> A comment on the YouTube video below complained, “Not a word about return on investment in the presentation. That means it’ll never pay off” MAGAlomaniacs are everywhere these days.
Given the supposed 50+ year lifespan of such a battery, I find it hard to believe it doesn't turn a profit at some point. And I understand that debunking low-effort accusations is asymmetric warfare. But why cite a random YouTube comment if you have no intention of addressing its claims? A more charitable interpretation is that it's meant to ragebait the readers. But to me, it seems like trying to make people feel ashamed for having doubts, by making a public example of a skeptic.
kragen 1 days ago [-]
If, say, further insulating your house or building a sand battery will pay for itself in 50 years, it's a bad investment, financially speaking, and probably environmentally speaking as well. You can deploy "the same amount" of resources in something else with a higher ROI, like maybe solar panels with a one-year payback, and get a much bigger benefit. This is an important consideration as long as you are constrained by some kind of resource limitation.
So I think ROI is a first-order consideration.
danielfoster 24 hours ago [-]
I agree with you, but one point I see everyone missing is the fact that this is a first-time installation of a new technology that hasn’t scaled. There needs to be a business plan of course. At the same time, no one would expect to see ROI figures for the first build of a concept car.
kragen 22 hours ago [-]
That's because concept cars aren't investments. This project is an investment. Investors invest in investments to get a return on their investment (ROI). Car buyers, other than car dealers and outfits like Budget Rent-A-Car, do not buy cars to get ROI. Advertising an investment without publishing any projected ROI figures (the business plan you mention) is like advertising a concept car without publishing any photos, video, or drawings.
Finland is the only country in the world where solar isn't the cheapest form of electricity because they get so little sun and they have good alternatives.
fulafel 7 hours ago [-]
You could be forgiven to think that about northern places, but the dark winters are compensated by the long (or even round the clock) daylight in summer. It's still fewer sunlight hours than markedly sunny places like italy or california but not 50% less.
But of course wind is more stable around the year and produces more in the winter when there's more need for energy. And the sunlight is more direct closer to the equator.
bryanlarsen 7 hours ago [-]
I didn't just think that, I read it in a news article about a study. My memory of what I read may be faulty, though.
Besides fewer sunlight hours, Finland also has lots of clouds and very steep sun angles which significantly affects production.
fulafel 6 hours ago [-]
The cloudiness is accounted for in the visualization, otherwise you wouldn't see that much variation on the same latitudes. But yep the sun angle affects things too like I mentioned.
hulium 1 days ago [-]
Certainly not the only country. Iceland is even more extreme in this regard and unlike Finland it is powered by 100% renewables, hydro and geothermal energy. In Finland the only good renewable alternative is wood/biomass.
bryanlarsen 1 days ago [-]
Seems reasonable. I'll have to dig up my source to double check. Maybe they just didn't have Iceland data in their set? It's certainly a surprising result to see other non-sunny places like the UK, Germany, Norway & Sweden have solar as their cheapest energy source.
kragen 1 days ago [-]
It's hard to get really solid estimates for solar costs because they've been dropping so precipitously, and because they depend on so many ancillary factors: wiring, inspections, permitting, power electronics, storage, and so on. Getting solid estimates for solar return on investment is even harder, because it depends on the future price of energy.
bryanlarsen 1 days ago [-]
Yes, it's certainly possible that Iceland is better for solar than Finland not because of its sunlight, but because of those myriad extra factors.
ponector 1 days ago [-]
I'm sure there is no sense in solar energy in Iceland due to strong winds there as well as geothermal energy.
It's sad they are building gas-powered data centers in US instead of powered by renewables in Iceland.
kragen 23 hours ago [-]
Windmills can be surprisingly expensive. https://www.eia.gov/analysis/studies/powerplants/capitalcost... is not up-to-date, but I think the windmill prices in it have changed a lot less than the solar prices; the 200 MW onshore project they price out there comes to US$1265/kW (US$1.27/W), of which something like 61% is the windmills themselves. Low-cost photovoltaic solar modules currently cost €0.055/W (US$0.065/W), lower by more than an order of magnitude https://www.solarserver.de/photovoltaik-preis-pv-modul-preis....
So, at equal cost, the alternative to a megawatt of windmills may not be a megawatt of solar panels, but 10 megawatts of solar panels. And that can compensate for their lower capacity factor.
I don't think people are building gas-powered data centers in the US. There's a data center crunch in the US because people aren't building them because they can't get the power because of the US's anti-renewable-energy policies.
ponector 2 hours ago [-]
Difference is massive, but price of land should be also accounted for. Solar uses 5 times more land per MW.
The solution is to develop everything, all kinds of renewables.
kragen 2 hours ago [-]
Even the EIA-commissioned study I linked doesn't include that, but it is a potentially significant cost. If we take the median price of US$4702 per Texas "acre" from https://texasfarmcredit.com/resources/texas-land-pricing-gui... it works out to US$1.16/m². At 30° latitude your panels provide about 0.86 square meters of panel per square meter of land, or more like 0.3 with trackers, so the land price is on the order of US$3/m². A square meter is nominally a kilowatt of sunlight, so that's US$0.003/W of sunlight, but mainstream panels are usually only around 21% efficient, so it's more like US$0.015/Wp. Historically this has been insignificant but may no longer be with mainstream panels costing only US$0.10/Wp.
Desert land, lakes, and harbors are cheaper, so we should expect to see more panels there instead of on potentially arable land.
bryanlarsen 2 hours ago [-]
You can buy land in the desert for under $1000 an acre. There are places you can buy farmland for under $10000 an acre.
grues-dinner 1 days ago [-]
There's also some long-term risk here. If we, humans, did massive amounts of dispatchable solar and wind, plus systems like this, static battery storage, other storage and things like widespread EV capacity arbitrage, it's not guaranteed that the negative or even low energy price events would even happen. The more people think they can store it and sell it later, the higher the demand for off-peak power. You could end up with op-ex exceeding revenue in the future.
Then again, the same also goes for the other storage methods as the spread compresses. Eventually, as always, it all comes down to who can do it on the thinnest shoestring. 1/4 the cost, but the thermodynamic efficiency is 1/3 (direct heat vs batteries + heat pump, say) is still a winner. Finns aren't going to stop needing heat in winter soon, and if you can provide it even a fraction under the cost of battery electricity and a heat pump, you get the customer. And the district heat infrastructure probably already exists.
moooo99 1 days ago [-]
Its of course true that this will somewhat even out once storage becomes more available. But there are still market forces at play. If the electricity prices are higher, operators have a renewed financial incentive to generate more power (more power = more revenue), for example by re-powering solar and wind farms.
Theoretically this would be an endless cycle, which is of course constrained by very practical needs of the electricity users.
vjk800 1 days ago [-]
> Given the supposed 50+ year lifespan of such a battery
Surely the lifespan is almost forever. It's just a tank full of sand and some heating pipes. Maybe the pipes and/or control electronics needs to be replaced occasionally, but nothing should happen to the sand inside - like ever.
idiotsecant 1 days ago [-]
'just' the piping, pumps, control systems, electrical system, valves, instruments...
The sand is the least complex part. Industrial facilities like this take a lot to keep running.
JeremyNT 1 days ago [-]
I think the parent is suggesting that these things could be maintained in a cost effective way indefinitely. It's not like you hit year 50 and throw it away because of some inherent quality of the tech (as with nuclear plants or lithium batteries which fundamentally degrade in ways that are cost prohibitive to "fix").
The thing is, I'm unsure whether this holds true. Could you actually replace pipes inside a huge sand battery without bringing the entire thing offline? And at some point are you basically rebuilding it?
echelon_musk 1 days ago [-]
What does MAGA have to do with Finland?
conception 1 days ago [-]
Authoritarian populism support is rising globally.
bslaq 1 days ago [-]
Posting a comment doubting the ROI of a public investment is not “authoritarian populism”. If anything, democracy needs more of it.
Rebelgecko 1 days ago [-]
The problem is when it's based on bullshit, like the secretary of energy's recent claims that completely covering the earth in solar panels wouldn't be enough energy for our needs. Like his hypothetical Dyson sphere of solar panels, a lie on Twitter can make it around the world before the truth can catch up.
bslaq 1 days ago [-]
The problem is this is Finland and whatever the secretary of energy of the USA says is completely irrelevant.
y-curious 1 days ago [-]
Unfortunately, people seem to see Boogeymen everywhere when they're terminally online. It's kind of like the mid-2010s where everything someone didn't like was "fascist" or "Nazi"
garciasn 1 days ago [-]
Populist strongmen are rising everywhere; this is a fact. The People have short memories and seemingly have forgotten those who rose to power in the first half of the 20th Century and whom the Americans fought against for the remainder of it.
Apparently now it's time for the world to return to populist authoritarianism and isolationist policy in order to bury our heads in the...sand...until we have to collectively rise against them again. Except, this time, it may be America who bears the brutal brunt.
jagermo 1 days ago [-]
I find it fascinating that renewables always have to have a ROI.
nobody cares about his car loosing value as soon as you drive off the parking lot. Or any other appliance - a fridge will never have a ROI, a washing machine will not and neither will a stove, a macbook or a fancy smart home system. They are part of our live, loose value and we accept that.
But solar or batteries (granted, mostly with home-solutions)? Better make money, otherwise why even bother.
rogerrogerr 1 days ago [-]
ROI is implicitly against the alternative or status quo:
- Fridge: has ROI vs. going to the store more often or getting food poisoning.
- Washing machine: Has ROI measured in the value of your time spent not slapping clothes against a board to make them clean.
- Stove: ROI vs. using and maintaining a fire pit, with the risk of burning your house down factored in.
- MacBook: ROI is how much work you can get done vs. a Windows machine, or not having a laptop and doing math really fast by hand on paper.
Etc. It is suspicious that there isn’t a “this will pay for itself in N years vs. not having it” statement somewhere.
18 hours ago [-]
j45 1 days ago [-]
RoI is a fun one, anyone calling it out should be able to point out ROI as an example elsewhere that's accurate.
lupusreal 1 days ago [-]
> And I understand that debunking low-effort accusations is asymmetric warfare
Is the comment even that unfair? Asserting that it will never pay off because the presentation avoided mentioning anything about the payoff might be a little bit cynical, but not terribly so. It could be fairly presumed that if the project is a clear economic win, they would be proudly bragging about it; and the opposite presumption is also reasonably fair, even if it turns out to be wrong.
And what does such cynicism have to do with "MAGA"? That asserted association seems much worse than the initial cynical assertion.
blueflow 1 days ago [-]
> And what does such cynicism have to do with "MAGA"?
"Everyone i don't like is Hitler". It's a rather immature way of disagreeing.
All those subjects in the right context are things the left wing fights for. Reducing a complex subject and then saying because you do not agree with my interpretation you are against children, is not optimal. E.g. Climate Activists are a pretty diverse group you will find lots of people who have said the same thing. It is obvious this is a PR/Research stunt, but it might still pay off. This is not a straight forward discussion where all people in the right or left groups has to agree.
flanked-evergl 1 days ago [-]
I'm not saying it should be right wing coded, it's terrible that it is, but it has become so as far as I can tell.
ta1243 1 days ago [-]
People nowadays expect 10% return on their investment, so if you invest 1m you need to make 100k a year from it (120k to cover the deprecation over 50 years)
If you made 30k a year for 50 years you'd return 1.5m from your 1m investment, but you're only making 3%, which is a low return especially given the future risk (you'd have to run for 33 years just to get your initial investment back)
Either way it's worthwhile, because the reason people expect 10% is because the externalities are borne by others. Majority of people and countries in the world do not deem ROI to be the sole or even primary driver for investment, and judging investments only on the immediate financial reward already biases the conversation
Avamander 1 days ago [-]
> Majority of people and countries in the world do not deem ROI to be the sole or even primary driver for investment
It's partially that, other part is that we aren't really pricing in all the externalities of everything out there. So it's not that "there's no ROI", it's that "we aren't factoring things in the ROI calculation".
So while a heat battery might not make a huge profit, the ability to burn less fuel (less air pollution, less waste, etc), to offer redundancy and stability, the know-how and work it creates, that is all valuable as well.
hliyan 1 days ago [-]
Externalities can (and should) be priced in by taxes that offest negative externalities (e.g. carbon emissions, pollution). Unfortunately, legislative bodies that have to decide on taxes have a much cozier relationship with industry than they do with those who must endure the effects of negative externalities (the general population).
ta1243 9 hours ago [-]
Put a carbon tax on fuel in a western country and you end up with an unhappy population who pay more money in tax. Personally I'd distribute the revenue as a UBI which would mean the most polluting would be worse off but the average person would be better off.
The people who would mostly benefit from reduction in emissions - especially in the short term - are those in other countries. It's not going to be Finland suffering the most from doubling of the cost of food from failed harvests, it's going to be massive failures in rice harvests in south east asia. Finns will always be able to outcompete the average Cambodian when buying food.
One of the costs of emissions to western countries - say Spain - is increased bad weather - more frequent storms, fires etc. All fairly small stuff compared with mass starvation or water shortages though. That starvation leads to another problem -- increased migration pressure.
But those costs are going to be borne anyway. Even if Spain stopped emitting CO2, it wouldn't make an ounce of difference. International agreements have failed time after time to curb emissions.
The main benefit of renewable energy for a given country isn't the reduction in emissions, it's the increase in energy independence - no need to import gas or oil from unstable countries.
strken 1 days ago [-]
It's possible and often desirable to calculate the estimated impact of externalities, positive and negative. Human lives are (in)famously given a monetary value by environmental agencies to enable this calculation.
I think the more likely explanation is that this is a pilot project by a clean energy startup, it intentionally operates at a loss because it's RnD rather than mature tech, everyone involved is okay with this, and the company doesn't want to release its modelling of future ROI because that's valuable proprietary data and giving it away to clients and competitors is dumb.
kragen 1 days ago [-]
> Majority of people and countries in the world do not deem ROI to be the sole or even primary driver for investment
I think this is a little unfair. If it were true, it would be the reason for wealth inequality: you're saying that the majority of people and countries are so financially irresponsible that they consume any resources they get without investing any. But in fact everyone I have observed closely, in every socioeconomic group, tries to optimize ROI. Most of them aren't very good at it, but they do try.
On the other hand, people who expect a 10% risk-free return are just going to get scammed. There are 10% opportunities in most people's lives—weatherstripping, coupon clipping, bulk food buying, etc.—but you can run out pretty quickly.
ta1243 1 days ago [-]
> There are 10% opportunities in most people's lives
Average S&P total return (reinvesting dividends) is well over 10% over any appreciable timeframe (say 30 years), even during really low times (say buying at the peaks in 1999 or 1972)
zahlman 1 days ago [-]
The long term average is a bit over 10%, but there are definitely 30-year periods that have fared worse than that.
ta1243 9 hours ago [-]
Which specific 30 year period?
kragen 1 days ago [-]
That's cherry-picking a single country's stock market with the benefit of hindsight, though. Over the time frame you're talking about, that country became the world's sole superpower and also underwent an unprecedented redistribution of income from workers to investors. Neither of those things can happen again in the US, they aren't very likely to happen anywhere else, and if you had invested at those points in time, you wouldn't have known they were going to happen. If investors had known they were going to happen, they would have bid the price up higher earlier on.
And of course it isn't a risk-free return.
Consider what happened to investors in Germany, Hungary, or Romania in the 01930s, or South Vietnam in the 01960s, or Afghanistan in the 01970s, or Iraq in the 01990s.
You might think this is irrelevant because you don't live in 01930s Germany or 01970s Afghanistan or 01990s Iraq; you live in the USA.
But, if you live in the USA, you don't live in the USA of the 01970s or the 01930s. You live in the USA of 02025. In 02025, the country most like 01930s USA or 01970s USA is China, which is obvious if you read books from the USA from those periods. The USA in 02025 is the country that's been trying and failing to build high-speed rail for 60 years, since Japan got it working, and just elected a xenophobic demagogue who praises dictatorship; it's much more like 01980s Russia or 01930s Italy.
Warren Buffett said that, in the long run, you can't expect the stock market to return more than the long-run economic growth rate, which you can't expect to consistently be more than 3%. I don't understand the logic behind either of these propositions, but I suspect Buffett knows more about market returns than I do.
— ⁂ —
By contrast, if you can get an 0.8% discount on the potatoes your family eats by bulk-buying enough potatoes for the next three months, that's about a 10% annual return on investment, and the risk is pretty low—and almost entirely under your control. And, in practice, you can often get a much bigger discount than that, especially if you assign some cost to the errand of going potato shopping. You just have to make sure you have proper potato storage and that you don't have a sudden dropoff in family potato consumption.
How do I figure that ROI? Well, the amount of extra money you have tied up in potatoes oscillates between two months' worth and zero, with an average of one month of potatoes. But your expenditures on potatoes are 0.8% less each month, which is your earnings from that investment. Every year, you save 10% of a month of potatoes: 10% of your investment. Tax-free.
If you learn to calculate ROIs and reorganize your household expenses on the basis of ROIs, whatever income you have will go dramatically further than it would for someone who hasn't done that.
anon191928 1 days ago [-]
they print more than %10 each year, LMAO. people are not smart. remember
testdelacc1 1 days ago [-]
I really like this comment. Concisely explains the points of view on an investment like this. There’s not much more to add.
This is why I open the comments before the link.
csomar 1 days ago [-]
The battery (am assuming it's just sand and metal) should be very cheap compared to Lithium especially in the places where you generated solar energy (they are hot and have a lot of sand).
The problem is: is it profitable to even store energy there? There is no mention beyond "In operation, the sand battery has demonstrated a round trip efficiency of 90 percent.". That doesn't mean much if you do not compare it to Lithium and you don't give me a breakdown of the costs.
The other thing: Size. Is that big thing enough to store energy for a city? a neighborhood? A building? A house?
If it's enough just for a house, then I have trouble seeing this scale.
kragen 1 days ago [-]
1 MW is enough to heat somewhere between 100 and 2000 houses, depending on other factors like insulation, climate, and house size.
Sharlin 1 days ago [-]
It's right in the title. 1 MW/100 MWh.
rsynnott 1 days ago [-]
If your house is consuming 100MWh in heating on any reasonable timescale, you, ah, have problems :)
yencabulator 1 days ago [-]
But at least the problems will be short lived! Should reach self-ignition pretty quickly with that, even in the middle of Finnish winter.
skrebbel 1 days ago [-]
Does anyone understand why people do this? I mean, really why? It's similar to eg climate protestors quoting all kinds of outrageously incorrect statistics as fact, or saying that $TECH can supply "4% of all households" with electricity, fully knowing that households only consume a tiny % of total energy, and so on.
I simply don't get it! The political landscape across the west is that there's swaths of people who've simply stopped believing mainstream media when they're reporting things, and somehow our reaction is to just lie even more? Try to out-lie camp Trump? I mean I don't think it's even possible to lie more than Trump so wouldn't the honest, nuanced truth be a a much better antidote than global left's current strategy of "also lie, but a bit less"?
I simply don't understand where it comes from. Like in what bizarro world is this shit a smart strategy? Is it all just incompetence?
zahlman 1 days ago [-]
It has nothing to do with political partisanship (except to the extent that false-flagging happens or that powerful individuals have bad ideas about how to propagandize for their cause). Most people are just terrible at critical thinking, and most of the interesting claims (especially statistical ones) are simply not verifiable by random individuals.
Plenty of leftists have their own reasons to distrust media. But scarcely anyone imagines reasons why someone else would lose trust. Not that they could do anything about it anyway.
The "global left" is not a real thing. I mean, of course you can draw lines around groups any way you like, but this one doesn't offer meaningful insight.
skrebbel 1 days ago [-]
Appreciate your response. I think I agree with all of it, great points.
aaron695 1 days ago [-]
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flanked-evergl 1 days ago [-]
[flagged]
kitd 2 days ago [-]
I like these technologies. They may not be as energy efficient as using more exotic materials, but what they do use is simple, cheap and often sourced locally. Such economic factors are often as important to the ROI as the purely scientific ones.
pilif 2 days ago [-]
> They may not be as energy efficient as using more exotic materials
yes and given that the energy you put in is practically free, it doesn't matter if it's not as efficient.
looofooo0 1 days ago [-]
I think with enough renewable in the grid, there will always be times when the costs are 0 or negative, so you can help stabilize the grid by consuming.
yurishimo 1 days ago [-]
Are there downsides to "just" sending all of the extra energy to ground? I've often wondered why overpowering the grid has been talked about as this huge unsolvable problem.
I understand it's wasteful, of course, but waste in a ecosystem of vast abundance seems like a feature, not a bug.
ZeroGravitas 1 days ago [-]
Solar and wind can be trivially turned down when not required. They are much, much better at it than traditional sources.
So easy that one of the actual problems we face is that by default grids will generally prefer to turn off the clean renewables and let the difficult to modulate fossil fuels run.
This is why negative prices are a good thing, financially incentivizing fossil producers to plan for flexibility and fining them when they fail to do so.
grues-dinner 1 days ago [-]
> but waste in a ecosystem of vast abundance seems like a feature, not a bug.
The problem is that it's not a ecosystem of vast abundance, just occasional abundance. Literally no-one in the world right now is sitting on a constant supply of TWs of excess electrical power and saying "golly gee what are we going to do with all this". Perhaps France got closest in history and their prices still aren't "too cheap to meter".
You can "waste" the power (either by actually "burning" it to heat and dumping it, or just disconnecting the solar panels), but then you'll be short of power later and need to fall back on something expensive or with high externalities. It's also bad in terms of the capex for the solar panels (assuming solar), as you can't use your expensive plant as much as you want. If you can you'd rather use "$10" of energy that you can't sell to store and sell it later, even as heat, at any price than just lose it all.
Even if you massively, massively overbuilt solar and wind so that you were in a "vast abundance" scenario on average, you still have to store some of it for night and/or winter.
lupusreal 1 days ago [-]
As I understand it, you need to limit the current flow to ground to not create a fault that burns out the whole setup. The most practical way to do that is with a bank of resistors. At that point, the resistors are doing the work and you're just using the ground as a return path, which isn't necessary.
kragen 1 days ago [-]
To clarify, the current flow never goes to ground; it goes back to where it started, which is why we call it a "circuit". When you do it without routing it through a load like a bank of resistors, it's called a "short circuit". Electromechanical generators will generally tend to catch on fire if you short-circuit them.
Solar panels have no problem with being short circuited; the amount of heat they produce in that state is the same as any other black object in sunlight.
Windmills are like any other electromechanical generator in this sense. You have to stop them with a brake. But that is totally a thing you can do, and quickly, and every mainstream windmill does it regularly (if only to handle overspeed winds safely), although, when this system fails, you get spectacular viral video content.
In the usual case where it works, though, you don't need a load bank either.
Load banks come into play when conventional inflexible baseload generators can't ramp down fast enough or when perverse market incentives pay renewables operators to pump power into the grid when it's not being demanded.
grues-dinner 1 days ago [-]
> Solar panels have no problem with being short circuited; the amount of heat they produce in that state is the same as any other black object in sunlight.
Internet akchually: a small amount of the heat will be dropped in the wiring that forms the short circuit rather than in the internal resistance. So the panel will be slightly cooler than you'd expect for an object of that colour even in short circuit. They're the same temperature in open circuit, though. When operating normally, they can be quite a lot cooler and in fact you can detect non-functional panels by looking for hot ones with thermal cameras.
kragen 1 days ago [-]
Yes, agreed, especially if you're "short-circuiting" them with MOSFETs or TRIACs or something instead of relays.
I did know that normally-operating panels were significantly cooler (23% efficiency means 23% less heat than a regular black body) but I had no idea that people used this feature to detect broken panels with thermal cameras. I'd only seen people forward-biasing the panels from an external source to stimulate NIR light emission and using NIR cameras.
You'd think water would be easier to exchange heat with since it can slosh around the heat exchanger elements in the tank more easily. Which should translate to lower costs since you don't need as many exchanger structures in the medium.
Any guesses for the motivation in using sand? Maybe it's that you can heat it over 100C? But then big heat differences to the environment mean high conductive/radiation losses or heavier insulation requirements.
grues-dinner 2 days ago [-]
Sand also mostly stays where you put it. While obviously water can be put in tanks easily enough, there's still more maintenance and inspection required and a gigantic watertight tank that will last n decades is substantially more expensive then a steel sand box. Plus it only goes to 100C unless you pressurise it and that really gets hard. Unplanned release of that much water at 100C is also extremely dangerous. Whereas even 500C sand will mostly just sit there. Plus the usual corrosion and scaling effects water systems love to develop at high temperatures.
Insulation isn't such an issue with sand because sand itself is fairly good insulator and obviously doesn't convect. 1m of sand is about the same as 10cm of air. 500C through 1m of sand if roughly 125W/m². Which isn't nothing but it's also 7m from the center to the edge, and the efficiencies only improve the bigger you make the silo.
Presumably they have a double-skin gap and other external insulation too. As the Icelandic hot water pipe systems show, which drop only a few degrees C over hundreds of kilometres of pipe (and thus a gigantic surface area to volume ratio), you can have really quite good insulation if you have space to make it thick.
The hassle of handling hot water is also presumably why they use hot air rather than water as a working fluid for heating the sand in the first place. The worst case if you spring a leak in a heat-transfer tube inside the tank is that a bit of air escapes. Leaking super-heated high-pressure water or steam into the (unpressurised) tank would be a much larger problem, and unloading up to 2000 tonnes of hot, damp, sand to plug it would be operationally very annoying if nothing else.
tarvaina 2 days ago [-]
The Wikipedia article says:
"Rock, sand and concrete has a heat capacity about one third of water's. On the other hand, concrete can be heated to much higher temperatures (1200 °C) by for example electrical heating and therefore has a much higher overall volumetric capacity."
and
"Polar Night Energy installed a thermal battery in Finland that stores heat in a mass of sand. It was expected to reduce carbon emissions from the local heating network by as much as 70%. It is about 42 ft (13 m) tall and 50 ft (15 m) wide. It can store 100 MWh, with a round trip efficiency of 90%. Temperatures reach 1,112 ºF (600 ºC). The heat transfer medium is air, which can reach temperatures of 752 ºF (400 ºC) – can produce steam for industrial processes, or it can supply district heating using a heat exchanger."
internet_points 2 days ago [-]
I learnt some new concepts here, specific heat capacity vs overall volumetric, things I kind of understood intuitively, but now much clearer:
If I add some fixed amount heat to some fixed volume of water, it might rise by 1℃, while the same volume of concrete rises by 3℃. And by the same logic, on release, that fixed volume of water dropping by 1℃ releases 3x as much heat as when that fixed volume of concrete drops by 1℃.
So if you can max heat water to 100℃, and max heat concrete to 1200℃, and on release you let it go to 10℃ (probably the range is less in practice), then the water can drop 90℃ and the concrete 1190℃, so even if the water releases 3x the amount of heat per ℃, the water just releases 270 (per volume) while the concrete releases 1190 (per volume)
privatelypublic 1 days ago [-]
Also to add some practicals: you can drive a steam turbine with the concrete temps, but not with the water.
Also, looking at how hot water could theoretically get (decomposes between 2200-3300C), it looks like 1200C is an interesting limit. Above that and you get safety(practical) and cost issues with every material I could find (common salts, pure elements).
Sand just makes sense! Though, don't ever youtube sand battery.
stavros 1 days ago [-]
Why not YouTube sand battery? I did it, and nothing much happened.
privatelypublic 1 days ago [-]
Previously it was a bunch of overunity nutjobs.
stavros 1 days ago [-]
Ahh right, I did see some preppers there, to be fair.
internet_points 1 days ago [-]
> don't ever youtube sand battery
Huh? I just get stuff related to this article?
fulafel 2 days ago [-]
The higher temperature output is a good point, you can't get 400C output for industrial processes from a 100C water based heat battery.
dinkblam 1 days ago [-]
a Blast furnace needs closer to 2000° than 400°
in any case, how would you transport high temperatures to the industrial sites? water boils at 100° and few liquids boil above 400°. most liquids will be impractical due to cost or safety (combustibility, toxicity…).
happosai 1 days ago [-]
Of course you can't do blast furnace with a sand battery. But there is still a sizable market for industrial heat in between 100c <> 400c.
rsynnott 1 days ago [-]
Pump water through, producing steam to drive a turbine, use turbine to generate electricity, use electricity for industrial process.
Now, in practice you _probably_ don't want to do this, because, in this case, you have district heating demand, which is a far more efficient use of the power.
fulafel 1 days ago [-]
Steam?
Tuna-Fish 1 days ago [-]
> But then big heat differences to the environment mean high conductive/radiation losses or heavier insulation requirements.
Square cube scaling means that insulation becomes trivial in total costs as you scale the installation up. Something that's convenient for a single household would probably be too hard to insulate, but this thing holds 2000t of sand.
decimalenough 2 days ago [-]
The article mentions that they heat the sand to 500°C, which is not possible with water (well, at least not without turning into steam along the way).
Cthulhu_ 2 days ago [-]
To be pedantic, yes you can but you'd need to pressurize it to uuhh... According to this calculator [0], you can get water to 370 degrees C if the pressure is 207 atmospheres, which is about the pressure of the ocean two kilometers deep.
Interestingly that's also about the pressure of gas in scuba tanks. Can't imagine how much energy to pressurize water to that
trhway 1 days ago [-]
Due to incompressibility of liquids, pressurizing a liquid is very cheap energy-wise - orders of magnitude cheaper than pressurizing a gas. The issue is that pressurized liquid also requires correspondingly strong and expensive vessels and pipes.
sfn42 1 days ago [-]
You don't need to pressurize it. You just put it in a tank and apply heat, the water evaporates and creates pressure. Like a pressure cooker.
nick49488171 2 days ago [-]
How many kiloton of TNT equivalent?
grues-dinner 1 days ago [-]
Well, if you say the energy stored is the 100MWh from the headline figure, and say you can arrange release every joule of all at once by flashing high-pressure water to steam at 1 atm that's about 0.1kT.
District heating tends to operate at 50-70C at lowest. But more often up to 115C and in some case even 180C.
Even the lower range doesn't leave much delta in best case of boiling water. So you would need some type of heat pumps instead much simpler heat exchangers. So that is also one cost optimization.
And of course it's still a win if you can heat the return water half of the way to spec with the battery, it's not necessary to have the battery heat it all the way to the plant outgoing temp.
District heating systems have been happily using ~90C water based heat batteries for a long time.
Ekaros 1 days ago [-]
Other limitation that I know is that for tap water minimum is 55C. So the last building in loop should get at least that much. So 40C is only acceptable back at power plant.
In the end it comes to balance with cost, simplicity, capacity and such. Heat pumps do allow extracting heat from colder storage medium. But on other hand electric heating elements and heat exchangers are very much simpler and cheaper.
fulafel 17 hours ago [-]
In the good systems there's two pipes, return gets its own (like eg the earlier linked PDF describes), so it's fine for buildings to output cooler water to the return pipe.
But yes heat pumps are used in some parts as well in DH.
isoprophlex 2 days ago [-]
For this specific use case, you need to heat to far above the boiling point of water to retain some thermal efficiency. Sand/rock is better suited for storing the thermal energy at ~500 celcius.
vintermann 2 days ago [-]
I wonder if there are any chemical effects from heating the sand to 500 degrees Celsius. Finely roasted sand.
If it were pure silica sand, you could presumably get even hotter before anything changes chemically, but at the that point you start having materials issues with metal parts of the system: 500C is about the limit for ordinary steels to lose strength (and many are less than that - heat effects can often start at 300C).
isoprophlex 1 days ago [-]
Interesting, thanks for pointing that out, I didnt catch that they're not using actual sand.
isoprophlex 2 days ago [-]
None, really. Pure, fine sand being mostly silicon dioxide, it melts at ~2000 and boils at ~3000 C, still without decomposing or reacting. It is really extremely chemically stable.
That said in practice, at scale... before filling up your storage tank you'd probably need to pre-heat it once to remove all moisture and volatile gunk adsorbed onto the sand.
LtdJorge 2 days ago [-]
It's as inert as it gets
chii 2 days ago [-]
perhaps sand is easier to heat to higher temps, and also it's less thermally conductive, so you'd lose less heat in storage for the same sized container.
d--b 2 days ago [-]
They probably use the trick where they blow air in the sand to give it "liquid" properties where they need the sand to flow.
Several cities in Finland have water based thermal batteries already, connected to local district heating networks. They have been previously used to store energy from existing combined heat and power plants, but now that wind power build up has created a lot of excess cheap power period, have been modified to include electric boilers.
nabla9 1 days ago [-]
Helsinki has advanced integrated district heating and cooling. Over 300 MW of heat pumps by 2025.
Collecting heat from wast water is free energy. When you defecate, wash clothes or dishes, or take shower there is warm water and solids going down the pipes. That heat can be used. In the summer stored cold sea water can provide district cooling.
Really interested in seeing how it fares in reality, almost sounds too good to be true.
jnsaff2 2 days ago [-]
Why too good to be true?
There are significant trade-offs with this technology.
It's storing heat, so if you need electricity then you eat a lot of efficiency. I think Vernon said ~45% round trip efficiency. Batteries are 90%+.
The storage is at a high temperature (500-600C) which means that you can't use heat-pumps to produce the heat to be stored. This means that you miss out on ~400% energy gains possible from converting electricity to heat.
So the efficiency is pretty low.
That said, solar PV is really cheap and moving large amounts of earth into a pile is also a very much solved problem so in some cases, notably higher latitudes which have very long days and low heat/electricity demand in the summer and the opposite in the winter, it could still be a very good solution.
Sharlin 1 days ago [-]
The whole point is that the thermal energy is used directly, via district heating. These are not meant to store energy for electricity production (though they could do that if really needed – emergency power for various facilities? Maybe not worth it compared to diesel.)
Heat from existing thermal power plants can be stored directly and later distributed with no conversion loss; excess electricity from renewables can be turned to heat at 100% efficiency, but the problem is that peak heat demand and peak electricity supply do not typically coincide. Heat batteries are meant to solve that problem.
jnsaff2 1 days ago [-]
The link in the OP comment is however talking about electricity generation (not excluding heat use tho) and energy being stored from excess PV.
Sharlin 1 days ago [-]
Ah, sorry, missed the context.
HPsquared 1 days ago [-]
Yeah the efficiency is much less than 40% if you compare to heat pumps. It'll be something like 15% compared to those.
It's not clear to me why you would hold 100 hours of energy, assuming you discharge at maximum power. If you want to store energy from summer to winter, then 4 days of energy is nothing. Even if your average discharge is only 30% of the maximum power, you still get only 2 weeks of energy. And if the use case is day to night, then 8 hours of storage is enough. Maybe the idea is that the houses in Finland are so well insulated that you need heating only in cases of extreme cold, and only during the night, 100 hours will do the job?
etrautmann 1 days ago [-]
4 days is often cited as a useful target for buffering power to backstop intermittent generation from renewable sources. You're never going to store a full winter's worth of power, and might want to be able to ride out a few days of weather.
jonespen 2 days ago [-]
So, a gigantic sauna heater? Very on brand Tommi and Markku!
pintxo 2 days ago [-]
Really like the idea, but my house alone has roughly 16 MWh/a heat consumption. Of which half gets consumed November through January.
So this system could supply 12 houses? Shows the importance of proper insulation, which is still on our todo list.
diggan 1 days ago [-]
Sweden seems to have some of the highest "Electricity consumption per dwelling" (https://www.odyssee-mure.eu/publications/efficiency-by-secto...) in Europe, and sits at 10 MWh, which makes sense, it's a very cold country but with very well isolated houses in general :)
It sounds to me like you're likely an outlier here, for curiosities sake, where do you live?
pintxo 1 days ago [-]
Germany, and these are numbers from our gas heater. But the house is almost 50 years old and not insulated to current standards (yet).
We got a heatpump this year, going to be interesting to see how this changes things.
lysace 1 days ago [-]
16 MWh of electricity/year isn’t really an outlier for an electrically heated (via efficient heat pumps) house in Sweden either.
Your number above probably includes apartments and houses heated using district heating, e.g. from incinerating forest industry waste products.
1 days ago [-]
1 days ago [-]
Fwirt 2 days ago [-]
Interestingly this looks like the same principle as a rocket mass heater or masonry heater, but on a larger scale and powered by renewable energy. They say the system can retain heat for weeks whereas the smaller thermal battery in a masonry heater is exhausted in a matter of hours. I wonder if this is a function of size or if the tank is heavily insulated? It would be interesting if this same system could work at smaller scales for off-grid heating by harnessing excess solar capacity. There’s a lot of waste involved in going from solar to battery vs directly to thermal energy, as long as it doesn’t bleed off before you need to use it.
davedx 1 days ago [-]
Good idea but why is it being measured in MW/MWh when it’s not an electrical battery? I know they can be converted but maybe it should be measured in actual thermal units like Btu?
flowerthoughts 1 days ago [-]
W and J are the SI units for power and energy. Those units make the most sense to use in Europe, regardless of the type of energy.
Wh is an abomination that has come about because professionals think consumer brains would expose if they ever saw the unit watt-seconds (J). No consumer had any preconceived notion of either Wh or J, so had we used J from the start, it wouldn't have been a problem...
(Yes, same with Ah vs C, though the battery pros also shot themselves in the foot by starting to use C (electrical charge) to mean "the capacity of this battery" when talking about charge rate, a.k.a. current.)
grues-dinner 1 days ago [-]
I dunno, 1kWh seems quite natural as a unit of building-scale energy usage when you know a kettle or space heater is about 3kW. We think about energy usage much more in terms of kW and hours than in watts and seconds. And even in small devices like an LED bulb, 5W is more obviously 0.005kW than, say, 2 hours is 7200 seconds.
And in this context it's much more obvious that it can notionally deliver energy at a peak rate of about 1% capacity per hour. If you said 1MW/360GJ, I don't think that would be nearly as clear.
Same for batteries, which started with car batteries/deep cycle batteries, rather than AA batteries, which usual don't even say, and phones. A battery that provides 1 amp (at 12V, but that's already given in a system) for 50 hours. Makes immediate practical sense, especially when equipment is often labelled in current draw and you can measure amps with an ammeter. 2.16MJ far less so.
flowerthoughts 1 hours ago [-]
This still falls under the "but we're used to it" argument. That notion that it feels natural, I argue, is a result of you having seen both W and Wh in enough contexts that you start building intuition for them. Had we had W and J, you would have been able to build the same intuition.
> If you said 1MW/360GJ, I don't think that would be nearly as clear.
Wouldn't have been using the hour as the mental reference. As you say, it's impractical. We would have probably rounded the 86,400 seconds in a day to 100,000 and used that as the reference for comparisons. There's nothing noteworthy about the hour in this context.
> A battery that provides 1 amp (at 12V, but that's already given in a system) for 50 hours. Makes immediate practical sense, especially when equipment is often labelled in current draw and you can measure amps with an ammeter. 2.16MJ far less so.
I argued Ah could have used the SI base unit C, not that we'd use J. Whether you count As or Ah is still just a matter of building intuition.
Gud 1 days ago [-]
Absolutely agree.
rsynnott 1 days ago [-]
Watts and watt-hours are generally used internationally for heating; the Btu is largely a historical oddity in most places outside the US.
Also it is a mess, as is traditional for US customary units:
> A Btu was originally defined as the amount of heat required to raise the temperature of one pound of liquid water by one degree Fahrenheit at a constant pressure of one atmospheric unit. There are several different definitions of the Btu that differ slightly.
(Best one is still the fluid oz, tho. A US customary fluid oz is about 29.6ml, a US food labelling fluid oz is exactly 30ml.)
grues-dinner 1 days ago [-]
Finland probably doesn't use US customary units like BTU (British Thermal Unit).
In fact even Britain doesn't often use such units - even gas boilers, heat pumps and some AC are specced in kW. You do see BTU (the /hr is often missing) sometimes on AC marketing. My theory is 18000 sounds big and impressive and 5.2kW sounds "meh". We definitely don't talk about "tons", and we buy gas in cubic metres or "units" (which is just kWh)
Cthulhu_ 2 days ago [-]
So why a surface sand silo instead of going down and using the soil/clay/bedrock/whatever is there? Ease of installation and maintenance?
shellfishgene 1 days ago [-]
They heat it by blowing hot air through it, that needs loose, evenly sized material.
whimsicalism 2 days ago [-]
presumably you need the insulation from the air, otherwise it would just sort of dissipate through the ground
IshKebab 1 days ago [-]
Open air is not a good insulator; that's why we wear coats! In contrast the ground is actually a pretty good insulator - that's why the London underground is so hot; the heat is all stuck in the ground.
It'll just be cheaper to build it on the ground than to dig a big hole and then build it in the hole.
crote 1 days ago [-]
Rather the opposite, actually.
Air is a pretty good insulator, we wear coats to prevent air from moving around. How do most coats keep you warm? Trapped air.
The London underground is hot because the ground is an okay-ish heat conductor: it carries heat away well enough that for a century it essentially acted as an unlimited heat sink, so during its initial construction they never bothered to build proper ventilation. In fact, it was advertised as the perfect place to stay cool during the summer! But this has gone on for long enough that a significant area around the tubes has gradually warmed up from 14C to 19C-26C, and the smaller temperature gradient from tube-to-ground means less heat is carried away, which means the tubes now stay hotter.
Had ground been a great insulator the Victorians would've had to install a proper ventilation system from the start, and they wouldn't been having this issue right now. On the other hand, had ground been a great conductor this issue would've taken far longer to pop up as the heat would've spread through the ground faster.
IshKebab 1 days ago [-]
> How do most coats keep you warm? Trapped air.
That is why I very specifically said open air.
whimsicalism 1 days ago [-]
i don’t really know what to say, i wasn’t suggesting that the ground is very conductive of heat - but it is certainly much more conductive than the air is. just search.
the reason we wear coats has more to do with convection than the heat conduction of air
IshKebab 1 days ago [-]
I said open air.
whimsicalism 1 days ago [-]
convection is orthogonal to conduction/insulation properties and this sand pit is in a silo. i don’t understand how your point is related to the notion that heat would diffuse if we just were heating up the ground
Findecanor 2 days ago [-]
I'm not a building engineer, but my impression is that it does not matter as much as we might think.
A housing complex near mine got a massive tank like this installed thirty years ago, and I think they put it underground to be able to build a house on top.
phtrivier 1 days ago [-]
It seems to depend on having a network to distribute heat, which is something that you have to take into account... basically when you create your town ?
Or is there a way to "retrofit" district heating into houses with their own gas boiler or heat pump ?
jpalomaki 1 days ago [-]
Over half of Finland’s population lives in buildings connected to district heating.
Ekaros 1 days ago [-]
Finland traditionally mostly used oil. If you have traditional water circulating radiators or underfloor water circuits it is pretty easy retrofit, just need to swap boiler with heat exchanger. Still, in many cases cost of infra is pretty high so heat pumps are often better options.
lupusreal 1 days ago [-]
They already have district heating.
bjoli 1 days ago [-]
90% roundtrip efficiency is pretty darn cool. I am not an engineer, but is it the high temperature difference that makes that possible?
IshKebab 1 days ago [-]
I think they're talking about thermal efficiency (since this is a thermal battery, not an electrical battery). 90% of the heat they put in, they get out again. Probably all you need is good insulation.
smokel 1 days ago [-]
That's only in heat transfer, that does not include generating electricity from it.
petesergeant 2 days ago [-]
I live in a desert where we have district cooling (and no shortage of sand or solar power), instead of district heating. Wonder if they can pull off the same trick.
phh 2 days ago [-]
Well you can't really do -600C sand (or anything), so the benefits of sand VS water largely diminished. "just" freezing water already gives you around 300C equivalent of sand (if my napkin is correct).
Also the point of this plant is to exploit the counter-correlation of cheap electricity and cold. Usually there is a bigger correlation between cheap electricity and heat.
Gravityloss 1 days ago [-]
You can use heat to create cool by using absorption materials. It's of course way more complicated than with heat. But anyway with that, stored heat in sand could be used to create district cooling.
dzhiurgis 2 days ago [-]
> you can't really do -600C sand (or anything)
You can if you stagger AC/HP or even peltier elements.
myrmidon 1 days ago [-]
You misunderstood-- temperature is physically limited to -273°C, this is not an engineering problem. You have a smaller usable temperature range in a "cold storage" than with heat from fundamental physics alone.
dzhiurgis 1 days ago [-]
Damn you got me there!
pintxo 2 days ago [-]
Cooling needs tend to correlate with the availability of solar energy. While heating especially far north does not so much.
Cthulhu_ 2 days ago [-]
In theory, yeah, cooling the sand would work, and it wouldn't freeze / expand. You'd need to use a coolant that doesn't freeze though, and of course keep any liquid out of it.
Havoc 2 days ago [-]
Interesting capacity vs discharge ratio. Way slower than battery but presumably sand scales well
haspok 1 days ago [-]
This is not a battery, this is thermal storage. No electricity is stored or generated. (Unlike liquid-metal batteries, for example, which are actual battery storage.)
1 days ago [-]
alkonaut 1 days ago [-]
No one is claiming it is storing electricity. I think people who use imperial (BTU) units for heat but SI units for electric power some times get confused by what power really is and what a battery is.
Something that stores _energy_ is a battery. Not necessarily electric energy. You can absolutely have a battery with mechanical energy (wound up springs), a battery with kinetic energy (a weight in a shaft) a battery with nuclear energy (Thermal reactor in a satellite), a battery with thermal energy (silo full of very hot sand) or a battery with chemical energy such as a Li-ion battery.
This stores 100 MWh heat energy, so it is a battery.
From wikipedia:
> Energy storage is the capture of energy produced at one time for use at a later time to reduce imbalances between energy demand and energy production. A device that stores energy is generally called an accumulator or battery.
slumpvaldperson 2 days ago [-]
Very interesting. Did anyone find a ROI calculation?
theshrike79 1 days ago [-]
It's a prototype, so not really relevant.
flanked-evergl 1 days ago [-]
If they did, and it indicated that it's not just a money pit they would have shared it, so doubtful. As with most things in Europe it was likely done on the basis of a virtue signaling assessment alone. Europe's motto is going to keep saying "we have the resources" until it rapidly runs out of resources.
Norway's sovereign wealth fund will likely be completely gone in 20 years and will leave large swathes of the population without a pension because the Norwegian government works on the philosophy of "it's going to be okay, we have infinite money", already it's showing cracks as the only thing they actually have the money for is to make inflation skyrocket.
dzhiurgis 2 days ago [-]
Wonder if one could use staggered heatpumps here - in summer there's quite a bit of heat out there (some of which needs to be removed) so you could get 3-6x more bang for your buck.
grues-dinner 1 days ago [-]
Staggering heatpumps doesn't help except on a practical level, like how climbing a staircase in big or small steps is the same. The only thing that matters to overall efficiency limits is the temperature delta.
The coefficient of performance for a heat pump from with cold/hot of 10C/40C is about 10 - this is ballpark where a domestic heating heat pump sits - this is why a heat pump house needs to be well-insulated to work - the heating loop isn't actually hot-hot like with a boiler). From 10C to 500C, it's 1.5. That's 9/0.5 = 18 times less advantage.
At any delta, you can eke out a bit of advantage as COP is always over one, but at some point overheads in the system start to overwhelm your theoretical advantage and you might as well keep it simple and use a cheap and reliable resistor to heat things for dead-cert COP of 1.
You could use a heat pump with a higher COP if you have a really gigantic tank that you only heat to about 40-50C, but obviously the thermal transfer from that is pretty bad and getting it where it needs to go while still being hot enough to be useful is a problem.
anovikov 1 days ago [-]
Problem here is that if heating was done with electricity itself, it could have like 300% effective efficiency because of using heat pump, but a heat pump can't be used for 500C temperatures, it must be resistive heating. So even if no thermal loss occurs at all, we end up getting a lot, lot less heat than we could do otherwise. It's a lot better to use normal li-ion instead, surely 100 MWh means 500-ton battery and with longer life chemistries and thermal management, probably a 1000-ton one...
shellfishgene 1 days ago [-]
In the end it may still make financial sense, the price for electricity often goes down to near zero or even below.
dguest 1 days ago [-]
Finland is still 25% oil for electric generation [1] (and almost 40% fossil fuel). That means a lot of the electricity to heat the sand still comes from oil. It makes me wonder if this is more efficient than just using oil heating. Or some hybrid approach that uses oil to heat the sand.
Of course there are other benefits: it's still a good way to level electric generation, which is important for e.g. nuclear plants and wind power.
> Finland is still 25% oil for electric generation [1] (and almost 40% fossil fuel). That means a lot of the electricity to heat the sand still comes from oil.
This is not a valid conclusion. Battery projects like this are gonna charge/heat up when the electricity price is low, electricity price is low when supply/demand ratio is high and this often happens when renewable electricity is most available and makes up a disproportionate share of the electricity mix.
Edit: Your graph is not what you say it is, this shows primary energy (i.e. includes fuel/heating/...), not "electric generation". Electricity in Finland is mostly nuclear, wind, hydro and certainly not "40% fossil fuel".
dguest 1 days ago [-]
I think the primary energy does include electric generation, but you're right, I posted the wrong chart. The correct one is here:
and it backs up your point. Sorry to any Fins I might have offended with my lazy post.
nabla9 1 days ago [-]
95% of Finnish electricity is clean: nuclear, wind, hydro, renewable biomass. Oil 0.3%, coal 1.5%, net import of electricity 3.8% (most of it clean also).
Older private homes still use oil for heating. All new use electric, heat pumps, or geothermal heat pumps.
happosai 1 days ago [-]
It is amazing how internet commenters can see some data that appears insane and build an entire post around it. Instead of like, consider, that they have completely misunderstood the data. Confirmation bias much.
Eg that graph is not Finnish electricity usage. It's ALL energy, including cars and planes that still use oil...
dguest 1 days ago [-]
Yeah I was wrong and completely misunderstood the data. I'd edit the post if I could but the timeout for that happened while I was editing. Not sure what confirmation bias I might have: I figured the Fins did their math correctly and was confused about why they were using electric heat.
Anyway, to explain my mistake, the data did not look "insane" to me, it's about right for most countries, and even if it had been correct for Finland the method they described might be favorable (some electric sources need leveling and using extra energy for heat is better than dumping it). Honest mistake, I'm not here with some agenda, and I learned of it by posting.
Anwyay, thanks for the correction! It's amazing (in a good way) that internet communicators can see something that looks plausible, but is wrong, and correct it! You've restored (some of) my faith in the internet.
happosai 1 days ago [-]
Cheers! For the record 25% of electricity from oil is "insane" for any place that isn't a small island or failing 3rd world country.
dguest 1 days ago [-]
Yeah thanks for pointing this out: I'd been confusing energy consumption with electricity generation for a while. Turns out that even countries that I thought were using oil for electricity (e.g. the US) were just using it for transportation / petrochemical.
I guess oil is too valuable to just burn.
mzl 1 days ago [-]
The point of these types of systems is that you can store energy when it is cheap to do so (there is an abundance of wind and/or solar energy) and use it later.
Hikikomori 1 days ago [-]
Most of that is not for generating electricity as it includes transport and heat. Direct heating of homes traditionally used oil, wood and pellets, same as other Nordic countries. This is slowly being replaced with heat pumps that mainly use electricity from wind, water, nuclear or solar (not so much solar in Finland though).
Rendered at 20:40:57 GMT+0000 (Coordinated Universal Time) with Vercel.
> A comment on the YouTube video below complained, “Not a word about return on investment in the presentation. That means it’ll never pay off” MAGAlomaniacs are everywhere these days.
Given the supposed 50+ year lifespan of such a battery, I find it hard to believe it doesn't turn a profit at some point. And I understand that debunking low-effort accusations is asymmetric warfare. But why cite a random YouTube comment if you have no intention of addressing its claims? A more charitable interpretation is that it's meant to ragebait the readers. But to me, it seems like trying to make people feel ashamed for having doubts, by making a public example of a skeptic.
So I think ROI is a first-order consideration.
And I don't think it's accurate to say, "this is a first-time installation of a new technology that hasn’t scaled". People have been using thermal energy storage for household heating for literally millions of years. https://en.wikipedia.org/wiki/Thermal_mass https://en.wikipedia.org/wiki/Thermal_energy_storage https://en.wikipedia.org/wiki/Storage_heater https://en.wikipedia.org/wiki/Ondol#Advantages_and_disadvant... https://en.wikipedia.org/wiki/Seasonal_thermal_energy_storag... https://en.wikipedia.org/wiki/Masonry_heater https://en.wikipedia.org/wiki/Ground_source_heat_pump https://en.wikipedia.org/wiki/Trombe_wall https://en.wikipedia.org/wiki/Feolite https://en.wikipedia.org/wiki/Drake_Landing_Solar_Community https://en.wikipedia.org/wiki/Kang_bed-stove https://en.wikipedia.org/wiki/Earthship#Thermal_performance https://en.wikipedia.org/wiki/Rocket_mass_heater https://www.helen.fi/en/news/2018/Gigantic-cavern-heat-stora... https://en.wikipedia.org/wiki/Barra_system https://en.wikipedia.org/wiki/Storage_heater https://en.wikipedia.org/wiki/Earth_shelter#Active_and_passi... https://en.wikipedia.org/wiki/Bokpoort_CSP#Energy_storage https://en.wikipedia.org/wiki/Russian_stove#Design https://en.wikipedia.org/wiki/Passive_solar_building_design#... https://en.wikipedia.org/wiki/Aquifer_thermal_energy_storage https://en.wikipedia.org/wiki/Home_energy_storage#Thermal_en... https://en.wikipedia.org/wiki/Qanat#Cooling https://en.wikipedia.org/wiki/Regenerative_heat_exchanger https://en.wikipedia.org/wiki/Rammed_earth#History https://www.mha-net.org/ https://en.wikipedia.org/wiki/Solana_Generating_Station#Ener... https://en.wikipedia.org/wiki/Hot_water_storage_tank
see eg this map where scandinavia is the same color as france or southern uk: https://vividmaps.com/annual-sunshine-hours-of-world/
But of course wind is more stable around the year and produces more in the winter when there's more need for energy. And the sunlight is more direct closer to the equator.
Besides fewer sunlight hours, Finland also has lots of clouds and very steep sun angles which significantly affects production.
It's sad they are building gas-powered data centers in US instead of powered by renewables in Iceland.
So, at equal cost, the alternative to a megawatt of windmills may not be a megawatt of solar panels, but 10 megawatts of solar panels. And that can compensate for their lower capacity factor.
I don't think people are building gas-powered data centers in the US. There's a data center crunch in the US because people aren't building them because they can't get the power because of the US's anti-renewable-energy policies.
The solution is to develop everything, all kinds of renewables.
Desert land, lakes, and harbors are cheaper, so we should expect to see more panels there instead of on potentially arable land.
Then again, the same also goes for the other storage methods as the spread compresses. Eventually, as always, it all comes down to who can do it on the thinnest shoestring. 1/4 the cost, but the thermodynamic efficiency is 1/3 (direct heat vs batteries + heat pump, say) is still a winner. Finns aren't going to stop needing heat in winter soon, and if you can provide it even a fraction under the cost of battery electricity and a heat pump, you get the customer. And the district heat infrastructure probably already exists.
Theoretically this would be an endless cycle, which is of course constrained by very practical needs of the electricity users.
Surely the lifespan is almost forever. It's just a tank full of sand and some heating pipes. Maybe the pipes and/or control electronics needs to be replaced occasionally, but nothing should happen to the sand inside - like ever.
The sand is the least complex part. Industrial facilities like this take a lot to keep running.
The thing is, I'm unsure whether this holds true. Could you actually replace pipes inside a huge sand battery without bringing the entire thing offline? And at some point are you basically rebuilding it?
Apparently now it's time for the world to return to populist authoritarianism and isolationist policy in order to bury our heads in the...sand...until we have to collectively rise against them again. Except, this time, it may be America who bears the brutal brunt.
nobody cares about his car loosing value as soon as you drive off the parking lot. Or any other appliance - a fridge will never have a ROI, a washing machine will not and neither will a stove, a macbook or a fancy smart home system. They are part of our live, loose value and we accept that.
But solar or batteries (granted, mostly with home-solutions)? Better make money, otherwise why even bother.
- Fridge: has ROI vs. going to the store more often or getting food poisoning.
- Washing machine: Has ROI measured in the value of your time spent not slapping clothes against a board to make them clean.
- Stove: ROI vs. using and maintaining a fire pit, with the risk of burning your house down factored in.
- MacBook: ROI is how much work you can get done vs. a Windows machine, or not having a laptop and doing math really fast by hand on paper.
Etc. It is suspicious that there isn’t a “this will pay for itself in N years vs. not having it” statement somewhere.
Is the comment even that unfair? Asserting that it will never pay off because the presentation avoided mentioning anything about the payoff might be a little bit cynical, but not terribly so. It could be fairly presumed that if the project is a clear economic win, they would be proudly bragging about it; and the opposite presumption is also reasonably fair, even if it turns out to be wrong.
And what does such cynicism have to do with "MAGA"? That asserted association seems much worse than the initial cynical assertion.
"Everyone i don't like is Hitler". It's a rather immature way of disagreeing.
There is a KYM page about this phenomenon: https://knowyourmeme.com/memes/everyone-i-dont-like-is-hitle...
If you made 30k a year for 50 years you'd return 1.5m from your 1m investment, but you're only making 3%, which is a low return especially given the future risk (you'd have to run for 33 years just to get your initial investment back)
Either way it's worthwhile, because the reason people expect 10% is because the externalities are borne by others. Majority of people and countries in the world do not deem ROI to be the sole or even primary driver for investment, and judging investments only on the immediate financial reward already biases the conversation
It's partially that, other part is that we aren't really pricing in all the externalities of everything out there. So it's not that "there's no ROI", it's that "we aren't factoring things in the ROI calculation".
So while a heat battery might not make a huge profit, the ability to burn less fuel (less air pollution, less waste, etc), to offer redundancy and stability, the know-how and work it creates, that is all valuable as well.
The people who would mostly benefit from reduction in emissions - especially in the short term - are those in other countries. It's not going to be Finland suffering the most from doubling of the cost of food from failed harvests, it's going to be massive failures in rice harvests in south east asia. Finns will always be able to outcompete the average Cambodian when buying food.
One of the costs of emissions to western countries - say Spain - is increased bad weather - more frequent storms, fires etc. All fairly small stuff compared with mass starvation or water shortages though. That starvation leads to another problem -- increased migration pressure.
But those costs are going to be borne anyway. Even if Spain stopped emitting CO2, it wouldn't make an ounce of difference. International agreements have failed time after time to curb emissions.
The main benefit of renewable energy for a given country isn't the reduction in emissions, it's the increase in energy independence - no need to import gas or oil from unstable countries.
I think the more likely explanation is that this is a pilot project by a clean energy startup, it intentionally operates at a loss because it's RnD rather than mature tech, everyone involved is okay with this, and the company doesn't want to release its modelling of future ROI because that's valuable proprietary data and giving it away to clients and competitors is dumb.
I think this is a little unfair. If it were true, it would be the reason for wealth inequality: you're saying that the majority of people and countries are so financially irresponsible that they consume any resources they get without investing any. But in fact everyone I have observed closely, in every socioeconomic group, tries to optimize ROI. Most of them aren't very good at it, but they do try.
On the other hand, people who expect a 10% risk-free return are just going to get scammed. There are 10% opportunities in most people's lives—weatherstripping, coupon clipping, bulk food buying, etc.—but you can run out pretty quickly.
Average S&P total return (reinvesting dividends) is well over 10% over any appreciable timeframe (say 30 years), even during really low times (say buying at the peaks in 1999 or 1972)
And of course it isn't a risk-free return.
Consider what happened to investors in Germany, Hungary, or Romania in the 01930s, or South Vietnam in the 01960s, or Afghanistan in the 01970s, or Iraq in the 01990s.
You might think this is irrelevant because you don't live in 01930s Germany or 01970s Afghanistan or 01990s Iraq; you live in the USA.
But, if you live in the USA, you don't live in the USA of the 01970s or the 01930s. You live in the USA of 02025. In 02025, the country most like 01930s USA or 01970s USA is China, which is obvious if you read books from the USA from those periods. The USA in 02025 is the country that's been trying and failing to build high-speed rail for 60 years, since Japan got it working, and just elected a xenophobic demagogue who praises dictatorship; it's much more like 01980s Russia or 01930s Italy.
Warren Buffett said that, in the long run, you can't expect the stock market to return more than the long-run economic growth rate, which you can't expect to consistently be more than 3%. I don't understand the logic behind either of these propositions, but I suspect Buffett knows more about market returns than I do.
— ⁂ —
By contrast, if you can get an 0.8% discount on the potatoes your family eats by bulk-buying enough potatoes for the next three months, that's about a 10% annual return on investment, and the risk is pretty low—and almost entirely under your control. And, in practice, you can often get a much bigger discount than that, especially if you assign some cost to the errand of going potato shopping. You just have to make sure you have proper potato storage and that you don't have a sudden dropoff in family potato consumption.
How do I figure that ROI? Well, the amount of extra money you have tied up in potatoes oscillates between two months' worth and zero, with an average of one month of potatoes. But your expenditures on potatoes are 0.8% less each month, which is your earnings from that investment. Every year, you save 10% of a month of potatoes: 10% of your investment. Tax-free.
If you learn to calculate ROIs and reorganize your household expenses on the basis of ROIs, whatever income you have will go dramatically further than it would for someone who hasn't done that.
This is why I open the comments before the link.
The problem is: is it profitable to even store energy there? There is no mention beyond "In operation, the sand battery has demonstrated a round trip efficiency of 90 percent.". That doesn't mean much if you do not compare it to Lithium and you don't give me a breakdown of the costs.
The other thing: Size. Is that big thing enough to store energy for a city? a neighborhood? A building? A house?
If it's enough just for a house, then I have trouble seeing this scale.
I simply don't get it! The political landscape across the west is that there's swaths of people who've simply stopped believing mainstream media when they're reporting things, and somehow our reaction is to just lie even more? Try to out-lie camp Trump? I mean I don't think it's even possible to lie more than Trump so wouldn't the honest, nuanced truth be a a much better antidote than global left's current strategy of "also lie, but a bit less"?
I simply don't understand where it comes from. Like in what bizarro world is this shit a smart strategy? Is it all just incompetence?
Plenty of leftists have their own reasons to distrust media. But scarcely anyone imagines reasons why someone else would lose trust. Not that they could do anything about it anyway.
The "global left" is not a real thing. I mean, of course you can draw lines around groups any way you like, but this one doesn't offer meaningful insight.
yes and given that the energy you put in is practically free, it doesn't matter if it's not as efficient.
I understand it's wasteful, of course, but waste in a ecosystem of vast abundance seems like a feature, not a bug.
So easy that one of the actual problems we face is that by default grids will generally prefer to turn off the clean renewables and let the difficult to modulate fossil fuels run.
This is why negative prices are a good thing, financially incentivizing fossil producers to plan for flexibility and fining them when they fail to do so.
The problem is that it's not a ecosystem of vast abundance, just occasional abundance. Literally no-one in the world right now is sitting on a constant supply of TWs of excess electrical power and saying "golly gee what are we going to do with all this". Perhaps France got closest in history and their prices still aren't "too cheap to meter".
You can "waste" the power (either by actually "burning" it to heat and dumping it, or just disconnecting the solar panels), but then you'll be short of power later and need to fall back on something expensive or with high externalities. It's also bad in terms of the capex for the solar panels (assuming solar), as you can't use your expensive plant as much as you want. If you can you'd rather use "$10" of energy that you can't sell to store and sell it later, even as heat, at any price than just lose it all.
Even if you massively, massively overbuilt solar and wind so that you were in a "vast abundance" scenario on average, you still have to store some of it for night and/or winter.
Solar panels have no problem with being short circuited; the amount of heat they produce in that state is the same as any other black object in sunlight.
Windmills are like any other electromechanical generator in this sense. You have to stop them with a brake. But that is totally a thing you can do, and quickly, and every mainstream windmill does it regularly (if only to handle overspeed winds safely), although, when this system fails, you get spectacular viral video content.
In the usual case where it works, though, you don't need a load bank either.
Load banks come into play when conventional inflexible baseload generators can't ramp down fast enough or when perverse market incentives pay renewables operators to pump power into the grid when it's not being demanded.
Internet akchually: a small amount of the heat will be dropped in the wiring that forms the short circuit rather than in the internal resistance. So the panel will be slightly cooler than you'd expect for an object of that colour even in short circuit. They're the same temperature in open circuit, though. When operating normally, they can be quite a lot cooler and in fact you can detect non-functional panels by looking for hot ones with thermal cameras.
I did know that normally-operating panels were significantly cooler (23% efficiency means 23% less heat than a regular black body) but I had no idea that people used this feature to detect broken panels with thermal cameras. I'd only seen people forward-biasing the panels from an external source to stimulate NIR light emission and using NIR cameras.
You'd think water would be easier to exchange heat with since it can slosh around the heat exchanger elements in the tank more easily. Which should translate to lower costs since you don't need as many exchanger structures in the medium.
Any guesses for the motivation in using sand? Maybe it's that you can heat it over 100C? But then big heat differences to the environment mean high conductive/radiation losses or heavier insulation requirements.
Insulation isn't such an issue with sand because sand itself is fairly good insulator and obviously doesn't convect. 1m of sand is about the same as 10cm of air. 500C through 1m of sand if roughly 125W/m². Which isn't nothing but it's also 7m from the center to the edge, and the efficiencies only improve the bigger you make the silo.
Presumably they have a double-skin gap and other external insulation too. As the Icelandic hot water pipe systems show, which drop only a few degrees C over hundreds of kilometres of pipe (and thus a gigantic surface area to volume ratio), you can have really quite good insulation if you have space to make it thick.
The hassle of handling hot water is also presumably why they use hot air rather than water as a working fluid for heating the sand in the first place. The worst case if you spring a leak in a heat-transfer tube inside the tank is that a bit of air escapes. Leaking super-heated high-pressure water or steam into the (unpressurised) tank would be a much larger problem, and unloading up to 2000 tonnes of hot, damp, sand to plug it would be operationally very annoying if nothing else.
"Rock, sand and concrete has a heat capacity about one third of water's. On the other hand, concrete can be heated to much higher temperatures (1200 °C) by for example electrical heating and therefore has a much higher overall volumetric capacity."
and
"Polar Night Energy installed a thermal battery in Finland that stores heat in a mass of sand. It was expected to reduce carbon emissions from the local heating network by as much as 70%. It is about 42 ft (13 m) tall and 50 ft (15 m) wide. It can store 100 MWh, with a round trip efficiency of 90%. Temperatures reach 1,112 ºF (600 ºC). The heat transfer medium is air, which can reach temperatures of 752 ºF (400 ºC) – can produce steam for industrial processes, or it can supply district heating using a heat exchanger."
If I add some fixed amount heat to some fixed volume of water, it might rise by 1℃, while the same volume of concrete rises by 3℃. And by the same logic, on release, that fixed volume of water dropping by 1℃ releases 3x as much heat as when that fixed volume of concrete drops by 1℃.
So if you can max heat water to 100℃, and max heat concrete to 1200℃, and on release you let it go to 10℃ (probably the range is less in practice), then the water can drop 90℃ and the concrete 1190℃, so even if the water releases 3x the amount of heat per ℃, the water just releases 270 (per volume) while the concrete releases 1190 (per volume)
Also, looking at how hot water could theoretically get (decomposes between 2200-3300C), it looks like 1200C is an interesting limit. Above that and you get safety(practical) and cost issues with every material I could find (common salts, pure elements).
Sand just makes sense! Though, don't ever youtube sand battery.
Huh? I just get stuff related to this article?
in any case, how would you transport high temperatures to the industrial sites? water boils at 100° and few liquids boil above 400°. most liquids will be impractical due to cost or safety (combustibility, toxicity…).
Now, in practice you _probably_ don't want to do this, because, in this case, you have district heating demand, which is a far more efficient use of the power.
Square cube scaling means that insulation becomes trivial in total costs as you scale the installation up. Something that's convenient for a single household would probably be too hard to insulate, but this thing holds 2000t of sand.
[0] https://www.engineeringtoolbox.com/water-vapor-saturation-pr...
So quite a bang - allegedly this is 200lb, so about the same: https://www.youtube.com/watch?v=ZDgvar7ON54
Even the lower range doesn't leave much delta in best case of boiling water. So you would need some type of heat pumps instead much simpler heat exchangers. So that is also one cost optimization.
And of course it's still a win if you can heat the return water half of the way to spec with the battery, it's not necessary to have the battery heat it all the way to the plant outgoing temp.
District heating systems have been happily using ~90C water based heat batteries for a long time.
In the end it comes to balance with cost, simplicity, capacity and such. Heat pumps do allow extracting heat from colder storage medium. But on other hand electric heating elements and heat exchangers are very much simpler and cheaper.
But yes heat pumps are used in some parts as well in DH.
If it were pure silica sand, you could presumably get even hotter before anything changes chemically, but at the that point you start having materials issues with metal parts of the system: 500C is about the limit for ordinary steels to lose strength (and many are less than that - heat effects can often start at 300C).
That said in practice, at scale... before filling up your storage tank you'd probably need to pre-heat it once to remove all moisture and volatile gunk adsorbed onto the sand.
For those who haven't seen it there is a famous Mark Rober video: https://www.youtube.com/watch?v=My4RA5I0FKs
Collecting heat from wast water is free energy. When you defecate, wash clothes or dishes, or take shower there is warm water and solids going down the pipes. That heat can be used. In the summer stored cold sea water can provide district cooling.
Really interested in seeing how it fares in reality, almost sounds too good to be true.
There are significant trade-offs with this technology.
It's storing heat, so if you need electricity then you eat a lot of efficiency. I think Vernon said ~45% round trip efficiency. Batteries are 90%+.
The storage is at a high temperature (500-600C) which means that you can't use heat-pumps to produce the heat to be stored. This means that you miss out on ~400% energy gains possible from converting electricity to heat.
So the efficiency is pretty low.
That said, solar PV is really cheap and moving large amounts of earth into a pile is also a very much solved problem so in some cases, notably higher latitudes which have very long days and low heat/electricity demand in the summer and the opposite in the winter, it could still be a very good solution.
Heat from existing thermal power plants can be stored directly and later distributed with no conversion loss; excess electricity from renewables can be turned to heat at 100% efficiency, but the problem is that peak heat demand and peak electricity supply do not typically coincide. Heat batteries are meant to solve that problem.
So this system could supply 12 houses? Shows the importance of proper insulation, which is still on our todo list.
It sounds to me like you're likely an outlier here, for curiosities sake, where do you live?
We got a heatpump this year, going to be interesting to see how this changes things.
Your number above probably includes apartments and houses heated using district heating, e.g. from incinerating forest industry waste products.
Wh is an abomination that has come about because professionals think consumer brains would expose if they ever saw the unit watt-seconds (J). No consumer had any preconceived notion of either Wh or J, so had we used J from the start, it wouldn't have been a problem...
(Yes, same with Ah vs C, though the battery pros also shot themselves in the foot by starting to use C (electrical charge) to mean "the capacity of this battery" when talking about charge rate, a.k.a. current.)
And in this context it's much more obvious that it can notionally deliver energy at a peak rate of about 1% capacity per hour. If you said 1MW/360GJ, I don't think that would be nearly as clear.
Same for batteries, which started with car batteries/deep cycle batteries, rather than AA batteries, which usual don't even say, and phones. A battery that provides 1 amp (at 12V, but that's already given in a system) for 50 hours. Makes immediate practical sense, especially when equipment is often labelled in current draw and you can measure amps with an ammeter. 2.16MJ far less so.
> If you said 1MW/360GJ, I don't think that would be nearly as clear.
Wouldn't have been using the hour as the mental reference. As you say, it's impractical. We would have probably rounded the 86,400 seconds in a day to 100,000 and used that as the reference for comparisons. There's nothing noteworthy about the hour in this context.
> A battery that provides 1 amp (at 12V, but that's already given in a system) for 50 hours. Makes immediate practical sense, especially when equipment is often labelled in current draw and you can measure amps with an ammeter. 2.16MJ far less so.
I argued Ah could have used the SI base unit C, not that we'd use J. Whether you count As or Ah is still just a matter of building intuition.
Also it is a mess, as is traditional for US customary units:
> A Btu was originally defined as the amount of heat required to raise the temperature of one pound of liquid water by one degree Fahrenheit at a constant pressure of one atmospheric unit. There are several different definitions of the Btu that differ slightly.
(Best one is still the fluid oz, tho. A US customary fluid oz is about 29.6ml, a US food labelling fluid oz is exactly 30ml.)
In fact even Britain doesn't often use such units - even gas boilers, heat pumps and some AC are specced in kW. You do see BTU (the /hr is often missing) sometimes on AC marketing. My theory is 18000 sounds big and impressive and 5.2kW sounds "meh". We definitely don't talk about "tons", and we buy gas in cubic metres or "units" (which is just kWh)
It'll just be cheaper to build it on the ground than to dig a big hole and then build it in the hole.
Air is a pretty good insulator, we wear coats to prevent air from moving around. How do most coats keep you warm? Trapped air.
The London underground is hot because the ground is an okay-ish heat conductor: it carries heat away well enough that for a century it essentially acted as an unlimited heat sink, so during its initial construction they never bothered to build proper ventilation. In fact, it was advertised as the perfect place to stay cool during the summer! But this has gone on for long enough that a significant area around the tubes has gradually warmed up from 14C to 19C-26C, and the smaller temperature gradient from tube-to-ground means less heat is carried away, which means the tubes now stay hotter.
Had ground been a great insulator the Victorians would've had to install a proper ventilation system from the start, and they wouldn't been having this issue right now. On the other hand, had ground been a great conductor this issue would've taken far longer to pop up as the heat would've spread through the ground faster.
That is why I very specifically said open air.
the reason we wear coats has more to do with convection than the heat conduction of air
A housing complex near mine got a massive tank like this installed thirty years ago, and I think they put it underground to be able to build a house on top.
Or is there a way to "retrofit" district heating into houses with their own gas boiler or heat pump ?
Also the point of this plant is to exploit the counter-correlation of cheap electricity and cold. Usually there is a bigger correlation between cheap electricity and heat.
You can if you stagger AC/HP or even peltier elements.
Something that stores _energy_ is a battery. Not necessarily electric energy. You can absolutely have a battery with mechanical energy (wound up springs), a battery with kinetic energy (a weight in a shaft) a battery with nuclear energy (Thermal reactor in a satellite), a battery with thermal energy (silo full of very hot sand) or a battery with chemical energy such as a Li-ion battery.
This stores 100 MWh heat energy, so it is a battery.
From wikipedia:
> Energy storage is the capture of energy produced at one time for use at a later time to reduce imbalances between energy demand and energy production. A device that stores energy is generally called an accumulator or battery.
Norway's sovereign wealth fund will likely be completely gone in 20 years and will leave large swathes of the population without a pension because the Norwegian government works on the philosophy of "it's going to be okay, we have infinite money", already it's showing cracks as the only thing they actually have the money for is to make inflation skyrocket.
The coefficient of performance for a heat pump from with cold/hot of 10C/40C is about 10 - this is ballpark where a domestic heating heat pump sits - this is why a heat pump house needs to be well-insulated to work - the heating loop isn't actually hot-hot like with a boiler). From 10C to 500C, it's 1.5. That's 9/0.5 = 18 times less advantage.
At any delta, you can eke out a bit of advantage as COP is always over one, but at some point overheads in the system start to overwhelm your theoretical advantage and you might as well keep it simple and use a cheap and reliable resistor to heat things for dead-cert COP of 1.
You could use a heat pump with a higher COP if you have a really gigantic tank that you only heat to about 40-50C, but obviously the thermal transfer from that is pretty bad and getting it where it needs to go while still being hot enough to be useful is a problem.
Of course there are other benefits: it's still a good way to level electric generation, which is important for e.g. nuclear plants and wind power.
[1]: https://ourworldindata.org/grapher/energy-consumption-by-sou...
This is not a valid conclusion. Battery projects like this are gonna charge/heat up when the electricity price is low, electricity price is low when supply/demand ratio is high and this often happens when renewable electricity is most available and makes up a disproportionate share of the electricity mix.
Edit: Your graph is not what you say it is, this shows primary energy (i.e. includes fuel/heating/...), not "electric generation". Electricity in Finland is mostly nuclear, wind, hydro and certainly not "40% fossil fuel".
https://ourworldindata.org/grapher/electricity-prod-source-s...
and it backs up your point. Sorry to any Fins I might have offended with my lazy post.
Older private homes still use oil for heating. All new use electric, heat pumps, or geothermal heat pumps.
Eg that graph is not Finnish electricity usage. It's ALL energy, including cars and planes that still use oil...
Anyway, to explain my mistake, the data did not look "insane" to me, it's about right for most countries, and even if it had been correct for Finland the method they described might be favorable (some electric sources need leveling and using extra energy for heat is better than dumping it). Honest mistake, I'm not here with some agenda, and I learned of it by posting.
Anwyay, thanks for the correction! It's amazing (in a good way) that internet communicators can see something that looks plausible, but is wrong, and correct it! You've restored (some of) my faith in the internet.
I guess oil is too valuable to just burn.