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Power United Kingdom

Construction Begins On World's Biggest Liquid Air Battery (theguardian.com) 117

AmiMoJo shares a report from The Guardian: Construction is beginning on the world's largest liquid air battery, which will store renewable electricity and reduce carbon emissions from fossil-fuel power plants. The project near Manchester, UK, will use spare green energy to compress air into a liquid and store it. When demand is higher, the liquid air is released back into a gas, powering a turbine that puts the green energy back into the grid. The new liquid air battery, being developed by Highview Power, is due to be operational in 2022 and will be able to power up to 200,000 homes for five hours, and store power for many weeks. The Highview battery will store 250MWh of energy, almost double the amount stored by the biggest chemical battery, built by Tesla in South Australia. The new project is sited at the Trafford Energy Park, also home to the Carrington gas-powered energy plant and a closed coal power station. The plant's lifetime is expected to be 30-40 years.
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Construction Begins On World's Biggest Liquid Air Battery

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  • Once the air is compressed and stored in a sealed container, it should last indefinitely (amusing no leaks) until energy is used to unseal the container (like a screw or something). The article does not go into detail on how much fossil fuels are used to create the battery, but I bet that it will take decades to be carbon neutral (still better then never being neutral).
    • by Anonymous Coward

      You can lose a great deal of energy in the form of waste heat from compression. Heat energy which is pulled from the environment upon expansion - and in some cases even supplied by burning natural gas.

      • Re:Storage (Score:5, Informative)

        by tg123 ( 1409503 ) on Thursday June 18, 2020 @11:54PM (#60200720)

        You can lose a great deal of energy in the form of waste heat from compression. Heat energy which is pulled from the environment upon expansion - and in some cases even supplied by burning natural gas.

        Highview has had at pilot plant in Bury, near Manchester, running since 2018 which has an efficiency of 50% while this new commercial scale plant will have an efficiency of 60% by capturing the heat produced by the compression and using it to reheat the air when it is used to generate electricity. There is nothing new technology wise here as it uses well known technologies used by industry to produce liquid air , the real difference here is using the liquid air to store and generate electricity. https://www.economist.com/scie... [economist.com]

        • That sucks compared to pumped storage. It's not like the UK is short of more pumped storage sites so why on earth this is going forward God only knows.

      • by tg123 ( 1409503 )

        You can lose a great deal of energy in the form of waste heat from compression. Heat energy which is pulled from the environment upon expansion - and in some cases even supplied by burning natural gas.

        Not as much as you lose from burning fossil fuels with ICE Cars 80% of the energy is lost to heat and with Coal fired electricity generation its 70% lost to heat.

      • Thought about the waste heat too. I don't know what's nearby, but it would be great if they could use the low-grade heat produced as part of a district heating loop or as part of some industrial process. Fortunately capture and reuse of waste heat is common enough that it's likely the designers thought of it. Possibly they could capture some in thermal storage to use on the expansion valves when releasing compressed air (to keep them from freezing/icing).

    • Re:Storage (Score:5, Informative)

      by Enigma2175 ( 179646 ) on Thursday June 18, 2020 @09:46PM (#60200476) Homepage Journal

      The air is cooled and when they want the power back it is warmed and expanded through a turbine. It doesn't mention efficiency in the article but I doubt it's very high. The Wiki article [wikipedia.org] seems to support my suspicions:

      In isolation the process is only 25% efficient, but this is greatly increased (to around 50%) when used with a low-grade cold store, such as a large gravel bed, to capture the cold generated by evaporating the cryogen. The cold is re-used during the next refrigeration cycle.

      So is this plant 250 MWh input or is it truly 250MWh output? Either way, they compare it to Tesla's Australian battery but with that efficiency it doesn't seem like they are comparable.

      • Assuming 50% efficiency, I think they're using input numbers.

        Rough math

        900kwh month home usage (Google result)

        730 hours in a month (Google convert)

        900/730 = 1.25

        1.25*5*200,000 = 1.23 megawatt hours

        That's approximately half the 250 number.

        Obviously I rounded all my math.
        • Re: Storage (Score:5, Interesting)

          by rtb61 ( 674572 ) on Thursday June 18, 2020 @11:22PM (#60200688) Homepage

          Now compare that to the efficiency of putting a full solar panel array on 200,000 houses and having two batteries, one for the house and when that one is full, it goes to a battery for the grid to sell to other users. Which is the most efficient, seeing as the structures are already then and secured and monitored, they just need the panels and the batteries.

          It makes far more sense to make deals with home owners especially landlords, for solar panels and batteries for a distributed energy generation and storage solution. Some will buy the gear, some will lease it and some will just pay for the electricity at a reduced price. The capital cost is higher but owners cover a lot of it, for the corporation that owns the grid, a big win.

          • Exactly; when you look at component costs of electrical energy, distribution is the biggest problem. Demand-side and supply-side (or in this case grid-side) energy storage maximize the grid efficiency and let you do a lot more with less.

          • by bazorg ( 911295 )

            It's difficult to imagine let alone calculate efficiencies if first we have to go retrofitting panels to 200,000 houses in a built up place like Manchester. The traffic alone would justify every single NIMBY reaction.
            If starting such huge building works from scratch is not possible, placing this energy storage in a centralised location seems like a valid approach.

            • by Shotgun ( 30919 )

              I remember in the 90s reading about how expensive it would be to convert the telecom infrastructure to fiber.

              "It's not going to happen. No one can afford it."

              What actually happened in that companies used fiber for new installations, and only replaced existing cable when it wore out. 30yrs later, nearly all of the infrastructure is fiber and it was all taken in stride.

              rb61 paints a good end goal. It is something that would grow organically over years, and will won't make headlines.

            • It's difficult to imagine let alone calculate efficiencies if first we have to go retrofitting panels to 200,000 houses in a built up place like Manchester.

              When? On Tuesday? Is that when you're going to retrofit all of the houses?

              Or maybe you should spread it out, and do it over a week. Perhaps a year? Maybe ten years.

              And if you're doing it over 10 years, that's 2000 per year, which comes out to 5.5 every day. Which is also 0.00275% of the houses in the city, so you're going to increase traffic by that much, or even DOUBLE that much!

              I guess we should cancel switching to solar. That's just not workable.

          • by AmiMoJo ( 196126 )

            Like most things in energy production it's an economic problem. Much easier to raise capital to build a storage plant with clear, tried and tested business model.

            Especially in the UK a lot of people are ignorant and scared of solar power and batteries and wouldn't allow them to be installed in their house even if it was free and guaranteed to reduce their energy bills. Unfortunately certain newspapers have spent decades sowing lies about renewable energy and it's very hard to undo that. Realistically we may

            • by nagora ( 177841 )

              Like most things in energy production it's an economic problem. Much easier to raise capital to build a storage plant with clear, tried and tested business model.

              Especially in the UK a lot of people are ignorant

              Possibly

              and scared of solar power

              Not true.

              and batteries

              So outlandish a claim as to be hard to say whether it's true or not. Seems unlikely.

              and wouldn't allow them to be installed in their house even if it was free and guaranteed to reduce their energy bills

              I see houses covered in them every day. New builds quite often have them pre-installed.

              Unfortunately certain newspapers have spent decades sowing lies about renewable energy and it's very hard to undo that.

              I'm sure there's cases of newspapers lying about wind farms and other "visible from space" stuff but solar panels seem to have largely escaped.

              Realistically we may have to simply wait for those people to die of old age because undoing the brainwashing at scale is almost impossible.

              Aaaaand there we have it - people who disagree with AmiMoJo are brainwashed (or racist. Probably both).

              • by AmiMoJo ( 196126 )

                The scaremongering around solar panels was mainly about the effect on house prices and maintenance issues. The stuff about batteries was the usual nonsense about them only lasting a few years and catching fire.

                Parts of the British press will print any old scare story to sell a few copies. They did the same thing with electric cars, telling people they would need to rent the battery and pay £8,000 to replace it after 3 years even as Nissan were selling cars with an 8 year warranty.

          • The primary benefit of LAES is that storage capacity is extremely cheap -- you just need a bigger tank. That's almost impossible to beat with any kind of battery except for a flow battery.
        • by tg123 ( 1409503 )

          Assuming 50% efficiency, I think they're using input numbers. Rough math 900kwh month home usage (Google result) 730 hours in a month (Google convert) 900/730 = 1.25 1.25*5*200,000 = 1.23 megawatt hours That's approximately half the 250 number. Obviously I rounded all my math.

          Highview say they plan on 60% efficiency from input Electricity used and there are two numbers 50mwh /250mwh - 50Mwh generation and 250 Mwh storage and from what I understand that is actual storage and generation capacity. https://www.economist.com/scie... [economist.com]

      • The company is quoting 60%. When combined with waste heat and cold storage (or usage), then the economics get better. You could build one of these next to a bio-gas sewage works, for instance, and use the waste heat as part of the water treatment, and the waste cold to increase the efficiency of your gas turbines. This technology looks very scalable and re-locatable; so you could put it where waste heat and cold is most useful.

        The impressive thing here is the not the efficiency though, it's the scale. IIUC,

    • (amusing no leaks)

      I love this

      1) Word choice
      2) Neglect for reality

    • I hear it's good for stopping T1000s, too. But all seriousness aside: this is not compressed air, this is liquified air. I was looking for a good phase diagram for nitrogen (the primary component of air), but couldn't find one that went up to room temperature or there abouts. But my impression is that it would take a huge pressure to liquify nitrogen at room temp, meaning you'd probably have to keep it cold, even cryogenic. If that's the case, then I don't see how they could store it for weeks without u

    • Once the air is compressed and stored in a sealed container, it should last indefinitely (amusing no leaks) until energy is used to unseal the container (like a screw or something).

      It can't last indefinitely without further energy input. Air only stays liquid at -194 degrees celcius. If the temperature increases past that it boils and turns back into a gas. You could insulate the shit out of your container, but even the best insulation will allow some heat transfer. Ergo you have to keep actively cooling it if you want it to stay liquid.

      • by tg123 ( 1409503 )
        All you would have to do is keep the liquid air at its boiling point in a insulated container the evaporation of a small amount of the liquid air takes away heat and the rest of the liquid air in the container stays cool. This what LNG tankers use and they can stay at sea for weeks at a time. https://en.wikipedia.org/wiki/... [wikipedia.org]
        • Re: Storage (Score:5, Interesting)

          by c6gunner ( 950153 ) on Friday June 19, 2020 @12:54AM (#60200844) Homepage

          Yes, I'm aware, I've worked with cryogenic liquids myself. However whether you're adding energy to cool it, or allowing it to offgas to cool it, you're still using/losing energy to maintain it in that state. Ergo it cannot "stay in that state indefinitely", which is what I was pointing out to him.

          • by tg123 ( 1409503 )
            ok :-)
          • In this instance temperature keeping is pretty easy. Heat transfer is proportional to surface area while capacity is is proportional to volume. At scale, the surface area to volume ratio gets tiny such that losses are tiny. Your lab dewar flask is not a good proxy.

            Also keeping the liquefied air cold is as simple as letting a bit boil off as needed. The vaporization takes huge amounts of heat with it. It's a loss for sure but small. Even lithium batteries have some self discharge to contend with. This

            • I'd also wager that most of the time they don't plan to "burn off" the entire store of liquid air at one time, just chunks of it and probably with some regularity to it. So there's probably regular boil off and re-compression cycles that go on, making the idea of making and storing the entire lot of liquefied air for years kind of an irrelevant problem.

              The value in these renewable storage systems seem to be the regular marginal unneeded energy produced "for free" by solar or wind that can be put to use sto

    • How do you know that only fossil fuels are used to create this thing? There is plenty of renewable energy generation in the UK and generally more than can be used hence the battery.
  • Does anyone know the efficiency of this battery (the percent retained when going to and from the battery)?
    • Cryogenic energy storage is typically around 50% efficient, but it seems this technology (LAES) is in the range 60-75. (I assume the range is due to variations in ground temperatures, but not sure )
      • More likely that the attached "peaker" NG plant may not be operating when time comes to drain the storage; with the "cold" start no waste heat stream would be available to decompress the liquified air until after some/all of the storage has been used as the LAES would be preferred over activating the NG plant.
  • Paywalled (Score:5, Informative)

    by TheInternetGuy ( 2006682 ) on Thursday June 18, 2020 @09:13PM (#60200380)
    There's an Ars-Technica from a few days back that is probably much more informative anyway. https://arstechnica.com/scienc... [arstechnica.com]
    • Sorry, actually it wasn't paywalled. It seems just some JS/Browser wonkyness that didn't let me click past the registration popup.
    • by AmiMoJo ( 196126 )

      The Guardian is paywall for you? It always lets me straight in with just a little begging box at the bottom. If it's paywalling people I'll look for alternative sources next time but I thought it always showed the full stories.

  • by ZombieEngineer ( 738752 ) on Thursday June 18, 2020 @09:37PM (#60200460)

    These are two very different beasts - Highview power project will be able to provide power to a small city for an entire day but is unlikely to have much "spinning reserve capacity" to help the grid when something goes wrong elsewhere. You simply can't go from zero to full load in under 15 seconds (hydro plants can - timing is in seconds, the Tesla battery solution responds in milliseconds).

    HOWEVER - Nice to see an alternative storage suitable for base-load applications, currently battery solutions are more expensive per kWh capacity compared to grid supply charges (cheaper to buy power off the grid than to install a battery to store power that would otherwise be lost - from memory the battery pricing is about 150% of the local grid supply cost).

    Would like to see a storage solution that is at most half the current cost of a battery equivalent solution.

    Zombie Engineer

    PS: Comparison between battery and grid price - 5 years x 250 days/year x supply tariff ($/kWh) x storage capacity (kWh) vs Battery installed cost ($)
    250 days is for a typical office building that does not work weekends or public holidays. Yes the comparison is a bit simplistic but it is equivalent to the MPG sticker on a car - depends on the actual circumstances.

    • It seems a hybird approach would work well here, with a large air/liquid battery for long term energy output, with a smaller chemical battery that can quickly respond until the larger battery can get up to speed.
    • by AmiMoJo ( 196126 )

      This will be aimed more at replacing peaker plants, rather that grid stability like the Tesla battery in NSW. Rather than spin up some coal or gas for a few hours a day they can use this to time shift generation from the previous night.

      It will also help smooth out renewable output. If the wind dips a little for 15 minutes they can make it up by releasing stored air, making renewables suitable for base load and even more highly predictable than they already are.

      • by dwywit ( 1109409 )

        *small cough* it's in South Australia.

        Carry on.

      • The more times you can cycle the storage system within the economic life of the system, the more cost effective it becomes.

        The Australian "National Energy Market" (commonly known as NEM) has a few quirks which makes the Hornsdale Reserve battery (South Australia) viable. During a south east heat wave (impacting South Australia and Victoria, the cities of Adelaide and Melbourne respectively) there is simply not enough generation capacity to power all the air conditioners when it is 40+C/105+'F outside. This

    • The technology is both black start and 1 minute response. Gas turbines need to compress before ignition I guess, where as this form of technology doesn't. You just open the tap and away it goes.

      They are looking at adding batteries for 1 second response.

  • Cool (Score:4, Funny)

    by Ronin441 ( 89631 ) on Thursday June 18, 2020 @09:46PM (#60200474) Homepage
    Cool cool cool.
    • Speaking of which, I have always wondered why the storage tanks don't have heat-sink fins on them...
      • Because attaching heat sink fins to a cryogenic tank accelerates the heat flow into the tank?

  • by BAReFO0t ( 6240524 ) on Friday June 19, 2020 @01:02AM (#60200860)

    I thought we had no problem storing compressed air indefinitely. Did they somehow use a very shitty release valve?

    • It's not "compressed air," it's "liquified air."

      The cryo container is probably heavily insulated, but a small amount will continuously evaporate and keep the bulk below the boiling point.

  • by dr.Flake ( 601029 ) on Friday June 19, 2020 @01:54AM (#60200970)

    So the regeneration cycle is atrocious, but still better than loosing the energy all together.
    Can anyone think of alternative good use for this compressed / liquefied air, other than direct conversion back to electricity?

    For instance. It's very easy and cheap to power a simple car with compressed air. So imagine having the city's buses driving on the excess energy. The heat required to expand can be used to provide airconditioning in the interior of the bus. No toxic fumes in your inner city has a large health "gain" / value.

    Or, to maintain a liquid state, a small continuous leak is needed. The waist air is still very cold, and could be used to keep a large frozen warehouse cold.

    anyone other creative alternative uses?

    • Can anyone think of alternative good use for this compressed / liquefied air, other than direct conversion back to electricity?

      Rocket fuel. Well, rocket oxidizer by separating the liquid oxygen from the other gasses. In seeing how the liquified air process works there's dry ice that comes out as a by product, as does argon and perhaps a number of other gasses in quantities valuable enough to bottle up. Liquid nitrogen has a number of industrial uses. Argon is used in welding. Those four gasses, oxygen, nitrogen, CO2, and argon, make up something like 99.9% of the atmosphere. All of them have value when separated out, which ki

    • by AmiMoJo ( 196126 )

      Blow the air back at the windmills to make them spin when windspeed drops.

      • Blow the air back at the windmills to make them spin when windspeed drops.

        Poe's Law or Dunning Kruger? Maybe both.

        • by AmiMoJo ( 196126 )

          I kinda ripped it off from an XKCD although that used an electric fan so my idea is probably more efficient.

  • by AndyKron ( 937105 ) on Friday June 19, 2020 @02:37AM (#60201064)
    If this is so great why isn't being used now? It's nothing new
    • It is being used. This is their second plant. The pilot plant has been in operation for a number of years.

    • by AmiMoJo ( 196126 )

      It's been in use for ages, this is just the first time it's been scaled up to this level. They have had a smaller demonstration plant operating for a couple of years now.

  • Leakage, heat loss, ...I'm no engineer but turning air into liquid takes a ton of energy, a lot of which is gone once the hot compressed gas cools down.
    • The UK's main pumped-storage facility (Dinorwig) runs at around 75% efficiency. This liquid-air battery will run at an estimated 60% efficiency, so it is fairly close.

      Thanks to the UK's large-scale rollout of wind farms, the liquid-air battery will be harvesting energy that is essentially "free" at off-peak hours, and using it at peak times. For that reason, the efficiency of the battery can afford to be relatively low.

  • As someone who lives in the southern part of the United States this interest me. We get plenty of sun in the summer time - and much of the rest of the year as well. I could see using solar to compress the gas to store the power and run air conditioners at the same time.

    I've also thought of just how much regular battery capacity would be needed to run air conditioners at night. The area I'm in doesn't have reliable wind power BTW.

    If properly harnessed releasing compressed gas to run the air-conditioning power would be great (the low last night around here was about 80F), but it could be harnessed more directly as well. Decompressing gas blows cold, and cools the container it was in as well. The decompressing gas itself could be used to cool a house on a small scale. If ambient air then by directly venting it into the cooling system, if something less safe by using "radiators" in a heat exchanger.

  • Just imagine the sound all that air would make when it escapes. You could probably hear it across the country
    • Yeah, I was thinking about this: What if the terrorists take it over? They could release all that oxygen and increase the risk of forest fires!

    • by hawk ( 1151 )

      and once again, the dog will get blamed . . .

      (Clifford, is that you?) :)

      hawk

  • Efficiency isn't terribly high compared to the 70-80% cited for pumped storage [wikipedia.org], but of course not everyplace is suitable for that ... Here's a nice compendium of energy storage projects [wikipedia.org].

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