Gravity Energy Storage. Who's right and who's wrong?

Don't forget a guy from silicon valley.

Don't forget to add: "made by *clever* engineer grad students start-up"!! It works people, they confirm it.

You noticed that right..

It sounds like something as simple as closing the system inside of a silo would have solved 99% of the "debunking" that went on about it.

@@Belthazar1113 As long as that 100% is weather related concerns, possibly. Otherwise, no.
Pop quiz! What's the energy potential stored in a concrete block at the bottom of a stack?

Cheers Brendan. Much appreciated.

@@JustHaveaThink 🎓

You know he takes this seriously, and has an open mind, and just not gullible, as he takes in account debunker channel input. Much more credible than your typical Tesla fan boy.

@@Freja_Solstheim There is a reason they didn't compare it to hydro. this is so laughable tiny (24.4MWh), nobody would consider to build a hydro this tiny. LCOS scale mostly with size (especially for hydro).
Actual average Data from Lazard (same source the imperial college of London uses sometimes):
compressed air, pumped hydro, and lithium ion batteries are $128/MWh, $175/MWh, and $414/MWh
But that's real data including the cost overrun during construction etc. Meanwhile the calculated number for the "new" tech is the estimate of the enterprise proposing it.
I didn't find this Study, but another one for gravitational storage: heindl-energy.com/wp-content/uploads/2018/10/LCOS_GravityStorage-II-Okt-2018.pdf
Something a bit more serious, as the stored values are of significance (it's basically a hydro which could be built anywhere, again numbers are estimate (probably optimistic ones)).
Page 8 also reveals why we don't just make it all compressed air: compared it's rather inefficient with only 42% of the energy recovered.

@@JustHaveaThink just been reading an article about algae being used in glass panels on buildings which sounds interesting.
>Beautifully designed, energy-generating bio-panels that suck up carbon dioxide and pump out biomass for use as fuel or fertilizer - that's the idea behind Mexican startup Greenfluidics and its nanotech-enhanced microalgae bioreactor building panels.

Yes and it has an impressive effenciency if build big enough.

And you could probably build hundreds of water towers for the cost of one building full of concrete blocks.

Head loss (friction) in the pipes is the problem with hydro. Pulleys are much more efficient.

It obviously has geographical issues though, a lot of countries have nowhere else to put any more hydroelectricity, england for one example really, we dont really have anywhere else to put them, an alternate way of doing what hydro can do is absolutely something worth atleast looking into, since were going to need it for a green revolution.

@@darrennew8211 the problem is you cannot build towers big enough to be very effective. You need a huge amount of water and height to do pimped hydro.

Yup .. and water flows all by itself so you don’t need to stack it. No question water for long-term storage and batteries for short term is where this is going. Large battery buyers are buying under $150/kWh today, CATL anticipates being under $50/kWh this year for (Sodium batteries if memory serves) .. and we are no where near the limit on battery/performance/price.

Don't forget that installation of the weights allows that the gravity battery can start out in the "Fully charged" position. As long as the modular design has enough modules and energy collection equipment, there is a chance that the gravity battery can keep up with demand. I think it's important to think of the gravity battery as a secondary source of energy when demand requires it's use, or more or less a supplement to existing infrastructure.

@@davidleaman6801 and I think you are and idiot, Sir.

100x100x20 seems doable...

@@solarguy4850 Water is problematic because it's a liquid, it's harder to contain than solids, it can evaporate and couses corrosion, so imo pumped hydro is best built using natural terrain. Good boon for gravity storage is that it doesn't lose capacity over the years, downside being moving parts but pumped hydro has the same problem albiet smaller

Resistance is futile...

😂

I tried to find this but was unsuccessful. I did find out that there are 500,000 abandoned hardrock mines in the USA. But that doesn't give much further information on how suitable for this project they would be. But 500k is a pretty big number - even if a fraction of these are suitable that's still a lot of sites. I also don't think hardrock mines includes coal mines.

Using a water/air tight shaft lining the water intrusion point become moot. As in my mind Gravitricity would want to keep the shaft as clean and dry as possible. Which means that they would have to use some kind of lining in the drop shaft

It's gonna take a while to get firm numbers, but my findings so far:
Considering the worst-case scenario of a reinforced-concrete-lined vertical borehole gravity energy storage system in, say, the Amazon rainforest where the ground is always saturated; seepage rate across a given section of the inevitably-porous concrete is ((groundwater head pressure) -(viscous back-pressure))•(area of section); taking the integral of this function with respect to area will give us a flow rate value in units of volume per unit time. Due to this, out-pumping costs scale with the square of borehole depth, so there is definitely a limit to scalability *in certain biomes*

@@charlesmartin1972 Heavy water seepage just provides an opportunity to build it as pumped storage instead, with the lower reservoir at the bottom of the hole.
Shaft cleanliness seems a non-issue with enough slippage space between the weight and the walls. Remember that whomever used the hole for mining was already lifting things and people in and out of the hole. Graviticity doesn't need the hole to be safe for humans and don't need the various side shafts (all except construction and maintenance work of cause). A thin (2 inch) concrete lining like in sewer pipes and manholes would be enough for a hole in regular ground conditions rather than mine shafts.
500m depth could also be a repurposed elevator shaft in an economically failed skyscraper (originally built at prohibitive cost) or an intentional design feature in new skyscrapers where most of the building is making rent income to fund everything.

@@johndododoe1411 the volume occupied by free water represents a loss of gravitational potential energy available to the weights. Also, seepage through the walls is not passing over a turbine and is thus a net efficiency loss

Most Mines keep a certain area clear of water to make sure the shaft doesn't collapse. And those pumps will run indefinetly.

As you said, you need constant pumping to keep the water out.
Pumped hydro can't work if the bottom lake keeps filling on it's own

@@zbarba In most cases, the speed it fills at is slow enough to not be a problem. The capacity is generally very, very large. It would likely be much larger than whatever the surface area tank or lake would be.

@@chuckoneill2023 I find that hard to believe. You get a lot of volume from a reservoir since it is roughly cube or cone shaped. Meanwhile a mineshaft is by design narrow and windy.

@@ruukinen Actually, I think you're confusing a mine with a cave or cavern. Mine shafts are generally cut as straight as possible, for ease of removing the ore.
In any case, however straight or crooked the shafts are has little impact on the flow of water.
I toured an old below ground iron mine a few years ago. The void left behind by mining out a large deposit was basically the size of a cathedral.

It is also not very convincing that they present their (final) idea and probably pitch for money without having built a reasonable prototype to test their theory. After "working" on whatever and getting told that the idea will not work, they completely change their concept.

@@Kiboxxx Yes! Their idea crumbled under basic scrutiny (though not before wasting a lot of money) but it's a good idea to never trust a company that only ever presents CGI concepts, proof of concept isn't just important but vital.

But just wait until the rock monsters see that iron ore coming down. The Enterprise may have to tractor beam the ore up before they nibble on it! 🚀

discarded minshafts make for unsexy powerpoint when marketing to investors

@ Evil Otto
I disagree. Discarded mineshaft areas are less likely to draw the protest crowds when a company seeks to do something there.

Maybe they plan to operate in flooded holes.

Good point. That natural inflow of water takes off a slice of the potential energy to be stored.

@ Dan Tronics
I don’t think energy storage systems of any sort need to be near where demand is. They just need to be somewhere along the grid to take in excess power and feed it back into the grid as needed.

@@janwinders9702 not likely. weight in water is considerably less than in air. Also there will be significant hydraulic drag both lowering and raising the weight

I don't know, find a spot on a hill in the Western US, pump the water up/out let it run down hill. Recover some electric cost with hydro generation. If there is a gully and Hill at the bottom, you will get the water to return underground away from your project and start to turn the desert into grassland.

Also concrete is only twice as dense as water so I bet you could store almost the same energy without all that equipment in plain water... maybe salty water, water isn't scarse, drinkable water is, if you keep it close mantainance would be minimal, you will only need to fill it once, keeping it close avoids evaporation

@@ratgr Water is scarse in some places around the world but not having to transport rock to a location where it is avalible seems a logical option. The perfect combination in my view would be desert based solar panel farm and sand filled weights. Why make concrete if it does not have to be structual.

@@lenrichardson7349 The problem with sand is its corrosiveness, its not a fluid so you cant really pump it normally but you could use a screw pump, It will need more manteinance, and some other mechanical help to avoid dunes, before you recomend sand bags that makes it worse, you'll need some kind of computerized complex mechanical mechanism and wouldn't be able to use the mine in its entirety.
Water can be transported from the closest source, either pumped or water trucks, its mostly a one time cost, you only have to make the walls impermiable and the loses should be small, you dont even need this water to be fresh water, you could use salty water, very few places in the world are both far away from a water source and close to a population.

@@aaronlockey6429 the crane-managed block tower idea also had an expensive working prototype, although not to full scale. They had some multi crane tower and some barrels filled with concrete. The new design/3D-animation-concept doesn't have anything real AFAIK, although apparently they have a contract with China somehow. Ironically the closest thing to a prototype for that would be the prototype for gravitricity, specially if they gave up the nonsense of horizontal transport of the weights for no reason. Then it would at least look somewhat credible, although to me it wouldn't be clear whether the return on investment is really superior to just pump-hydro even if in ridiculously small sizes for pump hydro. Like filling the mines themselves with water and pumping it to a ground-level pool. Maybe one could hybridize the water supply system with something like that to some degree, as it has to be pumped up at some point, and has to go down.

I think it's fair to say the energy storage, just like energy production for a sustainable future has to be a multi-faceted approach, often depending on geography and facilities. Just like you wouldn't put solar farms in the high arctic or antarctic or wind farms in a calm area, you'd look at the geography of an area to see what energy storage would be most efficient in each case. If we did things based on studies, data, scientific approach to problem solving for maximum efficiency we could crack the code for 100% renewable energy worldwide, with adequate storage.

There's a lot more issues with that concept. While the principle is tried and proven as a warehouse system, there has never been a setup like this as far as I am aware with handling weights anywhere near this.

There is also the issue of the embedded energy in the construction.

Not just lost energy... Wayyy too many potential points of failure. A weight suspended on a hoist could be deployed even if there was no energy in the system... Like during a total outtage. But a giant warehouse of weights stored in computer-controlled conveyances by definition requires inputs to operate, so it could never be used as emergency power during outtages. And is just flat out going to break down at some point.

@@patreekotime4578 I can't believe I'm defending this daft design, but all power stations require some power to operate. In this case you would just need to have enough weights ready to drop to ensure there was power to move the weights sideways.

The engineers should be able to design the system in such a way that the blocks that have to travel laterally do that on a small slope configuration ,to reach their destination; by equipping the blocks with temporary rollers, or design the transport railing system with permanent ones.

Yes, and you could store more if the mass was stored at the top and bottom, so one rail car could carry multiple lots of rock, rather than a single lot as in this design.
However both pale when compared to pumped hydro. Snowy 2 for instance stores 350 GWh. With cheap UHVDC the location of the pumped hydro isn't as critical. Any old mountain by the sea could be pressed into service.

They are building the train cart.energy storage in Nevada. We might see it in 2035.

Remembered seeing that video also. Seems to be easier to install and maintain than either of the two mentioned in this video. And easily scalable also.

In Australia the Fortescue Metals Group is planing a system like that near Port Hedland

You know, that sounds like mines would make a good candidate for pumped hydro... pump the groundwater to the surface on off-peak hours (with a small amount of power used to re-circulate water the seeps back in), then release it through the pumps to and release the water back into the mine and generate power on demand.

@@erininstereo47 well, then you need to store it somewhere, and in a meantime new water come from the ground. So basically more water you have to pump out vs what you could possibly use. I'm not an engineer in this area, it just what come to my mind, probably this company have someone from this area in the team.

Where do you put the water you pump out of the mine?. and how do you stop the empty mine filling with water naturally? if you can solve these then you've invended pumped storage.

@@mralistair737 Creating surface water basins is not expensive per volume at all. In most mine shaft solutions you need solutions to prevent the mines from filling up naturally, through additional pumping of good sealing measures. With heavy block you could indeed have the blocks sink into partially water filled mines, but that would result in complex engineering as well. lifting and lowering a single 50 ton block in a 300 m mine shaft does not give a lot of energy: E=mass*gravity*height=50000*10*300 J = 150 MJ = about = 40 kitchen kettles during 1 hour.

Yeah, exactly. I see this more as covering overnight demand for a solar farm than holding those weights up waiting for a rainy day.

There's more than one kind of storage issue with renewable sources, and wind and solar have different problems. Despite the "OMG WHAT IF THE SUN STOPS SHINING OR THERE'S A VOLCANO OR A METEOR HITS THE EARTH???" nonsense, there's some very regular, quite predictable variation in both output and demand. So if you can compensate for that expected variation, you can turn either wind or solar into a consistent supply that can handle normal day-to-day variations. And those variations don't need nearly as much storage as saving energy so we can not have interruptions while the asteroid dust cloud blots out the Sun for seventeen years or whatever...

Used for grid balancing. for over 100 years en.wikipedia.org/wiki/Pumped-storage_hydroelectricity

Calculate how much mass you would need. It's enormous. Think mountains.

That really depends on the amount of mass in storage. With sufficient mass reserves to account for worst-case scenarios it should be OK. It's not as if the blocks are evaporating or chemically degrading while they sit in storage, so other than the requirement for 'excess' storage area there shouldn't be many downsides.

There is no way to generate of store energy without adverse effects. In the end, our need for energy will outweigh those effects, or we'd need d to do without.

"build a good cable" "cable" in steel wire rope form will not be improving much because it's a field that's been developing more than a century for elevators & cranes. For example, there are 30 factors that determine steel rope life, all well studied. Aramid ("Kevlar") or carbon fibre products could perhaps be developed more though since safety isn't an issue (Aramid was tried for elevators but abandoned when all ropes snapped due to a mistake by engineers during testing).

From my basic understanding, we shouldn't be looking at this in isolation. This is just one way of storing energy that will fill some use cases but not all of them. I believe the future will be a large mix of renewable energy sources and storage (gravity based, flow batteries, thermal salt etc). Combining all of the options will then provide a lot of resilience which will significantly reduce the 'baseload' electricity required from nuclear and gas.

@@timjarrett8777 I agree. But will this cover at least like a bilionth of our storage needs? If not and this is like a humorous curiousity, it's maybe not worth the attention.

@@miroslavhoudek7085 absolutely, but we need to look at scale. BBC report states there are approximately 150000 old mine shafts in the UK. If we assume even 10% of these are appropriate for Gravitricity then that is 15 thousand of these small scale storage options. If we assume 2 MwH per location (which is half of the first storage system they are implementing in North Yorkshire) then that means 2 x 15000 storage, which is 30 gigawatts. I personally would call that a substantial contribution to our energy storage needs.

Have you been watching "Robert Murray-Smith" latest video no. 1604?

@@sailaway8244 no. I saw a video about it on BBC

@@Whyoakdbi ruclips.net/video/9BW5GX05Fko/видео.html

I think he did a video on it 2-3 months ago

I recently saw an article on this.
Interesting idea.
Like this one, I hope it is viable and pans out.

Thank you. I appreciate that.

@@goodcat1982 cost, time and waste, we are facing a £120bn and climbing bill to sort out Sellafield. The French have had to Nationalise EDF because the economics don't stack up. I am not against Nuclear but it has some serious issues that need sorting

Great idea. A variation on the funicular railways that have existed since the 1820's.

but water is free, easy to transport and heavy. and the whole thing can be done with one moving part. huge funiculars have millions of moving parts and youd need to find some niche sites with long steep slopes.

They have (or had) a project in development in California, utilizing the rails on old mining sites. Traction engines were to be used, with concrete weights on cars, controlled by grid software. Back them up the hill to increase stored energy, let them roll down to collect. I think they had already taken it far enough to determine that response times were fast enough for a lot of grid needs, besides just bulk storage. Since they were using existing tracks, installation costs were low. But even if newly constructed, the transmission line install costs would probably be higher than laying the necessary track and setting up the traction engines/ballast cars. Very old tech, but seemed simple, robust, and cost effective.

​@@geoffreycahoon2410 but running railways is really expensive. you'd have to have qualified drivers in each of the trains, (sitting around waiting for peak demand) all the maintenance and checks etc. and old railways are really not that steep.. a traction engine is about 2 megawatts, power output, so call it 1.5mw electricity. Absolute peanuts. that's like $200 an hour, at peak times. if you compare it to wind generation that would be $60/h for that much power. '

@@mralistair737 These rail systems aren't generation systems, they're storage systems. Think of a weight at the end of a tether on a cuckoo clock. You use a generation system to raise the weight, and when the generation system isn't raising the weight, you use gravity to generate electricity. Saying you need a driver to run the weight is like saying you need an elevator operator to run an elevator. It's not complicated. And you can assemble a lot of peanuts, plus improve the efficiency of those individual peanuts.

Based

Comparing the costs of energy storage by the two batteries in question, for the energy measured in kWh, is wrong. Are you referring to a metric ton, when you write, for example, 150 tons?

@@franklins6694
Cost of energy storage has units of money / energy.
I chose $ / kWh
When I write 1ton I mean 1000kg of mass of material

What was the tunnel for? You mean, a hole?

Read "How the Scots Invented the Modern World".

As a scotsman I can assure you there are plenty of BS merchants north of the border, especially when there's a bit of free cash going for research. the fact that someone did something 150 years ago is no predictor of current performance.

I believe Scotland has the highest ratio of patents per capita anywhere in the world.

They could just use Loch Ness (221 m), Loch Morar (310) or other lakes. The north sea could be used (even if water with salt are nasty stuff for any equipment).

@@bknesheim use it for what? Loch ness is 15m above sea level.

Surprisingly there are a LOT of abandoned mines in most areas (I bet there is one within 100 miles of where you live). And even if there isn't, the cost of digging a new shaft is not as expensive as people think. It is certainly less than the cost of putting up a bank of batteries.

Tons of Cobalt mines in the DRC, Nickel in other parts of Africa, coal in the US and Germany.
Honestly, this solution would work better for regions that don't have very much aboveground sea level variation. If aboveground is flat, go underground. The Midwest and Great Plains of the US would be perfect for this, and I'm sure the northern provinces of France/Germany would welcome something like this. The Scandinavian countries would probably love to implement this tech

Electricity can be provided into the grid from anywhere. Even if it is a 1000 miles away.

@@SeeNickView I think the problem will be cost. Using abandoned mines saves a lot.
DR is probably not going to be at the front or even middle of the pack with adoption of these technologies.
France and Germany definitely have the money and will.
I do not know enough about midwest USA with respect to available mines. If they do not have then another storage technology would be more applicable.
Scandanavian countries have the terrain for pumped hydro so no need for this more expensive solution.

When it sounds like a rock grinder switching to 1st you're supposed to say "synchroooooomesh !" to your passenger & grin.

Thanks, will do!

Probably not as oil wells tend to max out at around 3ft diameter and usually more like 18 inch diameter or less and the system seems to expect a 10 ft ish shaft at the small end

@@brianzmek7272 Ah, I didn't know that. Thank you. I'll be honest, science isn't my strong suit. I love learning about it, though.

There's alternatives that use pressurized water; that might be an option. Sorta like pump-storage but in reverse. There might be other reasons why abandoned oil wells don't work though (could be as simple as no useful location).

One problem when using mine shafts is that they fill up with water (often with toxic elements). The pumping of water to keep the mines dry is often a major part of the operational cost and cleaning the water is also a major cost.

@@bknesheim Exactly, plus pumping out the water will cause the water table in that area to drop. The video shows farms surrounding it, I'm sure they wouldn't like their water table dropping and rending their current wells unusable.

This possibly will make tower unstable and prone to collapse during high wind, a special tower need to be built

Something goes wrong with either system and you have to shut both down for repair

People looking to $hit on your idea. I think it's brilliant.

Even through in theory this would work, the amount of energy that you can store in the very narrow shaft will be so little it will not weigh up to the CAPEX and OPEX. There is simply no room for a large, heavy object and the travel is limited as well (compared to mine shafts).

Because once the weight is lifted in that one tower the wind turbine would then be useless… sitting still with blades feathered for possibly days. Not to mention how top-heavy the tower would then be. Of course they could probably disengage and bypass the weight and gear system but gosh all that would be so complex and require so much upkeep.

There is quite a bit of flexibility in this particular system that could keep costs down.
Motors could be of various designs, and with a gear box would not have to be optimized for a particular speed or wide band efficiency (with the exception of very high gear ratios).
Gang style cabling could allow for use of a wide range of cable diameters and grades.
The ballast could be substituted with anything "heavy," even free material from around the job site (sacrificing a bit of energy density depending on specific gravity).
Support structures need to be sufficient, but not standardized.
Etc...
There isn't a "lithium" equivalent commodity to this system that necessarily creates a choke point.
That said, you are 100% correct if this system is deployed as a specific product instead of a general machine concept.

remember these are batteries not generators
so the answer is never
these work on the ends of coal plants too (they would just waste power that way though)
the main benefit of batteries is to make up for lulls caused by lacks in the system (renewables not always being actively useful for generating power)

its all cheap cgi to grift taxpayer and AGW cultist money away.

A vessel full of sand etc sounds better imo, even rocks.

@@hynot9175 I think that's the plan. Build the inital concept prooving plant with concrete, and if the physics/effeciency works out, then use more environmentally friendly heavy loads.

More parallel weights mean more (or bigger) holes more cables and more generator. How could that increase efficiency?
You can see in the animation that they plan to have one hole and one lifting/lowering system but multiple weights.

replace the weight with water, since its a mine shaft you can just dump the water so it takes less energy for winding /raising

@@dantronics1682 - that is hydro electricity.

@@dantronics1682 mines need pumps to drain them, else they flood

ERR why not just use water like for the last 100 years en.wikipedia.org/wiki/Pumped-storage_hydroelectricity

@ Mark
I thought of the ski hill idea as well. I’m wondering about the necessity of rails though. Given enough compacting and a ‘sled’ type design at the top and bottom ends of the weights you could simply slide them up and down the hill. Miners use to ‘rawhide’ loads of ore downhill.

Most mines have a significant power requirement to run machinery, lifts, lights etc.
Most of the basic infrastructure is already there.
Might need some upgrades.

The problem is that people are still thinking about a grid providing energy to customers and talking about grid scale solutions. That makes these problems seem far more complicated and challenging then they will be.
Decentralisation is key here. Of both generation and storage.
The economics are turning against grid based solutions. The grid has to become a management system instead of a delivery system.

Hope you enjoyed it!

I certainly did 😁

I think it might be easier to convert between currencies than from joules to money.

You mean small modular reactors won't be a THING?

@@srvq3101 ha, brilliant, exactly. Managed to fool Boris though didn't it

Just ANOTHER problem with deep storage,THANKS for pointing out, VERY important!

On CBC Radio they call these "Previously enjoyed episodes" (usually The Debaters).

I was also thinking of rails on a mountain slope . Probably more efficient than pumped hydro ...

@@richardstubbs6484 Exactly. Why lower cement blocks, roll the fucker. And to the marathon answer above, A simpler way to say it is every energy storage system is 100% efficient. Because the energy you are putting in is excess energy that the grid doesn't want, so currently it all goes to ground.

I think Energy Vault is claiming in the range of 75 to 80% round-trip energy efficiency, so somewhat comparable to lithium-ion battery systems. However, low round-trip efficiency may not be as bad for an energy storage concept as you are saying. As an example, a large-scale hydrogen electrolysis, storage, and fuel-cell facility e.g. in the middle of Europe could make sense, even though RTEE may only be 35%-40% or thereabouts. Here's the thinking. Wind power and PV power are becoming dirt cheap in capital cost. However they need cheaply scalable energy storage, capable of long storage time periods, to cope with intermittency and long periods of unlucky weather. So a centralized large-scale hydrogen facility could absorb excess power capacity and give 35% of it back potentially much later on. Scaling just involves more hydrogen storage tanks. So you build twice or three times as much wind and solar capacity as you need since it is dirt cheap, and rather than wasting the output as is frequently done now by disconnecting turbines from the grid or idling them, you get 35% of the excess energy back to use later. May very well make economic sense, since there would then never be times when wind farms etc are being paid not to generate.

@@erichawthorne2519 Yes, if you are going to otherwise have to divert power to a shunt and turn it into heat or shut down wind or tidal turbines to reduce supply to match demand, any round trip efficiency is better than nothing. And while the cost of wind and solar is dropping, it isn't nothing. Also different storage systems have different costs per kWh of output power. So as long as the extra generating capacity cost something, and the cost per kWh of storage capacity also varies, the round trip efficiency will always be a key factor in determining the optimum combination of energy storage methods to minimize the total cost per kWh of the system when averaged over an entire year.
Another factor is the response rate and duration required of the stored energy system. In systems in the US southwest, Australia and other desert climates where solar is going to provide a large percentage of the total renewable power capacity. The energy storage system is going to need to supply 8-14 hours of power with a daily cycle. This would tend to favor systems with moderate storage capacity and fast response rate to keep the grid stable. This is likely where systems with higher round trip efficiency and power response rates in the 1 second range would likely have the advantage. This could be batteries (which don't have to be lithium-ion regardless of what Elon Musk thinks). This is also where potential energy storage would have an advantage. Potential energy storage is nowhere nearly as energy dense as batteries, thus they will have a much bigger footprint to store the same amount of energy. But they make up for that by having the energy storage medium be dirt cheap because it is literally dirt (well rock, but same difference) and an extremely long cycle life.
However, for system like solar energy systems at higher latitudes where there is considerable seasonal variation in the length of the day and solar intensity, some form of long duration storage that can bank some of the summer energy for use during the winter will probably improve the cost per kWh of the system when integrated over a full year. Long term storage for seasonal shifting is where systems like power-to-fuel can be the better solution since the net kWh/m3 density is much higher and thus the very large amount of stored energy required for seasonal energy shifting will fit in a much more reasonable volume, even considering the much lower round-trip-efficiency. Hydrogen could be a good storage medium, but methanol might be better since it is a liquid at ambient conditions and so can be stored in simple tanks rather than requiring the expensive high pressure tanks for gaseous storage or complicated and expensive zero-boil off system for long term liquid hydrogen storage.
Bottom line is that to optimize an electrical power system where the majority of the power is coming from intermittent sources like wind, solar, tidal, and wave will require a number of different energy storage types working together to meet the demand power on the grid that varies on time scales from seconds to months to energy generation types which also vary in output from seconds to months.

Interesting; but there will be a HORIZONTAL component there, doing NO WORK; ,how much extra loss,if any, will that be ?

500 tons moving 500m vertically stores kWh. The weights need to be very cheap and you need lots of storage room if you want to cover seasonal dips

As mentioned in the video it is a short term energy storage system only. That's why they compare it with battery storage systems.
Just imagine it would be lifted just once in summer and then lowered in winter again. So you earn money for just 10 minutes per year. But you still have the whole investment and maintenance cost of the facility. Of course you would want to lower your weight as often as possible. Preferably multiple times per day. And that is how they calculate these low LCOE.
As seasonal storage you can multiply the LCOE with a factor of at least 300 (depending on their actual assumptions).

@@jonathanedelson6733 I didn't suggest that this technology be solely responsible for covering dips, just that it could help as can hydropower and flow batteries.

@@jonathanedelson6733 Graviticity plans to use scrap iron.

@@eclecticcyclist I was not saying it couldn't work. I was trying to describe the costs involved in making it work.
Say you already have the shaft and regen lifting/lowering system, and assume that this system already makes sense for short term cycling.
Now you ask 'what is necessary to get 'seasonal energy storage'. Say 'seasonal' storage means charging and discharging 2x per year.
Say your shaft is 500m tall, and you use 500 tonne masses. Each mass stores 680kWh. Over the life of the system each mass cycles perhaps 100 times for this 'seasonal' usage, and thus stores 68MWh. The cost of the 500 tonne mass plus the space to store it top and bottom has to be really cheap (my guess, $5-20K) to be worth it for seasonal storage. You are welcome to do more accurate math.
Keep in mind that if your 'seasonal energy storage ' is too expensive, then you are probably better off with things like larger solar arrays to provide sufficient off season production.
Jon

If the shafts are full of water, I wonder if they can be pumped out and used as the lower reservoir for pumped hydro?

@@ericmgodfrey Quidnet Energy wants to use such shafts to pump them full with water under pressure as an alternative energy storage system.

@@ericmgodfrey "I wonder if they can be pumped out and used as the lower reservoir for pumped hydro?" Yes they can. I'm absolutely guaranteeing that.

Agreed, very cringe

And the wind turbines in the valley instead of on the ridge

Yes that storage system is horrible.
But at this point in the American southwest pumped hydro is probably not a good choice.
Being that Lake Powell and Lake Mead are at excessively low levels.
10s of millions of people's water supply is under a serious threat.
Should the trends continue it is highly likely that a few cities might cease to be in the coming decades due to lack of water.

Do you mean after it's been poured?
I've got thin concrete foundation around the edge of my greenhouse, I get the feeling they draw quite a lot of water up out of the nearby ground through wicking which then evaporates, I've been considering removing the soil and painting the concrete to avoid this happening.

@@jamesgrover2005 Do you think that's what was meant? I thought perhaps they were referring to Permeable Pavement. 🤔

🤣

Jan klaas, i dont understand your emoji. What is the joke?

why should the govt gets involve?

@@dantronics1682 Because they have the funds to develop key infrastructure that helps society... Much of what we enjoy now was funded by governments.

500 tonnes at 500m is 680kWh.
Peanuts

You can with Pumped-storage hydroelectricity which coincidentally is the best and most importantly viable option. Still, it's an edge case solution as it requires a high difference in elevation and a cheap but unsteady source of power, most prominently wind turbines.

@@rot7296 I was referring to these suspended weight systems. They are constant torque, unless they have a complex gear box.

@@reesewebster9149 And I was agreeing and also shitting on those systems.

er, yes you can! with a suitable inverter driving the load motor you can control both the speed and the torque of the system, where torque x speed = power in either quadrant

@@maxtorque2277 are you saying to use a dc motor connected to the weights then use an inverter to connect it to the grid?

Skyscrapers already have enough physics working against them that adding extra strain and liability is not worth the minimum energy gain

@@thomasreese2816 It's an idea, even if they only used the energy within their own building to power computer banks and energy load.
Dump an overpower to the building, and have it ballance its own power needs.

@@onebylandtwoifbysearunifby5475 The maths for this is very easy. Let's say the elevator has a rated capacity of one tonne and the building is 100m high. That equates to 0.28KWh of stored energy. By the time you've overcome frictional losses I'd be surprised if you get 0.1KWh of electricity, which will make about one cup of tea and has a commercial value of about 5 pence. Deduct the cost of all the extra machinery and you rapidly conclude it's a non-starter

@@sammason2300 Frictional losses could be replaced with magnetic forces, so could be analogous to mag-lev trains or regenerative AC motors.
New buildings are being built all the time, and such ideas as energy recovery seem a good idea.
Maybe a retrofit wouldn't be efficient in this case, but a central tower with a mass suspended as a counterweight to locomotion may be feasible. This tower could also be subsurface, and part of the building's cantilever foundation.
The first aeroplane sucked too; i mean 12 seconds? That will never take off.

@@onebylandtwoifbysearunifby5475 Low speed generators are very big and expensive, whilst high speed generators require lossy step-up gearboxes.
But my main gripe is the exceptionally low power density. My view is that gravitational storage only makes sense for pumped hydro, and only then if the natural geography already exists.
This idea has been around forever. It wasn't commercially viable before so why would it be now?

Gravitricity is designed to use old coal mine shafts that's the whole point.

@@jasonleahy5543 ah thanks, i tink i lost that in translation. ( i am Dutch)
I thought they had to dig special size holes to specific depts

Coal states are owned by coal companies who don't want renewables as it cuts into their business. Even if, in economic terms, this is better for the state's economy, the politicians are already owned by the fossil fuel industry.

I agree. The Appalachian mountains now have lots of wind turbines harnessing the wind through the mountain passes and over the ridges, with many coal mines nearby. I think it would be a great area to test this out.

Most coal is removed on horizontal galleries there are not all that many tal vertical shafts compared to the mine area.
Also, mines don't stay empty. Ground water eventually getsmin and needs to be pumped.

@@phhowe17 Which would make me think that pumped hydro storage on the surface FROM the old mine shafts would be a good way to go.

@@eaglechawks3933 Yes - Rye Development is working on the 200-MW Lewis Ridge Pumped Hydropower project in a former coal mine in Kentucky

It's a fairly simple system built from known components with known longevity. Basically a winch, a motor and some electrical controls to switch direction and possibly convert frequency between winch speed and grid frequency.

@@johndododoe1411 For the system to be robust, the parts have to necessarily be stronger and heavier to withstand wear and tear. The heavier system builds in losses during both, charging and discharging cycles, which again is a huge cost everyday, every hour and every minute.
This defeats the purpose of system.

Yup got to say this one seems logical. It won’t handle all energy storage. But I imagine any one sitting on old mines will be installing these.

@@fritzstauff Well if you already have a cavern down there that you need to stabilize anyhow then it is really about running the numbers if you go for this solution or a more classical approach with water or compressed air as media.

well it does seem a great use for these old mineshafts. however, most mines, once decommisioned will flood when the pumps are turned off, greatly reducing the droplength of the weights... and keeping the pums running isnt really viable...even if somehow they manage to isolate the shaft from rest of the mine...

@@zvezdaster Great point. Any clue how much energy to run the pumps? Also I assume they only run when water is detected. Maybe a decent solar array can neutralize that energy.

@@fritzstauff well that would depend on the geological circumstances, but its safe to say that extraction has to be continuous and at a near fixed rate or level. alternating the pressure on the shaft walls is the surrest way to make it collapse. However when the shaft starts an elevated level, lets say halfway up a mountain you might get the advantage of "dry hight" that you will be able to exploit. also some of such shaft could be sunk on purpose with exit openings at the bottom in mountainous locations. Which was common in old mines in such locations to keep em viable. with modern tech this should be much easier to do..

I suspect such a system would be very hard to maintain. It would also suffer worse from weather and currents than the crane tower does from wind. Salt water being very good at dissolving stuff would make material requirements strict and maintenance underwater is far trickier and expensive. It's a fun idea though.

It's not quite what you are describing, but you might find this video interesteing. It explores 4 concepts of underwater storage: ruclips.net/video/gd1fTJ-csio/видео.html
The first one pulls gas filled containers under water to store energie, the others pump water in/out of a container and utilize the pressure difference to strore energie. Especially the last two concepts look interesting, as the capacity would go up with higher depth (higher pressure).

I know it would be a Challange, so is space. Plastics work well in the ocean, we have years of data confirming that. Lol
Thanks for the video Oliver!
I love outside of the box ideas

The submarines gonna crash right unto that and itll gum up from ocean barnicles etc

@@TheAnnoyingBoss yeah seems impossible for them to be able to avoid something like that with the ocean being so small and having no way to navigate or see anything underwater

I think the average UK usage of electricity is 10 KWH but that's because most of our heat energy comes from mains gas at the moment.
But this is a brilliant comment, really puts it into perspective the scale of the problem. Mine shafts is a good local solution I guess but hard to see how it will have a global impact.
That's not to say I'm against promoting local solutions. More small hyrdopower plants would be good

How is it brilliant? The math and spelling are both dismal.

The problem I think with pumped hydro in mines is that the mines tend to fill in with groundwater once you empty them, meaning no space for the water to go at discharge time. Maybe not a problem if you find a place to put the surplus water that you're generating, you'd need a secondary spillway that goes somewhere else and you'd need to be sure that the water from the mine isn't contaminated.

@@AlRoderick if it fills with water then that scuppers the weight lifting/lowering idea too.

Thanks for your post about PSHAUM. I had the same idea after watching the video so the fact that someone else is doing it isn't surprising and saves me having to do it myself. 😂

Agree it would make a good topic for a video.

@@robinherrick2177 I don't know if it scuppers it, weights sink in water too, the buoyancy would just affect the total capacity (the weight would store less energy per unit height in water).

Yeah I really think batteries just make more sense if you already have the energy in electrical form. Converting it back and forth with mechanical energy has more losses. And they don't involve massive construction projects, just mass manufacturing.

@@DFPercush Losses are not the issue, really. When you'll want to storing energy it will usually be dirt cheap (surplus solar / wind); the grid operator will be glad that you're taking it off their hands. For that reason, hydrogen is becoming a viable option despite the round trip (power grid, hydrogen, compression, and conversion back to electricity) only being around 40% efficient. Fewer losses are obviously better, but construction and operating costs are much more important, not to mention scalability. Fundamentally, Energy vault and Gravitricity suffer from the same problem: it does not scale well.

@@kaasmeester5903 Surplus solar is never going to happen, it's during the day most energy is needed so there will always be a demand for solar. Wind has more potential as it can be harnessed during off-peak times.

@@simonmoore8776 If we're going to rely on renewables for most of our power, we'll have to massively overspec it. So far the numbers look good for using mostly wind and solar, balancing with batteries or hydrogen, picking up shortfalls with hydrogen as well, and relying on gas fired plants a few times a year (or hydrogen generated from gas) for the few longer periodds of low production we can't bridge.

Mechanically switching the mechanical system between shafts while holding up the weights at the top will add extra complexity that would be avoided by simply replicating the equipment to provide complete failure redundancy.

Mineshafts are a) small and b) few and far between, relatively speaking. This would be a very small scale setup.

Leveling out grid demand with rapid response is also a good idea. It’s not trying to compete with pumped hydro, it’s dealing with brief shortages.

@@history8192 but batteries are much better at that. Bigger capacity and much faster.

You only store / get energy from the difference of vertical height. The horizontal length of the track does not give you any benefits, so it would just require more space for the same effect and you have reduced efficiency due to the friction of the wheels.

it is already done: called regenerative braking.

@@Kiboxxx - true and that is both a given and a good reason for their relative safety! There are plant of locations globally that would suit this application without taking up valuable human or agricultural habitat. Solar panels are great users of space and wind farms have a major visual impact and affect bird-life significantly. This is not meant as necessarily the best or the only solution - just a good one to consider from the gravity perspective. Their visual impact would be quite easily dealt with by running the tracks in a small artificial "ditch".

@@janami-dharmam - So why not use it this way too?

The amount of energy you get from a system is dependent on the 1) Weight of the load being moved up and 2) the Height you achieve. if you push a load straight up (like these guys are doing) then all of the energy you put into the system will go towards building the potential energy in the raised weight (minus any system loss in the motors). But if you push the load up an incline (like on a rail going up hill) then the amount of energy you put raising the load vertically is only a fraction of the over all energy that you put into the system because you have to spend energy counteracting the horizontal force that is pulling you back the track.