Siukkola Sand Battery -- article & 3 patents

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**Timo SIUKKOLA**  
**Sand Battery**

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[**https://www.thestorage.fi/post/hot-sand-for-a-cooler-climate**](https://www.thestorage.fi/post/hot-sand-for-a-cooler-climate)**Hot sand for a cooler climate: scalable sand-based heat
storage cuts industrial emissions by up to 90%**  
  
**Sand as the industryas green energy bank**  
  
TheStorageas technology captures electricity when it is abundant
and cheap, converts it intohigh-temperature heat, and stores it
in sand. This stored heat can be used in industrial processes
independently of real-time electricity availability. aCompanies
have wanted to decarbonize for years, but viable solutions
simply weren't available. Finally, renewable energy generation
can meet industrial heat demand in a way that's both
ecologically sound and economically practical,a says Timo
Siukkola, CEO of TheStorage.  
  
The principle of the sand-based heat storage is simple. The
proprietary technology stores heat in ordinary sand using two
insulated silos, an electric heater, and a heat exchanger.  
  
Cool sand moves from a cold silo to an electric heater, reaching
temperatures up to 800A degC. The heated sand is then stored in a
hot silo, where energy is efficiently retained in stationary
sand. By circulating the sand through an external heat
exchanger, the system delivers steam with up to tenfold higher
heat transfer efficiency compared to conventional static storage
systems.  
  
Thestored heat can be released on-demand as steam or thermal
oil, providing stable power that can be quickly adjusted to
match demand. The solution is scalable from 20 to 500 MWh with
charging power from 1 to 20 MW, depending on industrial needs.
The technology allows fully flexible operations in both charging
and discharging.  
  
Fossil-free industrial heat is central to achieving EU climate
goals, which target a 90% emissions reduction by 2040 and full
carbon neutrality by 2050. For companies, these targets are no
longer long-term aspirations - they are increasingly concrete
obligations: the Corporate Sustainability Reporting Directive
(CSRD) requires large and medium-sized companies to report on
energy use and emissions, while the EU Emissions Trading System
(ETS) makes fossil fuel use increasingly expensive.  
  
"Heat emissions now appear simultaneously in sustainability
reports, energy costs, and customer requirements," Siukkola
explains. Pressure comes not only from regulation, but also from
international corporations, which increasingly require suppliers
to demonstrate measurable emission reductions under the Science
Based Targets initiative (SBTi)."This forces industrial
companies to reconsider how they produce heat to remain
competitive in global supply chains," Siukkola concludes.  
  


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![](SandBatterySchematic.jpg) ![](Sandbattery1TheStorage.jpg)

   


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**PATENTS**

  
**Inventor: SIUKKOLA TIMO**  
**Applicant: BUFFER SOLUTIONS**  
  
**A DISCHARGING DEVICE AND A METHOD FOR AN ENERGY STORAGE
SYSTEM**  
**[FI20245073](FI20245073A1.pdf) 
//  WO2025153774**  
  
A discharging device utilizes solid particles (5), for example
sand particles, which are heated by the electric power from the
renewable energy power plant. The solid particles (5) are
fluidized by gas from a static solid-like state to a dynamic
fluid-like state. The discharging device has multiple adjacent
heat transfer modules (11 - 18), which are each partially
separated by a module wall (21 - 27). The module wall (21 - 27)
between adjacent heat transfer modules has an opening (31 - 34)
in the module wall (21 - 27) to allow the fluidized solid
particles (5) to travel to adjacent heat transfer module (11 -
18). The fluidized solid particles (5) travel horizontally from
the particle inlet via adjacent heat transfer modules (11 - 18)
and through said opening (31 - 34) to the particle outlet (59)
of the last heat transfer module (14, 15, 18).  
  
  
**A METHOD FOR STORING HEATED PARTICLES AND A PARTICLE
CONTAINER FOR AN ENERGY STORAGE SYSTEM**  
[**WO2025153775**](WO2025153775A1.pdf)  
  
An energy storage system utilizes solid particles that are
heated by the electric power from the renewable energy power
plant. A particle container comprises a cylindrical particle
chamber (10) for storing particles (5), that are heated for
example at a heat exchanger of the energy storage system. The
particle chamber walls (11) are made of a refractory material.
Between the particle chamber walls (11) and the support wall
(13) is a space (12) that is filled with solid particles (6).
These solid particles (6) are purposed to stay in said space
(12), and act as an insulation for the particle chamber (10) and
to provide flexibility to accommodate the thermal expansion of
the particle chamber (10).  
  
**A HEAT EXCHANGER AND A METHOD FOR AN ENERGY STORAGE SYSTEM**  
[**FI131819**](FI131819B1.pdf)  
  
A heat exchanger utilizes solid particles (5), for example sand
particles, that are heated by the electric power from the
renewable energy power plant. The solid particles (5) are
fluidized by gas from a static solid-like state to a dynamic
fluid-like state. The heat exchanger has multiple adjacent heat
transfer modules (11 - 18), that are each partially separated by
a module wall (111, 121, 131, 141). The module wall (111, 121,
131, 141) between adjacent heat transfer modules has an opening
in the module wall to allow the fluidized solid particles (5) to
travel to adjacent heat transfer module (11 - 18). The fluidized
solid particles (5) travel horizontally from the particle inlet
(41) via adjacent heat transfer (11 - 18) modules and through
said opening to the particle outlet (42) of the last heat
transfer module  
  


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