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Power Transportation United States

Nevada Startup Stores Energy With Trains (fortune.com) 324

An anonymous reader writes: Nevada's Bureau of Land Management has granted a land lease to a $55 million project by Advanced Rail Energy Storage, which "proposes to use excess off-peak energy to push a heavily-loaded train up a grade," according to Fortune. "Then, when the grid needs that energy back, the cars will be rolled back down the slope...that return trip will generate energy and put it back on the grid."

The company claims its solution is about 50% cheaper than other storage technologies, according to Fortune, and boasts an 80% efficency in energy reclamation, "similar to or slightly above typical hydro-storage efficiency." Citing Tesla's factory, the magazine callsthe project "further evidence for Nevadaâ(TM)s emergence as a leading region for innovative transportation and energy projects."

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Nevada Startup Stores Energy With Trains

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  • When I was a kid... (Score:5, Interesting)

    by 110010001000 ( 697113 ) on Monday May 23, 2016 @06:36AM (#52163507) Homepage Journal
    When I was a kid I always wondered by we couldn't store the cold air in boxes in the winter and then use it in the summer to cool us off. I was a dumb kid.
    • by Anonymous Coward

      Not necessarily a bad idea. How about this? A lot of your excess wind power during the summer comes at night when it's cool, provided your turbines are tall enough. In many places the winds are stronger during the winter. That's definitely true in the central United States. What if you used that energy to compress air and store it? Then let it reach temperature equilibrium with its surroundings? Then uncompress the air and circulate it when it's hot. The ideal gas law dictates that it will cool as it's depr

    • by necro81 ( 917438 ) on Monday May 23, 2016 @07:52AM (#52163853) Journal
      Actually, storing cold is an entirely viable strategy. Back in the 1800s, ice would be harvested from frozen ponds in New England, then packed in sawdust and stored in warehouses. That ice was later shipped to many place - the Carribean, the American West, even to India. Keeping ice cold and frozen is just a matter of proper insulation.

      More recently, there are plenty of sizeable buildings that use ice storage as part of their HVAC system. During the night, when ambient temperatures are colder, building loads are minimized, and electricity is cheap, power is used to create tons of ice. The ice is then used to cool the building the following day.
      • Re: (Score:2, Interesting)

        by Anonymous Coward

        We actually store truckloads of snow every winter in Finland, cover it with sawdust and wood chippings and then use it for early cross-country skiing in the fall. About half of the snow has melted during the summer.

      • by RicktheBrick ( 588466 ) on Monday May 23, 2016 @09:09AM (#52164243)

        When I go to grocery store to pick up soda, I am always amazed by the fact that the soda is room temperature. More than half of the year the soda could be cold just by drawing in some of the cold air that exist all the time for 6 months here in Michigan. I am amazed by the mountains of snow that are created in every parking lot. The snow will be there until the sun melts them. Yet there are a huge amount of freezers using electricity to keep food cool. The same goes for the refrigerator in my home. I have forced air gas furnace. It has a fan to distribute the air. All it would need is a way to draw in outside air in the cool summer nights here in Michigan to cool down my house. It would have to be smart enough to know when the outside air is cool enough to cool down the house. Take today for instance the sun will heat up my attic to about 85 degrees and the house to around 75 degrees. My bedroom will remain in the 70's well after the time I wish to sleep making it difficult to get to sleep. A few hours ago it was in the upper 40's or lower 50's but none of the cold air was used to cool down anything that I could use during the day.

    • by mark_reh ( 2015546 ) on Monday May 23, 2016 @08:13AM (#52163953) Journal

      This is sort of like storing energy in a vacuum vs a pressurized vessel. The energy stored in a vacuum is very limited (you can only go to zero pressure), while you can make a pressure vessel that can store a lot more energy in the same volume because the pressure is unlimited up to the point of condensing the gas.

      There's a practical limit to how cold you can make things, and therefore the energy you can store that way, but you can get a lot of things super hot (liquid sodium, for example) and store much more energy in the same volume.

      Maximizing energy/volume is what it's all about economically, because cost is directly proportional to volume.

    • by Anonymous Coward on Monday May 23, 2016 @08:30AM (#52164043)

      Its not completely idiotic, in fact I think they do something similar in Japan. Some buildings have concrete storage boxes burred underground where during winter snow is dumped. When summer rolls around the snow is used to cool the building for a few months out of the summer until the snow melts. It doesn't completely cover the cooling requirements but it does take a big bite out of it and it also gives them a place to shove some of their snow that's out of the way.

    • by CanadianMacFan ( 1900244 ) on Monday May 23, 2016 @08:40AM (#52164089)

      There are air conditioning systems that make ice during off peak electricity hours and then use that ice to cool air during the peak hours. https://en.wikipedia.org/wiki/... [wikipedia.org]

      Personally I wish more places would use ground source heat pumps (GSHP) though I understand that they don't because the systems are expensive. That's why I don't have one. When it came to replace my furnace and A/C last year I looked into a GSHP and it was about 5 times the price of a pretty good natural gas furnace (98%+ efficient) and a SEER 16 A/C. Instead of storing the cold you are storing the heat. In the summer a normal central A/C just dumps the heat into the air and gets less efficient the hotter it is. A GSHP will transfer the heat into the ground where it is kept and it doesn't matter how warm it is outside. Then in the winter the GSHP will take the heat that was saved in the summer, plus some of the heat that was already there, and transfer it back into the building to warm it up.

    • No, that's a completely valid idea - in fact, it's what people actually did before refrigeration existed to store frozen fish:

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

  • by sjbe ( 173966 ) on Monday May 23, 2016 @06:37AM (#52163521)

    Citing Tesla's factory, the magazine callsthe project "further evidence for Nevadaâ(TM)s emergence as a leading region for innovative transportation and energy projects."

    And the existence of Las Vegas is evidence for Nevada as a leading region for innovations in ways to needlessly waste energy and resources.

    • "Need" is a matter of opinion.
      • "Need" is a matter of opinion.

        Incorrect. "Want" is a matter of opinion. "Need" is not optional by definition. Sometimes people confuse the needs with wants but they are not the same thing.

    • And the existence of Las Vegas is evidence for Nevada as a leading region for innovations in ways to needlessly waste energy and resources.

      It does a marvelously efficient job of extracting billions of dollars from Los Angeles...

  • I read about this system and it seems interesting and it makes me wonder if there are any other forays into mechanical storage of energy, such as some kind of larger scale clockwork system of raised weights.

    A lot of the locations able to generate power surpluses are in remote regions with poor access to the geography and water for pumped hydro, but generally have a lot of square footage that could be used to house some kind of mechanical storage system.

    • by Troyusrex ( 2446430 ) on Monday May 23, 2016 @06:49AM (#52163575)
      There are some very interesting things going on with storing mechanical energy using Flywheels [wikipedia.org]. It isn't quite the same concept but takes a lot less space than moving a large train uphill.
      • Re: (Score:3, Interesting)

        by Anonymous Coward

        I recall reading about a huge cutting/shredding blade that weighed (a wild guess) between 80-200 metric tons and took over 8 hours to stop when it was shut down for maintenance. I imagine flywheels could indeed be a space-conserving and *extremely simple* solution for storing energy when there's abundant energy laying around the grids.

        The output of a flywheel generator could be also easily evened out using gears and/or variable frequency drives. When the flywheel gradually starts losing speed, the gears and

        • Hearing the "8 to 12 hours to stop" reminds me of MRIs and their superconducting (lossless) magnets that take a really long time to start. There should be some kind of low loss energy storage potential in superconducting electromagnets. Lots of problems there, but moving parts (in the major energy pathways) isn't one of them.

          • Yeh, I'm not convinced there's energy storage potential when you have to use massive amounts of energy to keep the superconductor cool.

      • I remember reading hopeful words about that in the Sixties...perhaps it's finally getting off the dime.

      • by necro81 ( 917438 ) on Monday May 23, 2016 @07:59AM (#52163899) Journal
        Beacon Power [beaconpower.com] tried to commercialize [wikipedia.org] that concept 5-10 years ago. Their flywheels were cylinders of spun carbon fiber, in vacuum chambers, and levitated on magnetic bearings. These were sunk into concrete silos - in case any one of them flew apart. The technology was used not so much for bulk storage, but rather for peak-shaving and arbitrage.

        The company went bankrupt a couple of years ago after building their first 20 MW storage plant. They're now owned by a private equity firm and making another go of it, so there's hope yet.
        • by dbIII ( 701233 )

          The company went bankrupt a couple of years ago after building their first 20 MW storage plant

          A power station I worked at had a backup generator that size run by an engine out of a British fighter jet from the 1950s. Not big but it could run conveyors and coal crushers to get a coal fired unit up and running from a cold start. A pump storage plant I spent a day working at had two 250MW turbines that could run until the storage dam was dry. Not big for hydro or pump storage.
          Twenty megawatts is tiny.
          The Bo

    • The world is moving towards more closely matching electricity supply to daily demand so hopefully we'll need less of these methods of shifting off peak power to peak power. Without exception they are all very lossy, some like this a lot more lossy than others. Using the power to actually do something useful instead of lossy storage, or not using resources to generate the unneeded offpeak power at all is a better idea.
      If it's an ore train in no hurry moving only at night when plenty of power is available t
    • by jcdr ( 178250 )

      The big advantage of hydro is that the useful mass cost almost nothing.

      I live in a region that have many hydroelectric infrastructures, including the Grande Dixence Dam https://en.wikipedia.org/wiki/... [wikipedia.org] that store 400'000'000m3 of fresh water so essentially the same number for his mass in ton. Now try to replace this mass with some cheap metal like iron that is about 50 USD/ton and you have to pay about 20'000'000'000 USD to get the same mass alone.

      This is a very big investment, not counting the global iron

  • Cliches (Score:5, Funny)

    by pr0t0 ( 216378 ) on Monday May 23, 2016 @06:42AM (#52163545)

    I can see this project going off the rails.

  • by turkeydance ( 1266624 ) on Monday May 23, 2016 @06:46AM (#52163555)
    Sisyphus
  • Sisyphus (Score:4, Funny)

    by Space ( 13455 ) on Monday May 23, 2016 @06:50AM (#52163581) Homepage

    They should call it project Sisyphus [wikipedia.org].

  • by mccalli ( 323026 ) on Monday May 23, 2016 @07:00AM (#52163641) Homepage
    Sounds like a variant of Electric Mountain [electricmountain.co.uk] in the UK. The same thing is done, only instead of moving trains up the hill they move water instead. There's more in the Wikipedia article [wikipedia.org] - essentially though, this idea works fine.
  • by swm ( 171547 ) <swmcd@world.std.com> on Monday May 23, 2016 @07:02AM (#52163649) Homepage

    Rube Goldberg...call for Mr. Rube Goldberg...

  • by OzPeter ( 195038 ) on Monday May 23, 2016 @07:07AM (#52163669)

    Grid Scale Energy Storage [aresnorthamerica.com] (complete with requisite animation)

    It looks interesting, especially for places in the West of the US where water access is slowly becoming problematic. On the East coast (where there is a lot more available water) there is the Bath County Pumped Storage Station [wikipedia.org] which has 3GW generating capacity.

  • Bill Nye had a similar idea that involved digging a large hole and raising a large weight with solar energy, then reclaiming it by letting gravity do the work. It's basically the same principle as weight driven clocks.

    There's really no innovation here - they've just made the entire thing larger. we've been storing energy like this even before batteries were a thing.

    • They're both fairly pointless ideas now that we have the technology to build magnetically levitated flywheels in vacuum vessels. They have very low loss, they take up very little power, they cost very little to build, they store fairly enormous quantities of energy, and they are very efficient.

      • They're both fairly pointless ideas now that we have the technology to build magnetically levitated flywheels in vacuum vessels. They have very low loss, they take up very little power, they cost very little to build, they store fairly enormous quantities of energy, and they are very efficient.

        And yet nobody has found an economically viable way to make this miraculous device and deploy it at industrial scale. Perhaps they aren't quite everything you are making them out to be just yet?

        Seriously the idea of large flywheels to store energy has logic to it and has been proven at smaller scales. We're just not quite there yet for industrial scale use. Maybe soon hopefully.

        • And yet nobody has found an economically viable way to make this miraculous device and deploy it at industrial scale.

          False [slashdot.org].

  • Bill Nye proposes a similar scheme, using giant pistons lifting weight instead of driving a train uphill.
    https://www.youtube.com/watch?... [youtube.com] starting at 7:40.

  • To me it seems a bit of a time limited system. If energy is reclaimed by rolling the train down hill there are two options: Either the train has to go really slow or the ramp has to be really long if you want to reclaim that energy in a reasonable long time. I can't imagine that let's say 15 minutes is enough time to catch up with top demand, a train rolling for 15 minutes at some speed needs a long track and thus a lot of space. If the speed were 15 km/h you would need a ramp of almost 4 km, an hour would

    • by OzPeter ( 195038 )

      As a poster before me already mentioned, flywheels could do the same trick, take less space and are likely more efficiënt.

      On the other hand this system stores potential energy whereas a flywheel stores kinetic energy - each type of system has it's benefits and drawbacks.

      For example it is possible to fill this train system up with potential energy and then shut it completely down for maintenance. You can't do that with a flywheel system.

    • It's not a train like you normally see on the tracks while going for a drive such as an Amtrack or a freight train. There are a large number of independently controlled flatbed cars on a series of parallel tracks. Yes the tracks are still long. When you have excess energy one or more cars are moved towards the top in order to take up the electricity. When electricity is required one or more cars can be send down the tracks using regenerative braking to create electricity. If a car reaches the bottom and e

  • Where I live we pump water up a mountain into a lake to store energy. Seems to me a simpler solution than using trains.

    I wouldn't be surprised if water would be slightly less efficient due to pumps and turbines having higher loss factor and due to water evaporating. But how many trains, tracks and difference in height would you need to have something equivalent to a small lake high up a mountain?

    • The problem with pumped water storage is that you need to have a good supply of water, a reservoir above, a reservoir below, and a proper height differential between the two reservoirs. These severely limit the number of places in which you can place such a system. (The reservoir below may not always be a reservoir if there is a source of water large enough, such as a river, always available when the system is running.)

      With this system all you really need is some relatively smooth ground running at a grade

  • Not going to work well anyplace without mountains.

  • I'd be curious how much space such an installation might require and how easy it is to add capacity. I imagine adding more cars or putting more weight per car is probably pretty cheap in comparison to other options.

    I wonder what argument NIMBYs will to try to shitcan it some places.

    • I'd be curious how much space such an installation might require and how easy it is to add capacity. I imagine adding more cars or putting more weight per car is probably pretty cheap in comparison to other options.

      Probably not. The cars would have to be designed at a maximum weight and running them below that specified weight would be a waste of capacity BECAUSE it would be so easy to load those cars with, say, rocks. To load the same volume with more mass, you'd probably need to use cast metal bars, which would cost much more than rocks and would probably eat the profit from the amount of stored energy.

      And putting more weight on the cars than originally designed for would result in a completly new fleet of cars that

    • The NIMBYs will say it will ruin the view. It's a big argument some people in Europe have against windmills. The big thing in North America against windmills is the so-called health problems which don't exist.

      I'd just tell then it's either this or a nuclear plant. Your choice.

  • A thousand tonne train of railcars pulled up a slope 100 metres in height, assuming no losses (spherical cow assumptions here but bear with me) will require Mass x Gravity x Height = 1 billion joules = 270 kWhr which at commercial rates for electricity is worth maybe $20 or $30 US. That's not a lot of energy storage given the capital cost of track and equipment and recurring maintenance costs etc.

  • Essentially what is already done already.

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

    --Q

  • Two problems I see with this: 1. Safety. If the grid goes away, this thing will have no reaction torque to apply, and it ain't gunna stop in a hurry. 2. Scale. A quick look at Wikipedia suggests that the heaviest goods trains in use anywhere are about 40,000 t. Suppose you have a mountain where you can raise that 1,000m. The energy involved is roughly 40,000 * 1,000 * 10 * 1,000 = 4e+11 J. That's 4e+11 / 3.6e+9 = 111 MWHr. It's not small cheese, but it's also not national grid scale. As I sit at my

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