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Earth United Kingdom Technology

Scottish Power To Build Vast Battery To Improve Wind Energy Supply (theguardian.com) 228

Scottish Power is to undertake the most ambitious battery power project in Europe in an attempt to unlock the potential of the UK's wind and solar farms. From a report: The company will connect an industrial-scale battery, the size of half a football pitch, to the Whitelee onshore windfarm early next year to capture more power from its 215 turbines. The first major onshore wind power storage project will lead the way for a string of similar projects across at least six of Scottish Power's largest renewable energy sites over the following 18 months. It claims the 50MW battery systems promise a "significant step" on the road towards renewable energy, providing baseload, or continuous electricity supply, for the UK energy system. The battery has more than double the power capacity of any existing battery in the UK. It would take an hour to fully charge and could release enough electricity over an hour to fully charge 806 Nissan Leaf vehicles over a total of 182,000 miles, according to a spokesman for Scottish Power.
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Scottish Power To Build Vast Battery To Improve Wind Energy Supply

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  • Sounds like they want to use the batteries to power big fans to supply the wind..

    • Sounds like they want to use the batteries to power big fans to supply the wind..

      No, Ivan, supply in that sentence follows the word "energy," not the word "wind." Wind is merely an adjective telling you what category the supplied energy is in.

      Even if you take "wind energy" as a compound noun, it still describes a type of energy, not an energy source. And "supply" is talking about distribution, not origin.

      When you "supply" something, you're providing it, not originating it.

  • by mykepredko ( 40154 ) on Monday June 10, 2019 @01:22PM (#58740364) Homepage

    182,000 miles / 806 Leafs = 225 Miles on a single charge.

    I don't know how useful that way of measuring energy is - it's like saying a school of piranha can skeletonize a cow in two minutes.

    Personally, I would think standardizing on 10kWh per house per day would be more reasonable. If this is a 50MWh system, then this means that the turbines and battery could power 5,000 houses a day.

    Which seems like a more easily understood way of describing how much power is being generated.

    • Brings its own issues though - not all countries have the same power use per house. I know that the US uses a lot more power per house than the UK, because of the widespread installation of domestic air conditioning. You don't find many air-conditioned houses in Scotland.

    • But a house in Europe does not consume 10kWh per day ... that would be a quite generous "standard".

    • by klubar ( 591384 )

      While we are nit picking the posting, did any else notice the mixed unit usage of "football pitches" and miles?

      • If you're pitching a football, you're still not going to throw it past the backstop. It seems like the same distance as if you just pitched a baseball?

        Maybe they should go back to measuring using football or soccer fields.

    • I really need to know how many furlongs per fortnight those 806 Leafs can go.
    • I rather they just go with kWH, MWH, or standard units.

      Powering "x" amount of Nissan Leafs as a unit of measurement is about as pointless as powering "x" number of houses. Those numbers can vary easily. Even using a beer as a unit of a temporal measurement ("This is a three beer job.") is more accurate than measuring via homes/Leafs.

    • by AmiMoJo ( 196126 )

      Quantifying a battery by how many homes it can power or how far it could take a car isn't a very useful metric. Batteries are not there to supply power, they are there to smooth output from wind farms and to respond to sudden surges in demand that are traditionally very expensive.

      Unfortunately they don't give a figure for the output of the wind turbines it is connected to.

      • by rtb61 ( 674572 )

        When it comes to battery design, which is smarter, to install at smaller battery at every home, so they can add in wind solar and for example gas turbine electricity (considering a gas heater, would use the same gas as a gas turbine and as a turbine, add in a generator and free electricity with your heat) or a big battery in a rural location. Which is more efficient in delivery over the long run, which provides localised back up energy, of the highest possible quality (the grid could be disrupted locking of

  • There should be no shortage of pumped hydro solutions, Scotland has plenty of rain and gradients to take advantage of.

    • by gweihir ( 88907 ) on Monday June 10, 2019 @01:30PM (#58740426)

      Pumped hydro is slow. It is a good choice for base-load. Batteries are very fast. They are a good choice to improve grid stability.
      Also, pumped hydro needs pretty stable power to pump. Batteries can easily take in highly fluctuation power.

      Any other questions?

      • Pumped storage is not slow.
        It reacts in 10th of a second.

        No idea if you belong to the crowd who does not know what base load is, but a pumped storage plant is either balancing power or reserve power, and not base load.

        • Pumping the water back up to the upper reservoir is slow, however.

        • but a pumped storage plant is either balancing power or reserve power, and not base load.

          That's today, when they're few and far between. If there's many more of them, they might ultimately contribute to base load if necessary.

          • When we have that situation (in germany we are approaching it) the term "base load" will be obsolet.

            • by gweihir ( 88907 )

              When we have that situation (in germany we are approaching it) the term "base load" will be obsolet.

              And more clueless nonsense. What will instead happen is that things will shift in the time-dimension and the terms will be kept.

              • No, the term will not be kept.
                The term is only relevant when you actually have "base load plants" that run 365/24 with close to macimum capacity. As we are losing most of those plants already and are replacing them with wind, the term is useless. At least regarding grid management.

                It of course will stay to be a "mark" on a graph, perhaps for educational purpose or reference. E.g. base load in France is close to 70% of peak. In Germany it is more around the 45% - 50% mark.

          • by gweihir ( 88907 )

            Thanks. And that is the idea. As soon as you are putting this into the context of not always available primary power, the slow storage (and pumped is that in comparison to batteries) becomes the base load supplier.

            • Scotland should have good conditions [nationalmap.gov.au] for pumped storage. (Navigate to Scotland and turn on the data sets on the left; for some reasons, a permalink to the position of Scotland doesn't work for me.)
              • The South Australian use is to stabilize the gird on a minute by minute basis. Things like keeping it all in phase. It works well and is profitable. But it is NOT for any substantial energy storage.

                Batteries are ridiculously expensive for any longer term storage. They would have to halve and halve again to be remotely viable.

                Pumped hydro is an old and proven technology. Not sexy, but it just works. Provided you are willing to have dam up a hill somewhere.

                • This is not about Australia, though, but rather about the potential in Scotland (being the topic of TFA). It's just that Australians did a global study of pumped storage potential recently, with a public result browser.
                • by gweihir ( 88907 )

                  Batteries are a new technology. There is still a lot of room for improvement. Also keep in mind that these are basically car batteries, i.e. optimized for size and weight, both of which are pretty immaterial in grid applications. That these are viable in any role at all in the grid is quite impressive.

                  One source of batteries for longer-term storage (probably still intra-day) is used car batteries. There are not enough of those around today, but if made with a bit of foresight, while these batteries become n

            • For some reason, the permalink to Scotland [nationalmap.gov.au] seems to work better in Firefox, where it doesn't try to do a virtual globe for me like it does in Chromium, so perhaps try that.
        • by gweihir ( 88907 )

          You continue to be full of it and clueless. Pathetic. Here is an actual source, refer to Table 1:
          http://www.ucdenver.edu/facult... [ucdenver.edu]
          Pumped storage is fast compared to the other options, but it is still in the minute range for load-changes. Heavy spinning parts with mass, you know. I assume you have heard of the concept?

          Of course, the load types are grossly simplified for the purpose of the answer. Quite obviously. And you are either terminally stupid, or you s

          • by AHuxley ( 892839 )
            The problem is the use of more solar and wind.
            That brings in the need for a battery.
            Pumped hydro works well but the wind and solar changed the energy use.
            A big battery is now needed to hide what wind and solar did.
            When the wind changes. The sun is not up as expected.
            The battery will then make it all seem ok again.
            With the new power prices to pay back that battery upgrade.
          • The Dinorwig [wikipedia.org] pumped storage station can go from standstill to supplying 1.8 GW in 75 seconds. If the turbines are spun up beforehand using compressed air, it can be done in 16 seconds. That's not quite instantaneous, but a lot faster than 5 minutes. All you need to do is adjust one valve (albeit a large one), so the 3-5 minutes from the study seem on the high side. Unfortunately I can't find the source for the table in the study you linked: it's missing from the list of references.

        • Where did you get that figure from for pumped hydro? No large diameter valve can open in a tenth of a second, plus you have inertia as the turbine spins up.
      • Pumped hydro is slow.

        Even if it were, changes in wind or sun averaged across Scotland are not fast.

      • by psavo ( 162634 )

        Batteries also tend to release energy (total Wh) as a fraction of amperage placed on them. The lower the amperage the more they will release. So high spikes will only be able to extract part of charge that a lower constant load would.

    • You need more than rain and gradients. You need a catchment at the top.

      Just look at a topo map of the highlands. You'd need the world's largest dam, twice, just to build a single small hydro power station. And the more rain you have, the less you would benefit from pumping.

      For pumped hydro you want a valley with a large volume and a small opening at one end. You certainly don't want the Scottish highlands with a long skinny valley that gets wider at both ends.

      If you want to take advantage of those gradients

    • by AHuxley ( 892839 )
      Pumped hydro worked in the past. When energy use was constant and had set times.
      The use of wind and solar bring rapid changes to how power is used.
      The advantage of wind and solar is that someone can now sell a big battery.
  • You don't need a lot of excess capacity, as the combination of solar, wind, and tidal in Scotland gives you a fairly decent energy profile, so you don't need nearly as much shaping that gas used to provide, and as we all know, you can literally recharge even Lithium batteries in about 80 percent of the alkaline lakes, for much lower costs than price spike surges in salts.

    Another approach is the use of flywheels for dock cranes for ocean vessel loading and unloading.

  • What's the point of being able to store an hour's output? If wind is slow, the reserves will be depleted long before it gets windy again.
    • Quickly ballancing out demand changes. Instead of using a gas turbine, you use the battery.
      Has nothing to do with storing for the time "when there is no wind".

      • by AHuxley ( 892839 )
        Re "Instead of using a gas turbine, you use the battery"
        The battery only lasts a short time to cover for the problem.
        Then an actual way to generate power is needed.
        The battery covers for the loss of wind/solar.
        The real power generation starts.
    • by gtall ( 79522 )

      That would be a good point, but only if you ignore that it is rarely non-windy everywhere. Dispersal of turbines makes a difference...unless your view of turbines are those quaint windmills powering well-pumps on the Great Plains.

    • It's not an hour's output of anything in particular, just their butchering of the units. They state it's a 50MW battery that would take an hour to charge, what they mean is it's a 50MWh battery.
    • by AHuxley ( 892839 )
      The hour the network needs to spin up actual power generation again.
      When the sun stops been as sunny as expected.
      The wind gets too fast/slow/stops.
      • by Jaime2 ( 824950 )
        It's already well known when a wind farm is going to stop producing. Weather forecasting has been good enough to say "it's going to be calm today" for quite a while now. It's not like the wind stops unexpectedly and there is a need for a stop-gap power source while other power generation sources scramble to get on line.
  • I wonder if, say, 2000 nissan leafs could be purchased, retro-fitted with tricked out charge controllers and power connectors, and sold at half price to the locals as a "distributed battery" Along with some T&Cs that say they have to be left plugged in to charge at least 12 hours a day and might be tapped for on-demand power.
  • It was bad enough when we started using Jumbo Jets as a measure of distance and weight but now we are using Nissian Leafs as a measure of energy? What SI unit is next?

    I guess if the Nissian Leaf is the new international standard the USA will go it alone and use the Tesla Model 3 as their standard for energy measurement?
  • by seoras ( 147590 ) on Monday June 10, 2019 @03:50PM (#58741344)

    On the A85 road to Oban, in Scotland, you can pull over at Cruachan [google.co.uk] and visit the Cruachan Power Station [wikipedia.org] which has a visitors centre.
    Built between 1959 and 1965 it "uses cheap off-peak electricity generated at night to pump water to the higher reservoir, which can then be released during the day to provide power as necessary".
    It's a hydro power station that pumps the water back up into the reservoir to store power. 440MW of it.
    It cost £24.5million (then) and 36 lives to construct.
    So a football pitch sized warehouse full of batteries sounds like progress to me, even if only 50MW.

    • Check your units. FTFA .......has a capacity of 7.1 GWh.

      And the big battery has a capacity of 0.05GWh

      So Cruachan Dam is 142 TIMES more capacity

      • by seoras ( 147590 )

        I did. You obviously didn't. The Guardian article only states the power (50MW) so for comparison I only quoted Cruachan's power, not energy, of 440MW.
        Cruachan has an energy capacity of 7.1GWh.
        Here's a good article [energylens.com] to help you understand the difference @SteveAstro

    • by AHuxley ( 892839 )
      The problem that wind and solar use created is that the grid needs power quickly.
      To cover for that problem a big betters is needed.
      When the wind stops. The wind is too fast. The wind is too slow.
      The sun is not working as well as expected for solar.
      Hydro that can pump worked for decades.
      Wind and solar is now an added complex new problem that needs a big battery to make work.
  • I think there's a lovely golf course to put it on.
  • The company will connect an industrial-scale battery, the size of half a football pitch

    What's that in yards/meters?

    could release enough electricity over an hour to fully charge 806 Nissan Leaf vehicles over a total of 182,000 miles

    What's that in amp-hours?

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