Siemens Gamesa Unveils World First Electrothermal Energy Storage System

An anonymous reader quotes a report from CleanTechnica: Spanish renewable energy giant and offshore wind energy leader Siemens Gamesa Renewable Energy last week inaugurated operations of its electrothermal energy storage system which can store up to 130 megawatt-hours of electricity for a week in volcanic rock. The newly-opened electric thermal energy storage system is billed by Siemens Gamesa as "The Future Energy Solution" and as costing "significantly" less than classic energy storage solutions. Specifically, according to the company, even at the gigawatt-hour (GWh) pilot scale, ETES "would be highly competitive compared to other available storage technologies."

The heat storage facility consists of around 1,000 tonnes of volcanic rock which is used as the storage medium. The rock is fed with electrical energy which is then converted into hot air by means of a resistance heater and a blower that, in turn, heats the rock to 750C/1382F. When demand requires the stored energy, ETES uses a steam turbine to re-electrify the stored energy and feeds it back into the grid. The new ETES facility in Hamburg-Altenwerder can store up to 130 MWh of thermal energy for a week, and storage capacity remains constant throughout the charging cycles.

Re:

[Joce640k]

Pumping water upstream has hard geographical limits and maybe a big ecological impact. This doesn't.

Electricity storage as a byproduct

[sjbe]

Pumping water upstream has hard geographical limits and maybe a big ecological impact. This doesn't.

The first sentence above is definitely true. The second is unclear at this time. Not saying you are wrong (I suspect you are probably right) but we simply don't have enough data about it to really be confident in such an assertion.

The efficiency of this system for storing electricity isn't mind blowing (around 45% - compare with 70-80% for pumped water and 90-95% for Li-Ion Batteries) but I could see it being a useful option to have in some use cases. It appears to be a far more efficient option for storing and directly using the heat so I would think the ability to turn the heat back into electricity is more of a useful byproduct than the likely primary purpose of this system. I think most of the time it would be used as a heating system that also happens to be able to store electricity if needed.

Re:

[drinkypoo]

Pumping water upstream has hard geographical limits and maybe a big ecological impact. This doesn't.

The first sentence above is definitely true. The second is unclear at this time. Not saying you are wrong (I suspect you are probably right) but we simply don't have enough data about it to really be confident in such an assertion.

Pumping water upstream, itself, doesn't have an ecological effect at all, energy consumption aside. Storing water behind a dam does, and it's well-understood already. We have all the data we need to understand the ecological impact, because dams aren't new. It's the same old dam data.

Dam jokes

[sjbe]

Pumping water upstream, itself, doesn't have an ecological effect at all, energy consumption aside. Storing water behind a dam does, and it's well-understood already.

All correct and not disputed by me. The ecological effects are due to the existence of a dam and I think the point is that building a new dam with the intent of using for electricity storage has known negative ecological effects.

It's the same old dam data.

Groan... That's a long way to go for a joke...

Re:

[drinkypoo]

Groan... That's a long way to go for a joke...

Welcome to Slashdot...

Re:

[bobby]

It's the same old dam data.

Groan... That's a long way to go for a joke...

Darn that dam data!

Pumped water doesn't work

[FeelGood314]

Pumped water maintenance costs kill you. The systems built in North America are no longer used to store energy between low and high demand. They are still used but the owner (they are almost all owned by a Quebec company) that uses them as insurance. Utilities can buy the right to buy power on very short notice. Basically they are used when supply suddenly drops (lack of wind in the Pennsylvanian, Ohio, Michigan and Ontario) or an unpredicted jump in demand and the coal plants need time to ramp up.

:Pumped water works in Austrlia

[aberglas]

Has for many decades, Here is one

https://en.wikipedia.org/wiki/... [wikipedia.org]

Re:

[vtcodger]

"The efficiency of this system for storing electricity isn't mind blowing"

No kidding. System efficiency for solar PV + hot rock storage would seem to be about 0.45*0.20 = 9%. ... maybe ... if the force is with you and the wind is fair.

I suspect that a magnifying lens and a random rock might do about as well once fully optimized. Nonetheless, storing heat is probably a useful concept and perhaps one that deserves more attention than it is getting. I'm just not sure that electricity is the ideal heat sourc

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[torkus]

The heat storing could (should) be nearly 100% efficient - resistive heating itself is 100%. I expect the 45% is the thermal to electrical turbine conversion minus losses on the 1000t block of rock.

As for the initial energy capture, solar thermal significantly is more efficient in generating heat but (AFAIK) the system complexity makes it less ideal. If you're already building a turbine plant, I think this falls under a 'why not?'

Build ~2x the solar thermal capacity you need, and 1x the generation. Route

Re:

[skids]

Depends what you are using the heat for. If it's for high temperature industrial processes, then you are probably OK because resistive heating doesn't waste much that far out on the carnot curve. If it's for low temperature use you would have been better off using a heat pump to heat a larger mass to a lower temperature.
Might be best used in conjunction with cryo energy storage technologies https://en.wikipedia.org/wiki/... [wikipedia.org]

That said, if (a big if) these plants are super-cheap to construct and operate, eve

Re:

[Ocker3]

Just use two old un-filled mines. Oh, your country actually made the mining companies fill in the mines, and didn't let them just walk away? I bet you're feeling stupid right now, aren't you? *sigh* Yup, Australia has Huge numbers of old mines that were abandoned, and no one cared enough to make the companies fill them all in and replant the area. So, now we've got a lot of options for pumped-water storage.

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[account_deleted]

Comment removed based on user account deletion

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[Joce640k]

Yes, but pumped water energy storage has an efficiency of about 70%-80% round trip (wikipedia). What Siemens isn't telling you is that electrothermal energy storage is hideously inefficient (below 30% round trip, not counting static loses from heat outflow).

Compare that to Lithium Battery storage at 90% - 95% round trip efficiency.

True, but: Lithium batteries are expensive and have limited life before they need replacement.

Cheaper installation/running costs might mean this actually gets installed and used despite the inefficiencies. Better to have this than no lithium batteries at all.

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[torkus]

Lithium batteries are expensive, but if you're designing on an industrial scale the numbers change somewhat. You can control how much you charge/discharge to greatly expand the life cycle. Also, at ~80% you don't have to just trash (well, recycle) them because you car doesn't get good mileage anymore.

If you're looking at industrial scale, factoring in depreciation and scheduled, phased replacement of the battery banks is normal. You don't even have to take the system down. Batteries can be swapped out a

Re:

[gbjbaanb]

You can still get the same efficiency as lithium but without using lithium batteries - alternatives such as vanadium flow batteries would be an alternative that doesn't suffer the same problems at grid scale.

Lithium batteries cannot be recycled, IIRC only the casings and electrics can be recycled with current technology.

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[hipp5]

If you used this kind of storage to make wind/solar more effective, you would need 3x as much wind/solar production capacity to get the same effect as using Lithium batteries instead.

It all depends on how the math pencils out though. In certain situations it might still be cheaper to install 3x more production and use cheaper storage than install more efficient, but much more expensive, storage.

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[gweihir]

What Siemens isn't telling you is that electrothermal energy storage is hideously inefficient (below 30% round trip, not counting static loses from heat outflow).

Actually, it is 45% and they are not hiding the fact in any way: https://www.siemensgamesa.com/... [siemensgamesa.com]

Re:

[gweihir]

And this can be placed where there is space, it is not bound to a specific location.

Efficiency is apparently only 45% overall for electricity to electricity (98% electricity to heat), while pumped storage gives you apparently 70-80%. That means this is one more tool in the mix, but not a revolution. Not a problem, there are applications for this. Reserve power does not care much about efficiency, for example, as it is usually not used.

Re:

[Errol backfiring]

Well, if there is volcanic rock, I would think that that is not so much of a problem.

Re:Efficient storage?

[JaredOfEuropa]

One has to wonder what sort of losses are incurred converting to heat and then heat to steam and then to electricity.

No need to wonder, just read the article, it's right there. Yes, this is a lot less efficient than a battery, but it is also way cheaper. They also foresee use cases where the energy is withdrawn as heat or steam for industrial applications, in which case the efficiency is a lot better.
I wonder if this will scale down nicely. A lot of greenhouses around here use gas fired heat/power plants to provide additional heat in winter, the excess electrical power is dumped onto the grid. Perhaps a scaled down version of this would allow farmers to use wind or solar power to drive this plant and just use the heat from it directly.

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[account_deleted]

Comment removed based on user account deletion

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[drinkypoo]

Back of napkin thinking would lead me to believe that a better, equally low-cost, but compatible solution may be in order - such as molten salt.

If your molten-salt-in-rock cycle is interrupted and cools, how long does it take to restart? Weeks? Months?

As for why Siemens is doing this - what does Siemens sell (beyond power & control equipment)? Gas and Steam Turbines!

Nailed that part. It doesn't have to make sense for the planet, it only has to make sense for Siemens.

Re:

[rahvin112]

This system will also have significant system losses, from converting electricity to heat, back to steam and then back to electricity to simply the heat that's lost over time. LIon batteries are like 90%+ efficient with electricity,

I doubt this is going to have an efficiency above 50% just because of the limits on the steam generation alone. Add in the losses during the process and heat lost to the surrounding earth and it's going to be around 30% or lower. That's a really bad efficiency. To store that 130M

Re:

[hipp5]

I wonder if this will scale down nicely. A lot of greenhouses around here use gas fired heat/power plants to provide additional heat in winter, the excess electrical power is dumped onto the grid. Perhaps a scaled down version of this would allow farmers to use wind or solar power to drive this plant and just use the heat from it directly.

Probably not the electricity generation side of it, but certainly for heating purposes. In fact, it already exists ("ETS" - electrothermal storage). They are basically big ceramic bricks that are heater with resistive elements. With my power utility, the only way you can currently get on their time-of-day pricing scheme is to install an ETS heater in your house.

Specifics about the losses that are incurred

[GPS Pilot]

The converting-to-heat stage is 100% efficient. (When electrical energy goes into a resistive heating element, 100% of the energy is turned into heat.)

Going the other way, not so much. The most efficient heat engine in the world [ge.com] is 62% efficient -- which is a remarkable engineering achievement on the part of GE; nonetheless, that conversion stage loses 38% of your energy.

https://www.ge.com/power/about... [ge.com]

Re:

[tatman]

That was my question as well. And the article doesn't say.

Re:

[gweihir]

30 seconds of Google use give you this: https://www.siemensgamesa.com/... [siemensgamesa.com]

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[Ol Olsoc]

One has to wonder what sort of losses are incurred converting to heat and then heat to steam and then to electricity. Doesn't sound very efficient. My bets are that the iron/water battery is more efficient at power storage.

Did you mean nickel-iron battery? They show a lot of promise for energy storage in power generating systems.

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[jellomizer]

Turning Electrical Energy to Heat Energy is basically 100% efficient, as normally all energy will finally end up in a state of just heat. The question is how much of that heat energy is stored in the rocks and how much is just off in the atmosphere. Turning it back into steam is where there is energy loss. But that is where the energy loss is in for most power plants. There is energy loss in storing in batteries too, as it is a complex chemical process.
But the real problem with power generation is the fac

Re:

[olsmeister]

Just put a datacenter down there, or a bunch of bitcoin mining rigs.

Re:

[skids]

Turning Electrical Energy to Heat Energy is basically 100% efficient

But moving heat around using electricity is more than 100% efficient [wikipedia.org]. Resistive heating is only competitive when the gradient is very high (which it is in this case.)

Re:

[Joce640k]

Not great, but ... it's a hell of a lot better than nothing.

QFT.

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[hipp5]

One has to wonder what sort of losses are incurred converting to heat and then heat to steam and then to electricity. Doesn't sound very efficient. My bets are that the iron/water battery is more efficient at power storage.

It probably doesn't matter so much for fringe use cases, though I'm sure it does matter if the goal is ubiquitous adoption of the tech. For example, there are currently situations in parts of Europe where electricity prices go negative (i.e. the utilities PAY other entities to take it) when the wind is blowing hard. With a situation like that, who really cares about efficiency as long as your capital costs are low enough? With low capital costs your cash-on-cash return is going to be quite high, making this

Well, at least carnot efficiency should be good.

[Rei]

750C is fiercely hot for an energy storage system (max Carnot eff = ~70%). Molten salt storage is generally less than 300C (max Carnot eff. ~50%). And of course in the real world you can't get that close to the Carnot max, and as a general rule, the lower the temperature differential, the further your realized efficiency is from the theoretical limit.

Re:

[turp182]

Solar Reserve is building molten salt plants and they claim the temps are 1050âF (566âC).

https://www.solarreserve.com/e... [solarreserve.com]

Cresent Dunes already exists (110mw):
https://www.solarreserve.com/e... [solarreserve.com]

Here it is on the map (I would love to drive past it, probably as cool as the Very Large Array telescopes that I have driven past in New Mexico):
https://www.google.com/maps/pl... [google.com]

Their Sandstone project (2,000mw) is rather ambitious (but can be done in phases as it's 10 towers).

Re:

[angel'o'sphere]

They are talking about 45% efficiency for generating electricity, 98% for using the heat itself and 98% for creating steam for chemical processes.

Re:

[burtosis]

Actually 90% efficiency for steam from thier literature.

This gets me back to my thermodynamic pet peeve with cycle efficiency - it calculates this with respect to an absolute zero cold side resovoir which is technically correct but also creates the impression that the process itself is the culprit. I often find it helpful to think in terms of relative efficiency which relates to comparing it to a process with a cold side resovoir at ambient giving a design the possibility of achieving near 100% - this i

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[account_deleted]

Comment removed based on user account deletion

Re:

[burtosis]

I wasn't speaking of steam but the thermodynamic efficiency in general. People see things like the low efficiency of internal combustion engines and get the wrong impression. It would be a better representation if it was -450F outside, not 75F.

Re:

[angel'o'sphere]

Internal combustion engines are not inefficient because of the Carnot principle, but because of engineering constrains.
According to Carnot they would be around 42% ... in practice they are around or below 20%.

Re:

[burtosis]

Do you know why the Carnot efficiency is so low for an idealized process? It's because it's compared to the maximum possible efficiency which is achieved with an absolute zero cold side resovoir. see this example [gsu.edu] it dosent go to 100% unless your cold side is zero. This is technically correct but puts a spin on the efficiency that confuses people without engineering degrees. Also note how it dosent take into account that you are getting free heat from the ambient resovoir of the atmosphere. It would mak

Re:

[angel'o'sphere]

Why are you posting this nonsense all the time?

You posted it minimum 2 times in this threat.

BTW: you are wrong. But I guess you know that and only want to provoke.

Re:

[burtosis]

Why are you posting this nonsense all the time?

You posted it minimum 2 times in this threat.

The only thing I threatened in this thread is the status quo of ignorance. Sorry if it stung. Usually I assume people just didn't understand so I reiterate the points while laying a larger foundation from which to see the truth. Curious though, if the minimum is 2, what's the maximum?

BTW: you are wrong. But I guess you know that and only want to provoke.

I'm not even close to wrong. My mechanical engineering graduate advisor didn't much like the idea either during my masters defense, but he couldn't refute a single point and conceded relative efficiency has its place. I'm c

Re:

[necro81]

For point of reference: 750C is around the operating temperature for the second stage of a combined cycle gas plant, and higher than the temperature of superheated steam in a coal plant.

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[blindseer]

That might be "fiercely hot" for an energy storage system but just about right for a molten salt nuclear reactor.
https://en.wikipedia.org/wiki/... [wikipedia.org]

Also about right for a Brayton cycle turbine.
https://en.wikipedia.org/wiki/... [wikipedia.org]

This electrothermal energy storage is focused on storing electricity as heat, but that does not make much sense since in most every case the energy is in some usable form before it is converted to electricity in the first place. If you have that energy in some usable form already then s

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[dryeo]

Using this to store hydro power is plain nonsense, as a hydro dam already has a storage system in the water behind the dam.

Thing with (some?) hydro is that it has to keep running whether the power is needed or not. Reservoir can only store so much water and a steady flow of water is needed downstream for things like fish habitat.
If it's like the dam down the road here, which is mostly used for peak loads, this would raise the amount that can be generated during peak usage.

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[blindseer]

Thing with (some?) hydro is that it has to keep running whether the power is needed or not.

I'm not sure that is true but I'll assume it is. Do you know what also must be kept spinning? Steam turbines. Shutting down a steam turbine is a lengthy process to avoid expensive damage. Getting them spinning to where they can produce power takes anywhere from minutes to hours, depending on how long it's been since it last saw steam. Repeated cooling and heating cycles would be avoided as much as possible.

With an electrothermal energy storage system the inherent inefficiency means half the energy that

Re:

[dryeo]

I misstated that a hydro plant has to keep running, as I meant keep the water flowing, usually through the turbine but not necessary. As the water is flowing, might as well generate electricity with it.
Interesting what you say about steam turbines, something I know nothing about as steam isn't used around here for power and the potential damage from it cooling off is something I hadn't considered.
I was thinking of cases where peak demand is predictable and the power (hydro) plant can meet needs 22 hours or

But they threw away a carnot penalty.

[Ungrounded Lightning]

750C is fiercely hot for an energy storage system (max Carnot eff = ~70%).

Which is good, because they threw away a carnot penalty when they stored the heat:

The rock is fed with electrical energy which is then converted into hot air by means of a resistance heater and a blower that, in turn, heats the rock to 750C/1382F.

If they'd pumped in the heat from elsewhere using that power, they'd have kept closer to 100% of the energy, rather than throwing 30% away.

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[Rei]

My assumption is that this approach would be used with e.g. wind. So you're not throwing away initial heat - you never had initial heat.

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[Ungrounded Lightning]

... you're not throwing away initial heat - you never had initial heat.

The history of the electricity's generation is immaterial.

You "contract for the penalty" when you burn the electricity to heat in a ("100% efficient") resistive heater, rather than pumping heat from your heatsink into storage (at a coefficient of performance greater than 1, i.e. "more than 100% efficient"). Doing it with resisitive heaters ends up with less energy in the hot rocks.

The carnot penalty comes due when you do your withdrawal

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[Solandri]

The reason higher temperatures are worse for storage is because the rate of heat transfer is proportional to the temperature differential. So if the environmental temperature is 20 C, then a 750 C heat storage unit (730 C differential) will lose energy at 2.6x the rate of a 300 C heat storage unit (280 C differential, 730 / 280 = 2.6). This is why your CPU gets hotter under load. The temperature increases until the increased rate of heat transfer to the air equalizes the increased rate of heat generation

Shit

[DeathToBill]

130MWh is approximately the same as 110 tons of TNT. Not in my backyard, thanks...

Re:

[Anonymous Coward]

130MWh is approximately the same as 110 tons of TNT. Not in my backyard, thanks...

Yes, but unlike .. say, liquefied natural gas or something ... that volcanic rock isn't going to catch fire or explode, it's just going to be hot rocks. It's far less volatile than 110 tons of TNT.

It's interesting to store it as heat and then drive steam turbines later. It partly solves the problem of storage and managing supply for when you actually need it.

I will be curious to see how this works out. If we can start solvi

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[atrex]

130MWh is approximately the same as 110 tons of TNT. Not in my backyard, thanks...

Short of dumping 130 tons of cold water directly onto all that hot volcanic rock all at once, by what mechanism do you think it's going to explode?

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[DeathToBill]

130MWh is approximately the same as 110 tons of TNT. Not in my backyard, thanks...

Short of dumping 130 tons of cold water directly onto all that hot volcanic rock all at once, by what mechanism do you think it's going to explode?

Well, since the recovery mechanism is... dumping cold water on the rocks... yes, that's pretty much what I had in mind.

Re:

[gweihir]

Some people do not even begin to grasp physics. This thing has no explosion risk.

Re:

[jellomizer]

Sure we can make sure it isn't in your backyard, we can just cut the power from your home too. I feel it is important for people to understand the trade-off we are facing for our luxuries.

How many small town had their economy collapse, because their water supply got polluted, only for the wealthy company owners who live hundred miles away complain that they are being unfairly sued because of the value of their product.

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[burtosis]

Nobody tell him about E=mc^2

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[Waffle Iron]

130MWh is approximately the same as 110 tons of TNT. Not in my backyard, thanks...

How about in your garage?

If you have a large pickup truck with a 40-gallon fuel tank, you've got the equivalent of over one ton of TNT right inside your house.

Interesting

[Ol Olsoc]

I'll be looking at this closely.

Even legacy generation plants often need storage. So we have various methods of doing it. Here's one https://en.wikipedia.org/wiki/... [wikipedia.org].

The storage medium will depend upon the local conditions. In my area, we couldn't use volcanic rock because there isn't any, and I suspect there would be a lot of problems with trying to use shale and limestone. We are blessed to have a almost constant wind presence (Allegheny Escarpment)

So some places - batteries, some places pumped s

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[blindseer]

I'll be looking at this closely.

Even legacy generation plants often need storage.

Legacy generation plants are often steam plants, and they already store their energy in the fuel. If they need any energy storage then it must be in a form that is somehow better than not burning the fuel in the first place.

The advantage that pumped hydro and chemical batteries offer is the ability to react far more quickly to changing demand than any steal plant could. Since this storage system is a steam plant then it cannot react to changes in demand any faster than any other steam plant.

Wind and solar

Re:

[Ol Olsoc]

If you're interested, there's a bit more info here [stiesdal.com] in the downloadable presentation.

Thanks much!

Heat a rock and then use a steam engine?

[gurps_npc]

This is what counts as an 'new' energy storage system?

Sorry, but this sounds like the total absence of an idea.

What problem does this solve?

[blindseer]

The problem with wind and solar power is their intermittency. When the sun sets or clouds pass by the solar collector output drops, and it tends to drop fairly quickly. Same for wind, when the wind stops it can be fairly quickly. Same for load changes, the load on a grid will ramps up fairly quickly and quite suddenly in the case of some kind of failure in the system. The primary benefit of chemical battery storage is its ability to respond in fractions of a second.

One large problem that is brought up time and time again against coal and nuclear power is their inability to change output quickly enough to match the changes in load. This is typically done with natural gas turbine generators, or less commonly this is done with diesel generators. The reason traditional coal and nuclear cannot follow the load is because it uses big steam turbines. Steam turbines are a very old technology, very efficient (by electrical generation standards) and therefore cheap to run. Like intermittent wind and sun this old steam technology could use chemical batteries to follow load if proven to be cheaper than the natural gas and diesel generators used currently.

Now we see a proposal for energy storage that uses steam to convert the stored energy to electricity. This is a technology that cannot follow changes in load on the grid fast enough. What is even more boggling is the multiple, and not terribly efficient, energy conversion steps proposed. There is the conversion of solar radiation (in light or heat) or wind (a mechanical energy) into electricity, the electricity to heat, the heat to mechanical power, then back to electricity. Again, steam is used as part of this process and it cannot follow changes in load fast enough. There will still be a need for natural gas, fuel oil, chemical batteries, hydro (pumped storage or traditional), or some other power source capable of following load.

With chemical batteries there is a rather simple, and efficient, shift of electricity to chemical energy, then back again, as storage. This is a system that can react very quickly to changes in load. With pumped hydro storage the water pumped up the hill is also a fairly simple and efficient conversion, and a hydro electric dam can follow load changes well enough on its own.

This process does not solve the problem of the intermittent nature of wind and solar because it cannot match the load. That alone makes this a nonstarter. The inherent inefficiency of multiple conversions is also a problem. Had they used solar energy more directly in some way to heat the rock then it might make some sense. With the slow response of steam this process has there is already a far better energy storage system already in place. This is the piles of coal outside the many power plants already.

This is a solution in search of a problem.

Re:

[blindseer]

So for it to work, we will need both short term battery(expensive storage) and long term cheap (pumped hydro, molten salt, maybe this...) storage.

We have very inexpensive short term and long term storage already. For the short term we have natural gas and fuel oil tanks for burning in gas turbines and diesel engines. For long term storage we have coal, uranium, and (again) natural gas for use in steam thermal plants.

I find it difficult to believe this means of electricity storage will ever be viable. For this to be viable the costs of wind and solar would have to be low enough to not only compete with existing thermal power but with a wide enough

Re:

[drinkypoo]

I find it difficult to believe this means of electricity storage will ever be viable.

Maybe if they could combine it with solar thermal. Mirrors are cheaper than solar panels.

Re:

[blindseer]

I don't know if you noticed, but the world is generally trying to get rid of coal and natural gas in the long term, and nuclear plants are shutting down on their own.

There is no longer any question that the future energy policy of the USA and any other first world nation will include nuclear power. Old plants will be shut down but new ones will take their place.

This is solution for tomorrow, not for today.

That's nice. What does anyone propose we do until this future technology can be deployed? The wind and solar advocates promise much but haven't been delivering well. They tell us we can do without nuclear power since wind and solar power will be so low cost. We cannot simply take that on faith. If we don't

Re:

[blindseer]

You think nuclear waste is a problem? Well, there's only two ways to dispose of nuclear waste. One option is to store it until it decays away. Depending on who you ask this can take anywhere from 300 years to 3 billion years. The other option is neutron bombardment, that means nuclear reactors.

If you believe nuclear weapons are a problem? If you do then again there are two ways to dispose of the weapon grade material. We can guard it until it decays away, which takes millions of years, or neutron bomb

Conflating Storage Units

[necro81]

The article is conflating thermal storage with electrical storage:

which can store up to 130 megawatt-hours of electricity for a week in volcanic rock

The new ETES facility in Hamburg-Altenwerder can store up to 130 MWh of thermal energy for a week

So which is it? The Siemens press release [siemensgamesa.com] is clear that the number is thermal storage. But then the ignorant reporter saw "store 130 MWh of energy for up to one week" and immediately thought that meant electricity.

To be clear: I am not griping about the technology. Large-scale energy storage is important now and only will become more so, and the more ways we have to do it, the better. I am just disappointed that, yet again, journalists can't keep their units straight.

I guess it could have been worse, the reporter could have totally bolloxed the units and said some nonsense like "130 MW per week".

Re:

[sysrammer]

To be clear: I am not griping about the technology. Large-scale energy storage is important now and only will become more so, and the more ways we have to do it, the better. I am just disappointed that, yet again, journalists can't keep their units straight.

I saw an article from a group of scientists that used to work on the Mars Climate Orbiter. They took a look at this process and declared that they can improve the energy conversion to within twelve parsecs.

Steam driven turbines

[mveloso]

Steam driven turbines seem to be de rigeur for converting heat into electricity. You'd think there would be a better way by now.

If this pans out...

[Alamandorious]

If this pans out it will solve the biggest problem with renewables outside of their inefficiency. It basically makes them viable.

generator is rated only 1.4 MW

[extensive]

Compared to the storage capacity of 130 MW, the turbine/generator are tiny, providing just 1.4 MW of electrical power. https://www.siemensgamesa.com/... [siemensgamesa.com]

Re:

[nitehawk214]

If you think "heating a thing up with electric heaters" is technobabble, then perhaps you are an idiot.