant future but until then we desperately need large, consistent, clean power generation.
You aren’t wrong, but you are assuming that the grid is required. Solar panels can be installed at the point of use, and then the grid doesn’t come into it at all.
I agree, but off grid solar requires a lot more panels and personal infrastructure owned by the customer than grid tied solar. and a storage solution for night time and winter and cloudy days.
A typical house isn’t going off grid and maintaining a worry free electric schedule without a minimum of 25,000$ of panels, mounts, inverters, batteries, BMS, cabling, installation, and permits.
To be fair, the cost is still less than the amount of time the system will last so economically is can be viable but who has 25,000$ just sitting around…you have to be able to install it yourself to save enough money to really even think about doing it.
I am on your side, but we should be focusing on storage technology right now because solar is honestly really advanced at this point. Once those technologies can work together all the arguments against solar that make sense disappear.
That’s the worst way to do solar, though. It doesn’t get to take advantage of economies of scale in installation and inverters. Some levelized cost of energy studies put it just as expensive as nuclear.
Solar gets its cheapness when it’s in fields or on top of large, flat commercial/industrial buildings.
Do commercial/industrial buildings not require power then?
There’s often enough space on those buildings for excess power. Not all those buildings have particularly intensive energy needs. Many are just warehouses.
We can’t manufacture and install enough solar farms and storage to get us off of fossil fuel within 20 years and more importantly available investment capital isn’t the limiting factor.
Investments in nuclear power are not taking money away from investments in solar.
We can do both, and it gets us off fossil fuels sooner.
This is interesting. Why do you think that?
I would disagree, because is see investment capital as finite. There are only so many investors able to operate at infrastructure scales. And therefore I see nuclear’s true cost as opportunity cost.
From an investor perspective, solar farm projects are a slam dunk once they reach the point of being ready to purchase panels.
There are a lot of things to line up to build a grid-scale solar farm before you get to that point. You need to acquire (the rights to) the land, get permits to connect to the grid, which usually includes construction of the new transmission line to the grid. You need to line up panels from a manufacturer (who in turn has supply chains to manage), and labor to install it. And 100 other things. It typically takes a few years of planning, but get all that in order and it’s a small percentage of the total expense of the project.
At the point you need to do the larger capital raise needed to buy the panels and hire the labour it’s a slam dunk. The project can be completed typically within 12-24 months so there’s a quick process to get to generating revenue for investors, and because solar has gotten so cheap it doesn’t take long to see positive ROI. It’s not like electricity demand is going away either. It’s a very safe bet, once all the pieces are lined up, and not difficult to raise funds once you get to the point of needing the big money.
People on Lemmy/Reddit have this mental model that there’s a fixed budget for investment in the energy transition. If that was the case, then yes it would make sense to go all in on the cheapest technology option.
But that’s how it works. Energy projects are competing with the global market for investment capital with non-energy related investments and there’s no shortage of wealth wanting to throw money at a solar project because they’re low risk/high ROI.
Nuclear projects are a different story, long timelines from construction to revenue generation and high upfront capital costs make them unfavourable investments, they generally need government support to derisk the investment before investors jump on board. Which the governments are reluctant to do because they lack a mandate to do so from the populace. In part because of this mindset that nuclear investment impedes solar or wind investments.
Total solar manufacturing capability has been increasing exponentially. So has wind, and so have various storage methods.
Yes, we can install enough.
Solar has been growing exponentially for the past decade or so, wind has not. Wind has run into supply chain limitations on rare earth metals such as neodymium and isn’t growing exponentially anymore.
It’s doubtful that solar will continue growing exponentially for the next 20 years but even if it does, that only gets us to the point of enough capacity to displace the ~17.9 PWh of electricity generated by fossil fuels in 2023.
To get off of fossil fuels we need to change everything else that’s burning fossil fuels too. That means every vehicle replaced with an EV, every gas furnace replaced with a heat pump. As we do that it’s going to 2-3x electricity demand.
The world burned 140 PWh worth of fossil fuels in 2023, and we only generated 1.6 PWh from solar power. That 1.6 is up from 1.3 PWh in 2022. A lot of that 140 PWh was wasted heat energy so we don’t need to get that high, but we still need to generate something in the area of 60-90 PWh of electricity annually to eliminate fossil fuels.
~4/5th of our energy still comes from fossil fuel, we have a long f’ing way to go. Even with the current exponential growth of solar we don’t get off of fossil fuels within 20 years, and that’s assuming global energy demand doesn’t increase.
Don’t take my word for it. Extrapolate the data yourself. Your rose coloured glasses aren’t helping.
That’s why we also need to reduce our use of pretty much everything. We can never reach zero fossil fuel used, unless we start by reducing the amount of stuff we buy/use, starting with things that currently use fossil fuels: cars, shipping, flights, plastics and so on.
Then we could use renewable energies only or nuclear only or a mix of both to power what is truly necessary for our lives.
Except that this has actually been studied, and a future with Wind/Water/Solar (WWS) is completely viable without a single new megawatt of nuclear.
https://www.amazon.com/No-Miracles-Needed-Technology-Climate/dp/1009249541
It’s not a question of viability it a question of time.
Can we replace all fossil fuels with wind and solar power only? Absolutely.
Can we do it by 2050? Not without a miracle.
Yes, we can. Again, this is all part of these studies. It is easily the most economical viable and fastest plan.
You seem to be misunderstanding friend.
I’m all for building as much wind, hydro, and solar power as possible. It is the cheapest option.
I’m not arguing against that.
People here seem to think that money spent on nuclear is money NOT spent on Wind/Solar/Hydro/Storage/etc as if there’s a fixed budget for all energy transition projects. That’s not the situation.
Insurance and financial institutions are losing big money on climate change disasters, and they are getting data from their actuaries and climate scientist, saying it’s going to get massively worse. There is rapidly growing interest from “big money” private sector investors, In any technology that might solve the climate crisis.
There’s more money investors wanting invest in wind, solar, or hydroelectric projects, than there are projects to invest it. The limiting factor isn’t money.
Believe me, no one would be happier than me to be proven wrong that we can build enough wind, solar, and hydroelectric to get off a fossil fuels by 2050.
But if you extrapolate the current data and the current trend lines, they don’t come anywhere close.
If we also invest in nuclear, we come closer.
Let’s say you have money to invest in the energy sector. You take a look at nuclear and find that while the regulatory environment is very high, it isn’t insurmountable. The Department of Energy has shown a willingness to sign off on new nuclear projects as long as you do your homework. It’s a lot, but it can be done.
Next, you look at the history of building projects. The baseline for time to build is 5 years, but everyone knows this is a lie. That thing isn’t getting done for at least 7 years, often more like 10. Its budget will expand by about the same proportion. You won’t see a dime of profit until it’s done. If it can’t raise the money from either yourself or other investors to cover the shortfall, then it’s useless and your entire investment will be wiped out.
The Westinghouse AP1000 design was hoped to get around some of the boutique engineering challenges of building nuclear in the past. It did not.
If you instead invest into solar or wind, you’ll find some regulatory hurdles. Mainly from the local NIMBYs. The hookup agreements with the utility companies take some doing, but it’s not outrageous. Looking at the construction side of things, these projects are pretty much turnkey. They don’t require any specialized engineering (not the way nuclear does). They tend to get done on time and within budget.
This, too has been studied. The average cost overrun of a solar megaproject is 1%. For wind, 13%, and it’s 20% for water. Want to know what it is for nuclear? It’s right near the top of the list at 120%. The only megaprojects on the list that do worse are Olympic Games and nuclear storage.
With numbers like that, it’s no wonder investors are dumping their money into solar and wind.
A MW of solar averages out to about .2 MWh per hour. A MW of nuclear averages about .9 MWh per hour.
But even so as the UK does it, nuclear power isn’t worth it. France and China are better examples since they both picked a few designs and mass produced them.
China’s experience indicates you can mass produce nuclear relatively cheaply and quickly, having built 35 out of 57GW in the last decade, and another 88GW on the way, however it’s not nearly as quick to expand as solar, wind, and fossil fuels.
There is MW which is a unit of power and then there is MWh which is a unit of energy, but what is MW/h supposed to mean?
Thanks for catching the typo.
In many regions solar capacity factor is much higher than 20%; for example, the entire US. https://atb.nrel.gov/electricity/2021/utility-scale_pv
Maybe just use percentages instead of these weird units. 0.2 MHh per hour is just 0.2 MW, or 20%.
It seems easier to say solar produces an average of 20% of it’s peak capacity.
Nuclear actually around 0.6, because 1/3 is always off for repair and control.
Maybe in the UK where each plant is basically unique instead of having improvements from all the previous iterations. In the US it’s around 93%. I don’t know how to search China or France’s numbers, but I suspect they’re similar or better.
My observations are from France, germany, switzerland though. Maybe we are a bit more careful and by-the-protocol here, who knows.
On the other hand, rarely has one more than 3 blocks here, and a colourful mix of generations. You might be right.
You have to have some base load it can’t be all renewable because renewables just aren’t reliable enough. The only way to get 100% reliability from solar for example would be to build a ring of panels around the equator (type 1 civilization stuff).
Of all the options for base load, nuclear is the least worst, at least until we can get Fusion online, but you know that’s always 20 years away.
That’s why we have hydro. Its a giant battery. We can also make synthetic methane.
We absolutely can do 100% renewable.
Hydro is great but it’s not clean it requires you to flood vast areas of land, it’s quite damaging to wildlife.
It is also highly situation dependent, you be quiet exactly the right kind of geography in order to be able to build hydro and then you require that there is no one living in the affected area otherwise it gets very expensive very quickly assuming you’re allowed to do it at all.
I didn’t say hydro is perfect. It is renewable. And its a giant battery.
Hydro is kinda awful for the environment.
Better than fossil fuels
Storage. It’s all about storage. In exactly the same way that our water is handled. We have reservoirs to handle the times when natural water supply is low.
Also the budget and timeline is always understated, because otherwise government could withdraw funding if they don’t sink a little more cost into the budget every year.
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