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Imagine a typical steampunk setting. Now, let's make two grand assumptions about it:

  1. Steam engines here are MUCH more efficient than those in our world. Yep, we have to violate laws of physics for this one.
  2. We can't use any electrical energy. To not touch physics again, let's pretend we self-restricted ourselves from using any kind of electricity.

These do not apply to the entire genre - just for here and for now, we need these two for our thought experiment.

While generating whole lot of a mechanical energy, we can't convert it to the electrical one. This forbids us from a convenient way to manage said energy. Yet, our steampunk world still needs to do it somehow.

Is there any effective way to store this energy now? Be it some "batteries" for long-term storing, or "pipes" for temporal one (while transmitting energy for short distances).

Or maybe we could find another convenient form of energy to convert to, working around it?

Assume we don't want to violate physics anymore - apart from those laws we've violated already, of course.

I just wonder how this whole world would look like - it's not really a topic many steampunk universes raise, even though this is (possibly) a main problem these worlds would have to deal with.

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    $\begingroup$ Welcome Elvagyodas. You've a couple of distinct questions here (transmit and store), can you pick one. Any subsequent question can be asked in its own thread. Please edit. $\endgroup$ Commented Jun 27, 2023 at 0:16
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    $\begingroup$ Modern steam engines, that is, supercritical steam turbines, are about 40% efficient. It is not particulary clear how "much more efficient" they could be... Of course, they are used to generate electric power. And anyway, the true-and-tested method of storing and transmitting energy in the age of coal was, wait for it, coal. You store the energy in the form of coal. You transport the energy in the form of coal. This is what they actually did. $\endgroup$
    – AlexP
    Commented Jun 27, 2023 at 0:16
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    $\begingroup$ Transfer how far? Most steam-powered, and even early electrical-powered factories were essentially self-contained, with power generated on the premises and distributed mechanically with ordinary shafts, belts, and gears. You weren't trying to conduct power halfway across the country as in modern grids. $\endgroup$
    – Cadence
    Commented Jun 27, 2023 at 0:32
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    $\begingroup$ Flywheels, springs, pumping water uphill, pumping air into salt caverns. Note that flywheel or spring energy storage per kilogram is quite low compared to gasoline or batteries. The chief advantage of flywheels is speed of charging/discharging. But also if your steam engines are magically super-efficient then you should just keep the energy in the form of coal, and use the steam engine to transform it into motion when needed. $\endgroup$
    – causative
    Commented Jun 27, 2023 at 1:23
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    $\begingroup$ Store for what? we don't store energy in the same way for all purposes. since steam engines run on fuel just storing the fuel will be the most efficient. $\endgroup$
    – John
    Commented Jun 28, 2023 at 12:17

13 Answers 13

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Pneumatics or Springs

If you're just storing energy locally, a flywheel or pumped hydro is your friend, but if you want to move energy around in physical storage "batteries", then your best bet is compressed air.

Pneumatics are already widely employed, but you can turn compressed air directly into mechanical energy pretty readily with an air engine or employ it directly, as in compressed air cars.

The only issue would be the materials science required to store gasses under pressure, but if you have steam engines (and magically effective steam engines, at that), that's probably addressable.

The other option I'm lifting directly from The Windup Girl: kink-springs. In the context of the book, kink-springs are kind of like old-school mainsprings from watches and other clockwork, but capable of much higher energy densities because <insert materials science handwavium>. If you're already playing around with physics, a material that can be a spring that winds tighter and with more energy than any metal we have access to, and which will rebound to its normal shape is more than capable of being a mechanical energy storage battery. The problem, as illustrated in part of that book, is that if you break the spring, all that energy gets released at once.

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    $\begingroup$ Even better if this special material has some of the properties of nitinol, preserving its shape until heated. That would address springs' annoying desire to dump all their power quickly without having to engineer extremely rugged retardation mechanisms. $\endgroup$
    – biziclop
    Commented Jun 27, 2023 at 10:34
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    $\begingroup$ Note that flywheels can have industrial size and store huge amounts of energy. From a visit there I know that the Greifswald fusion research center (en.wikipedia.org/wiki/Wendelstein_7-X) has one which is a 10m long, 5m diameter solid steel cylinder rotating aroiund 30.000 times per minute. It stores enough energy to kick start their fusion reactor. $\endgroup$
    – quarague
    Commented Jun 27, 2023 at 12:44
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    $\begingroup$ Air compression is not efficient. Compress air => temperature of the air rises => heat loss through the container wall => loss of energy. Also hard to do this with large amounts of energy. Far better is the high water reservoir. Use mechanical energy to pump (or otherwise raise) water to the high reservoir. The energy is recovered when needed by allowing the water to flow back through a penstock with a turbine. $\endgroup$
    – Trunk
    Commented Jun 27, 2023 at 23:20
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    $\begingroup$ @RobertRapplean Well -- it is hard to remove energy from it in a controlled and useful fashion ;-). $\endgroup$ Commented Jun 28, 2023 at 0:35
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    $\begingroup$ @quarague, flywheels spinning that fast aren't exactly portable. Just try handling the gyroscopic effects as you tilt it slightly to go up a slope. $\endgroup$
    – Mark
    Commented Jun 28, 2023 at 1:41
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Massive flywheels, baby!

Although in our world we use them to store electric energy, that needn't be so.

There were even full-size buses propelled by flywheels, they were called gyrobuses, which if anything, is a cool name for a steampunk story.

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    $\begingroup$ There were plans in the eighties for the River Severn barrage to store many GWH in a single flywheel to even out the generating capacity of the tides. $\endgroup$ Commented Jun 27, 2023 at 12:31
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    $\begingroup$ Flywheels are fun, but flywheel based vehicles suffer from the gyroscopic momentum, making them problematic when going up and down hills. On the other hand, they have awesome regenerative braking qualities. Also, charging and discharging flywheels usually involves electricity. $\endgroup$ Commented Jun 27, 2023 at 22:26
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    $\begingroup$ @RobertRapplean There is a reason why we don't see gyrobuses in our cities, no matter how cool their name was. $\endgroup$
    – biziclop
    Commented Jun 27, 2023 at 22:44
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    $\begingroup$ @RobertRapplean I wonder why you couldn't use the momentum of the flywheel directly to power the vehicle, through a gearbox, instead of converting it to electricity with a generator and then back to rotational movement with a motor? $\endgroup$ Commented Jun 28, 2023 at 0:30
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    $\begingroup$ Although according to Wikipedia there is a light rail unit that does exactly this: it drives the axles off the flywheel rotation fed through a CVT. $\endgroup$
    – biziclop
    Commented Jun 28, 2023 at 8:29
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Gravity Battery

A gravity battery spends energy to lift weights, which stores potential gravitation energy that can be extracted later by lowering the weights. See wikipedia

I believe this is a relatively new invention in our world, but the basic concept is really just a crane, which existed in antiquity.

I originally heard of this from a startup Energy Vault that went viral in the news a few years ago.

You could directly use the mechanical energy of the winches lowering the weights to power nearby devices, but to distribute power in as infrastructure, you would need some kind of mechanical-to-heat transducer, the steam analog of an electric generator.

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    $\begingroup$ Another kind of gravity battery is just moving water from a lower reservoir to a higher one. These exist in our world already, without as many moving parts as that energy vault concept. $\endgroup$
    – Pyritie
    Commented Jun 27, 2023 at 10:06
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    $\begingroup$ I can't edit my previous comment any more, but here's a link en.wikipedia.org/wiki/Pumped-storage_hydroelectricity $\endgroup$
    – Pyritie
    Commented Jun 27, 2023 at 15:00
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    $\begingroup$ Some old style mechanical clocks use gravity. You pull the weights up every day to keep the clock running. Gravity pulls the weight down, churning all the gears. I don't know how old those are, but the ones I've seen look at least 200 years old. $\endgroup$
    – user458
    Commented Jun 27, 2023 at 15:17
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    $\begingroup$ Tower clocks definitely existed in the middle ages and they're all gravity powered. (Or at least were until they were electrified.) $\endgroup$
    – biziclop
    Commented Jun 27, 2023 at 18:08
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    $\begingroup$ @Pyritie Adam something? $\endgroup$ Commented Jun 28, 2023 at 0:27
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You don't, You store the fuel for the magic steam engines and just have the steam engines in all sizes.

You don't want to convert then energy then store it, if your engines are that efficient, they are more efficient than ANY storage that can be used after that step. Electricity storage is largely pointless anyway in your world, you don't need to handwave it.

You just store the fuel that runs your super efficient steam engines. Steam cars were a real thing. Steam engines can be made very small, or absolutely massive. The smallest working steam engine will fit on your thumbnail, the largest is over a hundred tons and is larger than a house, you can believably have a steam turbine for whatever you want to run. If they are as magically efficient as you say they could be made even smaller.

mechanical storage in your world is only used to smooth out small scale local instability, such as small flywheels or damper systems.

Steam engines can be run off a variety of fuels, wood, coal, gasoline, kerosene, methane, fuel oil, essentially anything that burns. All nuclear reactors are still steam engines at their core, as are thermal solar plants.

A steam engine does not even need to be run all the time to work all the time, steam cars will run for miles even when the fuel is exhausted just on the steam pressure left in the system.

In your world everything has uses power has a steam engine in it. The ultimate steam punk dream. An anime "Kabaneri of the Iron Fortress" even plays around with a similar idea, everyone walks around with a tiny steam engine on their belt to run basically anything small, even guns are steam powered.

A big upside of this is you only need to handwave once the one you already have the magic steam engines, nothing else needs to be unrealistic.

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  • $\begingroup$ As obvious as it is brilliant. I just didn't think of it. $\endgroup$
    – Fattie
    Commented Jun 29, 2023 at 14:19
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I suggest you read Wind Up Girl. This is a post-apocalyptic world where the main characters are operating a spring-based energy storage system. Spring-based and flywheel-based present the best energy density short of storing it as chemical energy. Chemical energy is still your best bet. Compressed gas suffers serious issues with energy losses due to heating of gas on compression.

Here are a few useful statistics on energy storage techniques. All numbers list where the values max out. Lithium-Ion presented for comparison. Note that density is per volume. If you want to carry this thing around, you need to measure it by kg.

Method max (MWh) Density (Wh/l) Issues
Pumped Hydro 3000 2 Requires lots of land
Compressed gas 1000 6 Efficiency loss from heating
Molten Salt 150 120 High max temperature
Lithium-ion 100 400 It's what we do
Flywheel 20 80 Frictionless bearings, explosive failure
Kink spring 100 Extremely low density per kg

Addendum: Based on OP, flywheels are out of the question. There are no schemes that I'm aware of that allow you to move power into/out of a flywheel without electricity. There is a method that uses magnets, but the loss to heat is intense.

Addendum2: There are numerous examples of using flywheels for short-term energy storage, connected by continuous variable transmission. CVT energy loss is a function of time, making this a viable way to store energy between, for instance, the time between when a bus stops at a bus stop and when it starts up again.

The cam shaft of a single-cylinder engine is basically a flywheel that stores energy from one internal combustion explosion to deliver it to the next pressurization cycle. Such capacitor-like storage of energy is not only possible, but commonplace. It's also not the thing that the OP is looking for. He wants something he can top off and leave it for days, if not months, and have it available when he needs it. A flywheel that lacks electromagnetic levitation will bleed its energy into heat far too quickly to be used for such purposes.

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    $\begingroup$ Hah. I also cited the Windup Girl (with link). It's the best example of a mechanical energy portable storage battery I could think of in fiction. $\endgroup$
    – jdunlop
    Commented Jun 27, 2023 at 0:18
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    $\begingroup$ @biziclop, true, but the overall efficiency of those systems maxes out around 70%. $\endgroup$ Commented Jun 27, 2023 at 21:42
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    $\begingroup$ @biziclop, no offense taken. All information is welcome. $\endgroup$ Commented Jun 27, 2023 at 22:23
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    $\begingroup$ You can get energy out of a flywheel just fine using a hydrokinetic transmission, a clutch and continuously-variable transmission, or any number of other ways. Admittedly, these tend to have lower efficiency or greater wear-and-tear than a motor-generator. $\endgroup$
    – Mark
    Commented Jun 28, 2023 at 1:47
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    $\begingroup$ Whatever the mechanism is that bicycles use to let you pedal, or not, while still rolling forward would let you add energy to a flywheel. Plenty of ways to get power of something rotating, see mechanical watches and all pre-electricity windmills. $\endgroup$ Commented Jun 28, 2023 at 3:08
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There are actually a fair amount of examples in the real-world, at least for long-term storage.

I'll start with the exotic Sand Battery, by Polar Night Energy which may be the least possible for you. Their concept is simple: an air circuit is embedded in a silo filled with sand. Heating the water leads to storing heat in the sand, cooling the air leads to extracting heat from the sand. Their goal is to heat the tons of sand to 600°C over the Summer, and have the battery last all Winter long, sustaining an entire small town. That's... a lot of energy.

On the more mechanical side, gravity is a good friend. The Swiss are known to buy electricity from their neighbors when it's cheap and use it to pump water up, then release the water when the price goes up, producing electricity they sell back to their neighbors at a higher pricer.

Multiple start-ups are currently investigating more elaborate systems, which generally involved moving massive weights up and down. Those Gravity Batteries operate on the age old principle of the pendulum clock (1656):

  • Energy Vault: building with giant bricks being raised and lowered.
  • Gravitricity: weighs are being raised and lowered in a vertical underground shaft, such as former mine shafts.

Others have mentioned flywheels, etc...

Note that those solutions are not necessarily good in terms of density, they are for high-capacity, long-term storage. For vehicles, you'll probably want steam engines, with coal/petroleum/... and for very low-capacity, short-term, then you can turn to small springs/micro-explosions.

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    $\begingroup$ How would you heat the water up to 600 °C? Is it in a very high pressure vessel? $\endgroup$ Commented Jun 27, 2023 at 22:52
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    $\begingroup$ @PaŭloEbermann: Not sure if they have liquid water under high pressure or steam under high pressure. Either would work, I suppose, though I'd guess liquids are better at heat transfer. $\endgroup$ Commented Jun 28, 2023 at 6:57
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    $\begingroup$ The critical point for water is 374 °C and 20 bar so it's definitely a supercritical fluid. And at 600°C the pressure would be around 1000 bar, so it would need some seriously strong kit. $\endgroup$
    – Slarty
    Commented Jun 28, 2023 at 7:25
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    $\begingroup$ It's air not water. $\endgroup$ Commented Jun 29, 2023 at 5:15
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Or maybe we could find another convenient form of energy to convert to, working around it?

Chemical energy

This is borderline moving from steampunk into dieselpunk, but might make sense for you.

This is also very commonplace in gasolinepunk settings such as real life.

Methane is a source of energy but it is not the best source of energy. Petrol is safer and easier to transport and use due to gasoline not being a gas (that came out weird).

For this reason there is a process called Gas to Liquids, or GTL for short, which converts methane and other lighter hydrocarbons into gasoline or diesel.

And remember, a tank full of gasoline is nothing more, nothing less than a chemical battery. An internal combustion engine is just the boring way to tap into that stored energy, the cool way being a match and optionally canned oxygen.

Anyway, GTL requires energy, so that may be where steam comes in. Depending on economic factors, or technological limitations, steam might be cheaper for large scale applications such as power plants (specially considering its magically more powerful in your world). So you extract methane from wherever, use steam to convert it into gasoline, and then people can use that gasoline to power portable shaving razors or grandfather clocks or whatever it is that your characters use.

By the way, for comparison, a real world 60Ah car battery can hold around 2.6 megajoules. One kilogram (2.205 pounds) of gasoline in a tank holds around 45.8 megajoules. That's about 17.6 fully charged car batteries in a little less than a 1.5L coca cola bottle (gasoline is lighter than water, at ~743g/L).

Storing energy in this way rather than mechanical means also gives your world a way to have a proper energy market. I love all the other answers, but there is a reason why in our own world we buy a liquid rather than pieces of metal spinning at 3,000 rpm or weights tied to springs to put in our cars and trucks. And the only other economically and physically practical alternative has been ruled out in the question.

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Steam engines are very efficient in some unexplained way (since they're already something like 40% efficient as a comment says, this really does need magic physics, but this is allowed).

So a really good way of storing and transporting energy in this world is ... steam. You can store it under pressure in very insulated boilers, transport it along insulated pipes.

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    $\begingroup$ Many cities already have steam pipes running through them to provide heat. en.wikipedia.org/wiki/District_heating. You can look to these for inspiration $\endgroup$
    – Kaia
    Commented Jun 27, 2023 at 20:10
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    $\begingroup$ Yup. People actually did (and still do this). There were even rail engines running on a steam battery (i.e. they did not have a firebox, just a steam tank) for use in environments such as explosives/fertilizer factories. In fact, steam has a pretty high energy density - if you compare just the steam with a full lithium battery, steam wins; of course, if you include the tank for storing the steam, lithium batteries win easily. The main problem is that coal has a much higher density than either. You store steam to level out variations in demand; the bulk storage is the cheap coal. $\endgroup$
    – Luaan
    Commented Jun 28, 2023 at 11:51
  • $\begingroup$ Storing steam kills UPS though. $\endgroup$
    – AnoE
    Commented Jun 29, 2023 at 11:35
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Mechanical energy could be used in a compressor / cooler unit without electrical input to produce liquid air or liquid nitrogen. With appropriate insulation this can be stored for a long time.

In fact this method of energy storage is currently under development. it uses modern electric compressors and other electric equipment, but these are not essential to the process and could be dispensed with at some efficiency cost.

To regenerate the mechanical energy the liquid air/nitrogen is warmed via the environment (reverse heat pump) and/or other sources of low grade heat to produce a high pressure gas that is then used to spin a turbine.

https://highviewpower.com/news_announcement/highview-power-unveils-cryobattery-worlds-first-giga-scale-cryogenic-battery/

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To make this really, really simple let's stop for just a second to see what's really going on: You want some method (or methods) to successfully store WORK done by another engine previously so that you can harvest later to get more WORK done. The easier it is to harvest this WORK, the better.

There are loads of ways to do this, some more inventive than others. (There are lots of options given above, for examples.) Unfortunately I spent an inordinate amount of my youth studying physics and gaming, and had become quite inventive in how this might be accomplished - for portable and non-portable methods.

My favorite portable method was to build small elastic liquid-filled spheres with a single "port" on them. The port was a bayonet-type port, meaning it wouldn't open unless it was secured to another connector. The only requirement for using these was that the sphere be connected with the port at the lowest point of the arrangement - either charging or discharging. One would connect the sphere to a "charger" which would then force air (or other gas) bubbles into it through the port, letting some liquid/fluid act as a one-way valve, and building pressure throughout the elastic "ball" to charge it up. I used water, but you could use oil, alcohol, even maple syrup - it really doesn't make much of a difference. WORK was done to compress the gas (air or whatever) into the "ball" past the liquid, which was then stored in equilibrium of the elastic sphere and the valve. This made it possible to carry the energy around, stored and ready. Or roll it around, if it's too big to carry handily. (In my game world they were made from a rubber-like elastomer that was incredibly tough and cut/puncture-resistant.) Because most of the battery was just compressed air (or some other gas, whatever you prefer) it didn't really weigh any more charged or discharged - so that was just a function on volume. A fully-charged sphere would naturally be physically larger than an empty one. BUT when someone needed to transfer some stored WORK to their application, it was easily transportable and almost immediately ready (you still had to connect it in the correct orientation for it to work). As a bonus, in case of an uncontrolled fire you could just chuck a few batteries on the flames to extinguish it! (Bet you can't do that with today's electrical batteries!) I said the elastomer was cut and puncture resistant. I never said anything about it being fireproof.

I almost forgot - the reason for the liquid/fluid at the bottom of the sphere was two-fold: initially it acted as a "lock" because it was heavier than the gas which bubbled through it to be trapped inside the sphere, and when the elastic limit of the sphere was reached the fluid would get pushed back in through the valve, making it possible to trigger a disengage (or some other activity) to prevent the sphere from being destroyed by being over-inflated. Safety first, and (try to) make it last.

I'll have to scare up my notes for other examples if you need them. (I'm currently at work - on break - and was curious if this would help.)

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Steam Accumulator

Spirax Sarco has a detailed engineering explanation of how they work and ways in which they can be configured. The image below is one example from their page.

Essentially you take your steam source and bubble it through water in another pressure vessel. The vessel stores thermal energy in the water. When the pressure is reduced, that super-heated water flashes back to steam. They are commonly used in real world industry to balance the boiler capacity and the process load. The boiler is operated at a higher pressure than the accumulator and control valves are required for a constant steam output.

Steam accumulators bear the same high temperature pressure vessel safety risks as a boiler, but are very efficient when properly insulated. If you are storing fictitiously large amounts of energy without regards to the vessel cost, the efficiency goes up as the vessel gets larger because volume increases faster than surface area.

And of course, more steam and pipes in a steampunk world couldn't hurt ;-)

enter image description here

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I interviewed at place that was building flywheels on magnetic bearings in vacuum as local back-up (electrical) power. As long as we're imagining, could we imagine a concentric turbine setup where power is applied as a super-heated steam jet near the periphery, with the flywheel spinning so fast that air and water vapor are flung out, away from the moving parts. Gotta keep wht wheel in a vacuum. This would require a gigantic radius and head room outside it.

Power could be extracted by admitting a working fluid- air, water, olive oil, to a compression turbine on the other face or outside the power-in turbine's diameter. The compressed or accelerated flow exits the container, energized by the flywheel. Can't slow it down enough to compromise the vacuum. Steam to accelerate would go out the same way, and carry with it high residual energy.

Is this too painfully similar to a perpetual motion setup? Maybe.

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  • $\begingroup$ Wasn't sure what you meant at first, but like a torque converter, right? Otherwise I don't get the bit about concentric turbines. $\endgroup$ Commented Jun 28, 2023 at 3:54
  • $\begingroup$ Yes like a torque converter. But if the spinning is flinging out gas and liquid, but the input steam is driving it, then the input can't be flung out because it transmits force to the turbiine and itself slows down. Slower exhaust won't be flung out. On a regular power turbine, the exhausted input stream exits at the center, bereft of force. My suggestion is a perpetual motion idea. Alas. $\endgroup$
    – Bill IV
    Commented Jun 28, 2023 at 10:48
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Physicists have a name for this: potential energy.

In physics, potential energy is the energy held by an object because of its position relative to other objects, stresses within itself, its electric charge, or other factors.

Use steam to pump water up a steep hill to a reservoir; if the land isn't that steep, build large water towers.

Then, when you need the energy, let it flow down to spin whatever you need to spin and then do other things.

@John is right, though: just make the steam when you need it, since coal and wood are a lot easier to store.

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