Sand for Thermal Energy Storage

I need your input on piping, insulation, and distribution of heat for a sand battery! Help!

When I worked in the Solar Industry decades ago we used a saturated water/salt solution that would turn solid at room temperature and turn to liquid when heated. This liquid was stored in plastic stackable trays stored in an insulated room, air flowed through the trays to charge them with heat or extract heat at night using a conventional HVAC duct system in an attic or space for the thermal heat storage.

Minnesota. We worked on one house that stored their heat with 1 inch riverstone instead of sand. Never thought about it before but the stone would allow full airflow from the heat source. Eliminating piping. Hum. The stone was in insulated below ground bunkers.

I love that you have more questions than answers. It breads intelligent conversations and innovation from the "crowd". there are more intelligent and well thought out responses in your comments that I wont even through in my two bits. keep us up on how it goes.

Here in the Netherlands there is already an housing project that uses a big isolated basalt stone mass as an heating battery for heating in the winter. During the summer regular solar panels collect electricity that is stored with piping as heat is the basalt. In the winter this stored heat is used to heat a whole housing block ( name of the project: cesar-project and basalt-batterij)

Hello I'm an hvac journeymen. I believe air is your best medium. Using soft copper you can store heat in your sand. Then when you want move your heat from the sand with air to a tube in shell style heat exchanger. A tube in tube heat exchanger would work as well. You then can control water temp by simply controlling flow rate of air around the water tubes. And from Here you have your radiators and such.

Hi there, as a Canadian,
I understand how sand is a nice thought in the Winter!
Tahiti has some lovely sandy beaches!
I am very interested in sand batteries.
In the past I’ve done a couple of small scale experiments.
In buckets, & large SS saucepans.
Bought 3 older electric kettles from thrift stores.
Hooked directly to a 100w solar panel.
They all worked.
The bucket worked best, but I was concerned about heating
the galvanized bucket that hot in the house.
Fumes might be an issue.
The saucepan worked well, but wasn’t big enough.
After watching your video, I now have a bunch of new ideas!
Who knows what I’ll come up with?
Keep your smiles on!

As a primitive heat storage for those who have had to use this method throughout history, rocks and I imagine, sand, would hold their heat for long periods of time. I am thinking of the very old fashioned methods of heating specific areas with hot stones, heated by a fire, then transported to where they were needed. They not only used them for heating beds in freezing bedrooms, but also in outdoor carriages, under the seats, and in their homes where needed. These rocks would get switched out for newly heated stones brought in from either outdoor fires or indoor fireplaces. In this day of fuel shortages throughout many parts of the world, it seems we must inform ourselves of lifesaving methods of survival. When the weather thrust Texas into a deep freeze a couple of years ago, it was reported people froze to death, and pipes broke from freezing also. It seems the electric was down in many areas, and people apparently were not able to stay warm. It pays to know basic survival techniques, and sand used for heat storage makes sense to me. I had been thinking of getting stones, as in Florida we don't have "stones" as much as limestone, inland. But I thought of sand as an option, because if nothing else, Florida has all the sand one needs. Of course, it is mixed in with organic materials, but it is not hard to wash sand to the pure white state. I have done that. Once that is done, dry sand should be good for heating by the fire outside in metal containers that can be safely moved indoors to a metal or fireproof platform to warm small areas, should our grid go down. We dip down into the 30's here, and while no one would necessarily freeze to death, it can get very bitter during the nights, with days usually in the 50's. Thank you for this video, and I just wanted to recognize sand as a great potential heat storage/insulation resource.

So far, I have my greenhouse pit dug, aprox. 5' deep. After insulation with ridged foam I plan on filling the floor in with two feet thick adobe/cob slab, then add another foot or so on top of that but with a 6" diameter channel running thru it to direct and collect heat from a woodstove before heading out thru the chimney. This will operate similar to a cob bench often attached to a rocket mass heater in a home.
Only requiring a very minimal amount of wood and effort in the day/evening to create enough radiant heat to get thru our cold Canadian winter nights. And, in summer, the cool floor mass will help regulate the interior temps with at most a dc fan for circulation.
I've come to appreciate systems with as few movable, motorized, and electrified parts as possible- less to break, more reliable, easy/free to DIY fix, etc.

In Sweden, for many decades, they have made and used tiled stoves that are made of ceramic tiles according to a certain system that forces the smoke to make a round trip inside the stove before it enters the chimney. These stoves are only fired up once a day and they slowly give off their heat during the day and night.

Air is probably the best choice for moving the heat into the sand. I’m looking to build a rocket stove and blowing cool air with a small fan across the top in a 4” pipe and then down into the bottom of the sand. The pipe then splits out as a manifold into smaller pipes that have holes in their bottom so the air can get into the porous sand. A similar manifold at the top could bring warm air to where it is needed.

let's do a little bit of math here.
before that I just want to point out that water usable working range is closer to 30-90°C rather than 60-85°C. With 30°C water you definitely can heat a room equipped with a costly heating floor OR more smartly a fan-equipped water radiator to replace old high temperature radiators.
For water, this gives a DeltaT of 90-30=60K
So the volumetric heat capacity for water over that range is E(water)=Cp(water)*rho(water)*DeltaT(water)=4186*1*60=251kJ/L
Cp being the thermal capacity in J/K/kg
Now for sand : E(sand)=Cp(sand)*rho(sand)*DeltaT(sand)
So if we want E(sand) > E(water) we need DeltaT(sand)>251kJ/Cp(sand)/rho(sand)
Google says rho(sand)=1.6kg/L and Cp(sand)=835J/K/kg
This gives DeltaT(sand)> 187°C
Since we took a minimal working temperature of 30°C for water we need to take the same for sand which eventually gives a minimal heating temperature of 217°C.
Now we need to remember that at this temperature sand is just as good at storing heat as water is in a given volume. We need it to be a lot better to compensate for its inability to be easily pumped like water.
Let us asume that we want sand to be 30% better per volume unit than water. Then sand will have to be heated at 273°C.
This means that our free heat source will have to be at least that temperature, which is clearly not that certain for domestic use. The only places where sand can be heated continuously over 250°C is in those concentrated solar farms where a thin curtain of black sand falls across the supper bright focused hotspot on top of the tower.
On top of that, those temperature are very close to the auto inflamation of most materials like wood, dust, plastics, etc. So the fire hazard would be extremely high in residential use.
With all that said I think that, for domestic use, the better way to consume less wood throughout the year is to throughly insulate your house, use a heat pump that only work during the daylight and store the daily heat in a water tank or a massive wall or soil using simple PEX tubes, it is less sexy (I love exploring tech ideas too...) but it is a long term solution.

So say you use some sort of rocket mass stove to heat a large volume of sand to maybe 500 c. Then used in auger system to move hot sand to an insulated storage bunker. Augers are cheap to make then work fairly reliably. What I'm saying is basically you'd like to have your thermal storage like in your basement or crawl space but you don't want to have a wood stove there heating sand there, so you could do something sort of like a outdoor central boiler just super heat the sand and then move it to a spot that was more beneficial to have it like an ultra insulated dump tank in your basement. Sand is the fluid.

I think that the best thermal exchange fluid for sand heating is air at high pressure in pipes. You can circulate this air by high temperature compressor between concentrator and sand heat storage

Hey mate, what you need to study are simply "heat exchangers" this is a well known domain and largerly used in the industry, and this is the convergence point between heat storage and its use. The good thing here is that you know which temperature range you'll have to work with, so you can start projecting and dimensioning your installation. Even simpler to design and order well sized thermo-electric generators. Have fun !

What if you took a new empty 500 gal septic tank and fill it w/ sand/water mix (water added for better thermal transfer) added copper/pex/ stainless steelcoils for both the primary and secondary exchanger and used that? The tank cold be wrapped in insulated board both inside and out. You could manifold the tubing for better transfer also there’s a thing called Glauber salt that phase changes with heat. Just a few thoughts I had, have a good one

Radiant in floor heating also ups the anty.
I have using a compost pile heater in the cold, cold winter for a greenhouse using radiant heat. Going on two years, it has served me well.

I am now subbed... I was going to try synthetic oil, can get hot. Have always wanted to use a trough collector. Need auto adjusting capability however, Bright days can call the fire department. In and out loops into sand use the oil. Run thru a plate to plate exchanger to loop in the house. Pump the water in a loop thru the coils in the house. Use 3way valves so loop is always flowing. Have a 3 way mixing valve on the water side of the exchanger to keep loop speed up while adjusting the percentage of hot water to recirculated water. You could probably even pipe the sand/oil side of the plate to thermo siphon when the demand is low, but have a boost pump in the circuit. Random thoughts: Might want to check the stratification of heat in a big pile of sand. You might use the coils and pumps that introduce the heat and take it out to recirculate the heat by pumping the top coil through the bottom one to keep heat saturation fairly equal. Heat always gets away at the top. I'm sure that you can see that I'm a controls guy. Retired from 30 years of being paid to be a control freak. I also ran the Building Management System where I was. A LOT of analog mixing control stuff with fussy people that like their offices just so. When you put in a lot of control, you can either make it work or it will SHOW YOU the weak spot. 70yo retired with 65yo wife on 2.3ac 45mi ne of Metro Denver limits. 35X70X25 shop just gettin 'restarted'!

If you want really simple and low tech that uses upcycled materials it makes sense to me to build solar walls with old windows or glass doors, especially those from shower units or vehicles, which are very tough and harder to melt down for recycling.
I built a rocket mass heater which uses mostly sand to store the heat from my wood burner, reducing the wood used by two thirds

Use as tubing, glass tubes.
glass melting point approximately 1400 C to 1600 C

I would say that electric heaters, fed by photovoltaics are a great way to store a lot of heat in a closed and well insulated sand container, that has built in pipes for heat exchange. You could easily get the sand to 300-400 degrees C. Stainless steel should be a good material for the container/heat exchanger. Insulation should be very good, maybe a first layer of perlite/cement, second layer of hempcrete or rock wool (or maybe both). And the whole thing put underground. Using a loop of high temp oil, you can easily transfer heat from the sandbox to a water boiler.
And relying on photovoltaics, rather than solar heat collectors, means that even in very dim and short winter days, you could get at least some heat.
And in the summer you can use the extra power for other stuff.

What you need to be more concerned about is how you will pump the fluid through the system without melting or burning up the pump, pipes or valves.
The way I would do it is to use hundreds of inexpensive flat mirrors to reflect the sunlight through a glass covered hole in the sand box to heat the sand directly. Then circulate water through the sand for use wherever.

We have a fireplace insert with a huge fire pit - so large that when we fill it with wood, things get too hot, and there is a risk of chimney fire. We came up with the idea of putting large concrete blocks in the back. They will heat up from the burning coals, and stay hot for a long time. Two fans will blow this heated air around the house.

I created a scaled down version of a mirror concentrator from a Mother Earth News article in the mid 80's. I used a 10 x 10 array of 12" x 12" mirrors that tracked the sun using simple photo voltaic cells, a relay and a car starter motor to maintain focus on the sun. I raised our 24' above ground pool by about 17 degrees F. I only tracked across the sky and had to adjust every couple of weeks for longitudinal changes. Adding a second motor and sensors would be simple, especially with arduino systems available. I like your idea of using oil instead of water to avoid the thermal limit that steam introduces. The article is entitled "Make a Solar Furnace" under the renewable energy category. Using oil instead of water through a system like that would give you the temperatures you are looking for. Using oil in the trough design would allow a simple thermal gravity flow if aligned right. The cost of mirrors like the article do add up quickly. Keep us up to date on your plans. I like it.

I'm about to build a high performance house. We are using geothermal hvac and solar hot water. We are running our hot water in the roof rain screen with metal roof and radiant barrier. It will be a continuous Ling with no breaks being pumped to an insulated pre tank in the attic. We are in climate zone 3 so our cooling is more of an issue than heating. Non the less we will try it to see how it works out. Good luck with your project 👍

Build the sand storage box with an air gapped insulated compartment on top and control the temperature of the air so that you can heat a closed loop water system directly via salvaged radiators or copper pipe. You may need an exhaust in the air box as protection to prevent over heating of the water.

Iam using foam crete to insulate my 55 gallon drums and heat element to heat the sand to 600degrees I have to put it in play this spring but have some problems to solve in the process. This way I can do foced air for the cabin and green house and heat water as needed

Use the heat stored in the sand to heat air and pump the air to the dwelling / greenhouse.
Eliminate the complexity and expense of liquid handling altogether.
Used aircon ducts are usually available in metal scrapyards. Cheers

I've been researching subject for long time, use ceramic medium, best guess is chimney prefabs. Use nitrogen as heat transfer medium and air turbines to move heat around, can place turbine on cold side. I'm aiming for temperatures reaching 700+C here, borderline stainless steel heat, because it's in later parts in my project where stainless is inevitable at one point of it.
Liquid salt and liquid sodium is too corrosive, for your small scale I'd suggest using nitrogen as neutral medium. Can use existing evacuated tubes and parabolic mirrors. For your use best is steel water pipes that are stick weld and have nitrogen running trough it. Obvious side note, you need air pump engine well separated from blades and any regular bearings.

We plan on using MINERAL OIL ( it's Inert ) 350F / 180C. Run through Pex using a Solar style water heater/collector with a 1 watt Car water pump. Its simple. System is buried in IBC totes under ground wrapped ( set ) in aircrete. Return closed loop is water ( easy clean up should there be any future failures to the system ) run through hydro radiators. Great Preheater to add to any Hot water system.

For charging use electric Resistive Heating and solar. Vehicle Glow plugs can heat to 1400C. Stove elements can heat to 900C. For extracting heat look at copper pipe and air to a holding water tank like you discussed. I wonder what a regular hot water tank filled with sand would do if the aquastats are modified for high heat?

A 70s solar system used air blowers from a solar collector to an insulated gravel heat storage running year long collecting heat during the summer and releasing it in the winter. Gravel was used to make the air pass through it easier to move throughout.

I'm Canadian situated in Quebec and I've been looking into this for a long time. Like said before we need to follow the KISS principal. I think that using a heat pump to move heat from a lower temp source to a high temp storage might be the way to go. I'll be looking at a 4 port system soon where I can use 2 ports to store/retrieve heat from the storage and 2 ports for house HVAC. Might be even better with only one circuit to control heat transfer both ways from the battery.

I did the calculation on my side ( with density and specific heat value of sand ) and I need about 60 000 liters of sand ( 60 cubic meter ) at a temperature of 500 degres celcius to cover my heating needs during winter in Canada. That's enormous ! It's about 10 000kWh of heating energy needed and perfectly isulated. So probably to cover the heat loss , need more than that.

Hello, and thanks for the video. I am planning a similar project. You mention Aircrete, maybe look at foamcrete instead, as aircrete are prone to water permetation and consequently cracking.

schedule 80 steel pipe, used full synthetic motor oil (it is free from your local garage) it will not burn until it gets to 450*F not as high as you could heat sand but it is the most cost effective thing I have found so far, consider using sea shipping containers for your storage, and rockwool insulation (the only insulation that can take 1500*F ) Ive been giving this system a lot of thought for a central heating system for my farm. Resistive heat is horribly inefficient. Im thinking a heat pump would work better... if I charge the sand in the summer the wast cold could be used to cool the house and green houses. Im in NH and we will build deep winter greenhouses that are insulated on all but the south side, so will only need added heat for 3 months. We are still working on design and collecting building materials and will start building summer of 2023. best of luck to everyone trying to figure out this problem!

Transfer the heat from the parabolic collectors with air. It's free and no need to worry about leaks. Keep the blower fans on the cooler inlet side. Water coils in the sand can transfer heat to the house. The collected air from the top of the thermal sand storage can flow through the greenhouse before is goes back to the solar collectors, or just circulate the warm air to the greenhouse on cloudy days. Water coils in the hotter parts of the sand can be used to power steam generators for electricity.

I imagine a large insulated storage container with two sets of copper tubing coiled inside surrounded by sand. One set of tubing circulates heated air from a standard electric heater through the sand and heats it, the other tube also full of air which is heated from the sand is ducted to a fan in your house or greenhouse. The sand heater operates during the day, usually powered by excess solar. The fan that circulates the heated air inside the house can run at any time but in daytime will usually be solar as well. I’m just not sure if the air will be too hot straight out of the sand battery and the best way to manage that. If it is is too hot then I’d siphon off some of the super hot air, mix it with outside air to cool it to the right temp before releasing it in the house.

The best system I have seen is much simpler and does use sand. My friend built a concrete building 10x10x10 he used concrete blocks but I would use the styrofoam concrete forms that lock together. Down the middle of the building is a wood stove custom made 2’x2’x9’. The stove is ruggedly built to withstand the weight of the sand. He also used a 16 foot length of 6 inch steel well casing as a chimney welded into the top of the stove. The building has styrofoam placed on the inside of the block walk to keep the heat in and also on the top. The stove is completely covered in sand and a system of pipes are distributed through the sand which goes all the way up to the top of the building. Water is pumped through the sand with ordinary circulator pumps out to his house. He actually rigged the plumbing to his existing oil boiler so he can heat his home with existing piping and radiators. He lights a small fire once every couple of days to maintain the temperature in the heat sink. He has antifreeze in the lines so it won’t freeze if he isn’t using it in the winter. The thing that is better about this system is that there is no creosote buildup because the water doesn’t contact the firebox directly. Also those water jacket heaters only hold so much water and don’t store the heat. My friend also has a domestic water coil going through the heat sink. If he goes away during cold weather he has to blow out the domestic coil because it has no antifreeze. This system can be adapted to use in greenhouses and other uses.

I'm hoping there is a series to follow, where you build this. I've been thinking of building something like this for a while. I suspect that is the famous 1% Inspiration, and the years of refinement ahead the 99% perspiration. The pattern of pipes through your sand, whether you heat/extract from the whole mass evenly, or use it as a series of units, with maybe colder areas still maybe having use for a greenhouse, using air flow, and saving some areas, so you still have piping hot water by spring. Control systems are probably the make or break in a project like this. Where I'm from, PV is the only real solar option, but powering resistive, or radiany heat with those, should be very efficient. I wouldn't get hung up on only collecting solar-thermal energy.

I did some research on this very idea. I learned that asphalt will hold more heat, up to a certain point, than any other earthly material.

Got this figured out already. I’ll be sharing it on my UA-cam channel soon.

I believe that the best working fluid for transferring heat to/from your sand battery may be MINERAL OIL. It seems to fit all of your requirements, while also having advantages over other fluids. As an alternative, you may also check into using cottonseed oil or rapeseed oil (also known as Canola oil) as these last two choices are more biodegradable.
I saw a couple of suggestions to use water with antifreeze, but that will start to boil at about 226 F (108 C) at atmospheric pressure w/ a 50/50 mix of water and antifreeze. You wanted a fluid that would handle about 300 C. So I don't think this is a good choice.
Some facts about MINERAL OIL:
> It is already used as a working heat-transfer fluid in products like electrical radiators, power pole transformers and high-voltage applications.
> The maximum operating temperature is 316 C (600 F)
> Boiling point at atmospheric pressure is 349 C (657 F)
> It is essentially non-toxic and more importantly essentially non-toxic to humans/animals
> It is odorless and colorless
> It does not conduct electricity
> It can be purchased in both industrial grades and food-safe grades
Sources:
www.multitherm.com/multitherm-pg-1.html
en.wikipedia.org/wiki/Mineral_oil
Ed Schultheis, PE
Mechanical design engineer for 35 years
My consulting business
Schultek Engineering & Technology, Inc.
schultek.com

As a proof of concept for sand I would personally start with your boiler and building an enclosure around it and filling it with sand. Then the system can grow with solar collectors.

Video just popped up again, haven't seen any follow up but a few channels fail to notify. Anyway, consider how much energy your 300C sand actually holds per volume and then look at water in reverse: what is the local groundwater temp and how much water would be required to absorb your heat to below boiling?
Depending on how you plan to access/ use the stored heat you could set up a steam turbine generator for electric which could also absorb some energy transfer. You could stall the steam in tanks buried in sand with valves that release the steam/ pressure through other turbines/ tanks until it's just hot water of the desired temperature to heat the house and fill the water heater.
This would also distill the water in process.

Used and spent motor oil might be an affordable solution in some areas. Switching to an oil burner isn't the most eco friendly. However that also allows you the opportunity to meet with more mechanics that might be able to help. Hydraulic fluid is pretty useful as it can take a ton of heat and is designed to be pumped. However you heat it, you can contain it in 55 gallon motor oil drums and cycle it through a radiator.
Heliostats are great in sunnier places than Manitoba. Honestly an automated pellet stove hooked up to wifi for the auger might be the simplest solution to what you're trying to manage. Just elevate the hopper that feeds the augur and maintain it as necessary.

Could I hook up the exhaust of a mini split to help charge the battery and if so how?

The flow rate of the liquid through the sand determines contact time which regulates thermal energy absorbed by the liquid. You could run water through 1,000° sand and adjust your flow rate so that the output temperature is 70° (or whatever you desire).

Sand battery is probably one of the most interesting idea to store heat energy for a long time. I am thinking about to realize that in a small scale, just for an alternative heating source for my house. Interesting question is, how to transfer heat out of the battery (in my case, intake goes trough electric heating element attached to a solar system)? Well, i think the cheapest version is the air (free available, heat resistant) . Also, you can use it in some kind of heat exchanger to heat up oil, watter or even another separated airflow like room heating with air.

Talk about this... to transfer heat from wood stove to sand, try air, thru steel pipe. Wood exhaust contains VOCs so we'll need to use a filter or transfer device to keep our hot air clean. For pumping hot air, use the hot end of auto turbocharger, cold end replaced with electric motor. Other thoughts: supercharge (compressed air) the wood combustion chamber, electrostatic exhaust filter at other end.

Boiler technician here. Water reaching those temperatures to me sounds like it would be a good idea to get a bladder tank, to give the heating and expanding water somewhere to expand into so it doesn't drive up the pressure and burst your copper. Also, if anyone is going to solder this together, they should remember to wipe their joints with a rag afterwards. So common is a situation where they don't do this and the joints all leak within a couple of years, because the flux is acidic. I really don't know about the longevity of ProPress joints. They are working like a charm for my boiler team so far, but it is probably a better idea to not have any joints or fittings inside your thermal battery; just continuous unbroken loops of copper, so that if one should burst on you, you can more easily repair it.

I would look at conducting tubing both electrically and thermally. It serves as both electrical heating element and air conduit. Bury such a tubing array in the sand. Use the output of the solar panels to power electrical heater. Run an air pump to circulate air through the tubing.

Make a manifold out of concrete or any metal or high temp pipe, bury it in an insulated sand box with pipes, and run hot air through it, and at night it should hold heat, also you could just put the whole thing under the house, just use separate pipes that lay on top of the block and go back into the house for heat at night, the out side could have a temp thermostat ,on, off fan could be solar with small battery back up. Also you have radiators, you cold bury a tank or manifold in the sand box, circulate the water through everything, have a high pressure safety valve outside and in. The sand should take a lot of the heat out, just have a shut off for high heat that way the temp won't go too high, or loop the water that is in the radiators somehow, till the temp drops, separate from the solar setup, Just ideas that may or may not work! but good video, and I also subscribed!

For a small room/ green house i would say: buy an green egg /ceramic bbq, fill it with sand/ basalt. Stick some 12v ceramic heating elements ptc in it on and connect them the solar pannels. Use the lid to regulate the heat.

In looking into this it appears to be advantageous to put rock on the top of the sand before the aircrete enclosure. In that enclosure heat of course tends to rise and the rocks can store additional heat before the aircrete insulation comes into play .....

Have you looked at Russ Finch's methods for growing things in cold climates? If I had a big enough property that is the way I would heat things up like a green house. I'm just starting to look at sand heating and storage for some around the house ideas so I'm just beginning my experimentation. My first challenge is to see how hot I can get sand with just the sun.

I learned a lot. Will try some version of this in my greenhouse

The Know You Know channel had an item about Polar Night Energy, 2 weeks ago

Using this concept and pv thermal hybrid panels should work great.

You could use photovoltaics to run an electric heater to heat air and blow it through tubes in a sand battery. The same hot air would be recycled around in a closed loop and continuously reheated by the electric elements of a heater. I don't know how hot you could get it but I would think you could get it to at least 500 degrees like an oven.

You can use black steel pipes with fiberglass insulation and for the temp regulation you can use a mixing valve and a heat exchanger from oil to glycol. Great video, thanks.

For heating the house, I think hot air can be used. That will be easier then setting up additional hot water system.

I wonder if blowing heated air bubbles through the sand from the bottom up would help distribute the heat throughout the sand better than running pipes through the sand.

I've seen fans that run on heat so that attached where the heat source feom the sun is and blowing the heated air into pipes that go into sand will heat the sand or water barrels/tanks so heat is held for when the sun goes down. Just a thought.

David Poz has a series of videos regarding his water storage tank and solar water heating panels system. It's just a bit small for his usage, but it gives him up to three days of autonomy. And that is what thermal storage is all about, right? The more days of autonomy the better.

Love the thinking here. Check out Curtis stones passive solar greenhouse. Insulated packed sand with air tubing running underground. Takes hot air from greenhouse pumps under ground, cooler air comes out. Inverse in winter.
Would be interesting to combine liquid lines underground

What has a better thermal coefficient for a heat battery medium, clay or sand?

what about used motor that has been filtered?

Could you run steam pipes through the heated sand into a steam turbine and make electricity?

Love the channel and your goals. Ya! Making it for cheap is the biggest problem and requires genius solutions. Hot tropical climate here. I need cooling ideas. I have seen the tube in colder water video. I will think and come back with ideas.

Very interesting. Been moving in this direction for a while. Still in progress

Air to water heat exchanger is used in such high temperature sand storage systems in Finnland for example!
Concentrated to high temperature solar beam should be used to charge that sand heat storage.

Here are a few thoughts for you. 1. oils and other chemicals are costly and in the case of a spill, may cost a fortune to clean up. If you used oil for pumping the heat into the sand, simplest solution for retrieving the heat is obviously air. Liquid salts are very abrasive and will destroy most piping quickly if I understand that correctly. If you are storing heat, you could even use a Stirling engine to convert some of the heat to electric.

Hey I run an induction furnace and a rolling mill. So we manufacture rebar rods. So after its final stage the rebar is about 300-400 degree on the cooling bed. Is there a way to store that much of heat and then translate in to an energy.

Some back of the envelope calculations.
4,19 kJ/(K·kg) *100kg*100K=41 900kJ
0,84 kJ/(kg*K)*100kg*1000K=84 000kJ
So yes you can store more heat in sand if you heat it to 1000C but I still would say that water is better choice. 1000C is good forging temperature and I suspect materials that can handle that are quite expensive (at least for small scale).
Still sand is far better choice than I anticipated. You might even be able to do it without any piping in the sand itself, just pump air trough the sand.

I've just finished lining the interior wall of my house with 20mm corrugated cardboard filled with very fine sand to act as acoustic barriers and a thermal heat sink, we'll see how well it works later this year.
My suggestion would be to buy 9 cheap copper electric immersion heaters. Remove the immersion units and fill each one with your copper piping and sand. Then sink each one of those units into a concrete "jacket" in a 1, 2, 3, 2, 1 layout and surround that jacket with the water. Concrete has excellent thermal mass itself, is easy to insulate all around, has high heat tolerance, and it's water tight. With individual "heating units" units you can easily replace/upgrade when needed.

Air under the sand should rise through the sand while heating so long as it remains dry and you have coarse sand. Delivery of the air could be as simple as metal piping to molded holes in the air create.

When I was first looking at solar I studied what the government had been using for their receiver type solar platforms. What they were doing was they concentrated the mirrors on piping that contained oil. That heating up of the oil created flow within the system, which turned an electricity generator. I do believe that you should be fine using oil for your transfer medium without any need for a pumping system. I do think that you should consider a piping solution that can handle the built up heat and pressure if you do this.

Consider a concentrated reflector system directly heating an air-crete box of sand with one window wall lined on the interior with cupric-oxide. An air gapped box around that box (thus two layers of window) could collect heat losses of the sand box into a lower temp storage like water.

There was a solar pond in Miamisburg OH that was built by Monsanto. They used black plastic as the liner and salt water to hold the heat. They were around for a long time, so they must have worked.

Regular store bought PVC pipe can go to 140 F or 60 C. While it won't be the primary "coil" it certainly might work in a return/transfer circuit.

Really need mother of invention
Mashallah good job

Well a cubic metre of sand stores 105 MJ for a heat difference of 30C, while a cubic metre of water stores 125 MJ. So water is better up to 100 C. The advantage of sand/rock is that a much higher temperature differential is available. But, as you say, and as my own contemplations have found, the complexity of dealing with temperatures over 100C on a domestic set up are too much. I can buy at 30 cubic metre plastic or concrete water tank for about $3000, and if that is heated to say 60 degrees above ambient, then I have 7560 MJ of energy stored there. Foam concrete insulation, plus fibre glass batts would slow heat loss enough and such a system would be affordable and simple enough to build. Hot rock/sand with say high pressure air to transport heat from the solar concentrator is just toooooo hard for the ordinary person. A bit of warm water plumbing and a few circulator pumps is a simple job..
7560 MJ is equivalent to 70 days heating at 30 kWh per day. Even assuming 50% lost via heat losses, and another 50% lost via poor transfer effeciencies, that is 35 days at 15 kWh per day. If your heat capture panels are able toget anything like 30 kWh input on a normal winter day, then you are safe for the full year's space heating providing you don't get more than 15 days rubbish weather in a row. You would see the storm coming anyway, and button up tight to conserve the resource. That sounds viable to me. Rocks or sand? Too hot to handle, IMHO..

What about using a water as a transfer liquid and then a heat pump with heat exchanger to heat up the sand with hot air injection?

You move from vac tubes to other solar very quickly. I reciently filled a vac tube with salt. Installed a thermocouple and stuffed the top with insulation. I don’t know how hot it got because the thermocouple quit working at 500F - 260C. These will work year round for heating oil but seals may be the concern.

Try lining the bottom with a structural foam like foamglas. You may require reinforcing the bottom of the structure through areas of the insulation to take some weight off the foam (it depends on the vertical axis of your tank and the specific density of the sand you're using (I don't imagine any variety you'd want to use being too different from any other).
I'm thinking there could be benefit to designing the battery with a larger, flatter footprint (potentially, a roof mounted "sand panel" could work but thickness will increase weight while adding more total thermal storage potential per sq ft of panelling or a wide silo on the ground for larger applications) would allow an air channel to be added. This could be used to preheat incoming air to the HVAC system during the winter by "boiling" air through the sand inside the channel from bottom to top. The channel or pipe would be filled with sand and completely surroubded by sand, so it will easily regain heat lost through use simply through its metal housing being a part of the battery.

Love the idea of using aircrete (which I was thinking of doing myself) for the insulation on your storage tank. You could build the tank entirely out of aircrete and rebar OR you could buy a metal water tank (like a livestock tank) and insulate it by filling aircrete around it.
Storing heat that will be used for heating is easy enough, but storing heat and transferring it into electricity to cover the other 40% of your homes electricity demands when the sun isn't out is the real challenge.

Peltier devices heated by that sand, cooled on the cold side by the ambient air above the sand would produce a fabulous instant voltage. You need a good quality peltier, like those used on spacecraft.

The higher the temperature the higher the losses. The best way to my mind would be to pump the heat into the ground in the summer, then extract in the winter. The heat wouldn't heat your home for long without the aid of a heat pump, that's the only issue! Greenhouse would perhaps keep it ice free year round.. although the losses from a greenhouse are massive.

I am thinking of somethint like this. The main problem with the soil is the heat transfer and the poor heat capacity. If you use a liquid with 300 celsius of maximum temperature, you can heat the sand also maximum to this temperature. The volumetric heat capacity of the soil is about 1.8MJ/m3. Water can store 4.18MJ/m3. The energy you win by the higher temperature, you loose by the poorer heat capacity. What about to build a well isolated huge water tank above the ground? 10 or 20 cubuc meter capacity? You could heat it all year with a simple water based heat collector, then you could take the energy out by a heat pump.

Check out Korean traditional floor heating system ... basically a giant rocket stove under the ground that could heat the sand which will radiat a constant temperature all night !

This would be increadibly practical in an apartment complex or better yet a neighborhood planned around low-tec systems like this

You're worried about 300 F deg air being too hot for your house. So at a convenient point after you've extracted the heated air from your sand-mass, mix it with a variable amount of external air to achieve a reasonable temp. for your home. The engineering for the mixing area might be expensive (in order to not lose your original stored energy), but I'm not an expert. Or another idea, just pump the 300 F deg right into an old-fashioned floor radiator (the kind originally built for steam).

That's what I start reading comments and lose what I had to put down. I was very interested in the beginning how you were going to store heat throughout the winter.
If you have to put heat into the sand you could just as well easily put it into your house (when the sun's available). I'm not sure I would try or waste time storing the heat in the ground unless it was under the house. Maybe build the sand battery in the walls instead.
Thanks for some ideas!

Have you thought about moving the sand? My knee jerk reaction is to say it would cost too much to move the sand except in a separate battery project moving sand is the actual solution to a physical electric battery. I wonder if you could combine those 2 systems. The sand is slowly moved upwards by (excess) solar panel power via a standard motor. But move it upward on a parabolic mirror trough. As it goes up it is storing both potential energy and heat. Once it's hot, drop it off the trough and into your aircrete tank which is 20 feet off the ground or on a hill or cliff if available. When your batteries need charging or you are cold you drop the hot sand down a pipe and collect the electric via inverter and the hot sand lands inside your green house where you blow a fan it to extract the heat into the air. The sand sits in some sort of "sand radiator" until it's cold and you use a microcontroller to open the flap at the bottom and the sand drops out into the base holding tank where it waits for a sunny day to make it's trip back up the mirror trough. I like this idea so much I'm going to try it. Thanks for the inspiration.

I would think a multi-level system would be necessary to utilize the all the heat actually available. I do however have a question... What is the most efficient way to extract the heat once stored?

Going in blind.
I would go with Iron piping in a sand pit. Just use air to charge it in the summer. And air to siphon out the heat. The higher the temperature the less air you need to move throughout the system.

just use multiple mirrors to focus down a light tube to the base of the sand/ granite chips extract heat using steel piping and air. been working on this for years.....live long and prosper
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If you build the collector on a big home made lazy Susan, alignment would be easy. I would try mineral oil if you can get it.olive oil can go rancid.

Use an Archimedes screw to move sand through a solar trough?