Jump to content

Thermal energy storage

From Wikipedia, the free encyclopedia
(Redirected from MSES)

District heating accumulation tower from Theiss near Krems an der Donau in Lower Austria with a thermal capacity of 2 GWh
Thermal energy storage tower inaugurated in 2017 in Bozen-Bolzano, South Tyrol, Italy.
Construction of the salt tanks at the Solana Generating Station, which provide thermal energy storage to allow generation during night or peak demand.[1][2] The 280 MW plant is designed to provide six hours of energy storage. This allows the plant to generate about 38 percent of its rated capacity over the course of a year.[3]

Thermal energy storage (TES) is the storage of thermal energy for later reuse. Employing widely different technologies, it allows surplus thermal energy to be stored for hours, days, or months. Scale both of storage and use vary from small to large – from individual processes to district, town, or region. Usage examples are the balancing of energy demand between daytime and nighttime, storing summer heat for winter heating, or winter cold for summer cooling (Seasonal thermal energy storage). Storage media include water or ice-slush tanks, masses of native earth or bedrock accessed with heat exchangers by means of boreholes, deep aquifers contained between impermeable strata; shallow, lined pits filled with gravel and water and insulated at the top, as well as eutectic solutions and phase-change materials.[4]

Other sources of thermal energy for storage include heat or cold produced with heat pumps from off-peak, lower cost electric power, a practice called peak shaving; heat from combined heat and power (CHP) power plants; heat produced by renewable electrical energy that exceeds grid demand and waste heat from industrial processes. Heat storage, both seasonal and short term, is considered an important means for cheaply balancing high shares of variable renewable electricity production and integration of electricity and heating sectors in energy systems almost or completely fed by renewable energy.[5][6][7][8]

Categories

[edit]

The different kinds of thermal energy storage can be divided into three separate categories: sensible heat, latent heat, and thermo-chemical heat storage. Each of these has different advantages and disadvantages that determine their applications.

Sensible heat storage

[edit]

Sensible heat storage (SHS) is the most straightforward method. It simply means the temperature of some medium is either increased or decreased. This type of storage is the most commercially available out of the three; other techniques are less developed.

The materials are generally inexpensive and safe. One of the cheapest, most commonly used options is a water tank, but materials such as molten salts or metals can be heated to higher temperatures and therefore offer a higher storage capacity. Energy can also be stored underground (UTES), either in an underground tank or in some kind of heat-transfer fluid (HTF) flowing through a system of pipes, either placed vertically in U-shapes (boreholes) or horizontally in trenches. Yet another system is known as a packed-bed (or pebble-bed) storage unit, in which some fluid, usually air, flows through a bed of loosely packed material (usually rock, pebbles or ceramic brick) to add or extract heat.

A disadvantage of SHS is its dependence on the properties of the storage medium. Storage capacities are limited by the specific heat capacity of the storage material, and the system needs to be properly designed to ensure energy extraction at a constant temperature.[9]

Molten salt technology

[edit]

The sensible heat of molten salt is also used for storing solar energy at a high temperature,[10] termed molten-salt technology or molten salt energy storage (MSES). Molten salts can be employed as a thermal energy storage method to retain thermal energy. Presently, this is a commercially used technology to store the heat collected by concentrated solar power (e.g., from a solar tower or solar trough). The heat can later be converted into superheated steam to power conventional steam turbines and generate electricity at a later time. It was demonstrated in the Solar Two project from 1995 to 1999. Estimates in 2006 predicted an annual efficiency of 99%, a reference to the energy retained by storing heat before turning it into electricity, versus converting heat directly into electricity.[11][12][13] Various eutectic mixtures of different salts are used (e.g., sodium nitrate, potassium nitrate and calcium nitrate). Experience with such systems exists in non-solar applications in the chemical and metals industries as a heat-transport fluid.

The salt melts at 131 °C (268 °F). It is kept liquid at 288 °C (550 °F) in an insulated "cold" storage tank. The liquid salt is pumped through panels in a solar collector where the focused sun heats it to 566 °C (1,051 °F). It is then sent to a hot storage tank. With proper insulation of the tank the thermal energy can be usefully stored for up to a week.[14] When electricity is needed, the hot molten salt is pumped to a conventional steam-generator to produce superheated steam for driving a conventional turbine/generator set as used in any coal, oil, or nuclear power plant. A 100-megawatt turbine would need a tank of about 9.1 metres (30 ft) tall and 24 metres (79 ft) in diameter to drive it for four hours by this design.

A single tank with a divider plate to separate cold and hot molten salt is under development.[15] It is more economical by achieving 100% more heat storage per unit volume over the dual tanks system as the molten-salt storage tank is costly due to its complicated construction. Phase Change Material (PCMs) are also used in molten-salt energy storage,[16] while research on obtaining shape-stabilized PCMs using high porosity matrices is ongoing.[17]

Most solar thermal power plants use this thermal energy storage concept. The Solana Generating Station in the U.S. can store 6 hours worth of generating capacity in molten salt. During the summer of 2013 the Gemasolar Thermosolar solar power-tower/molten-salt plant in Spain achieved a first by continuously producing electricity 24 hours per day for 36 days.[18] The Cerro Dominador Solar Thermal Plant, inaugurated in June 2021, has 17.5 hours of heat storage.[19]

Heat storage in tanks, ponds or rock caverns

[edit]

A steam accumulator consists of an insulated steel pressure tank containing hot water and steam under pressure. As a heat storage device, it is used to mediate heat production by a variable or steady source from a variable demand for heat. Steam accumulators may take on a significance for energy storage in solar thermal energy projects.

Large stores, mostly hot water storage tanks, are widely used in Nordic countries to store heat for several days, to decouple heat and power production and to help meet peak demands. Some towns use insulated ponds heated by solar power as a heat source for district heating pumps.[20] Intersessional storage in caverns has been investigated and appears to be economical[21] and plays a significant role in heating in Finland. Energy producer Helen Oy estimates an 11.6 GWh capacity and 120 MW thermal output for its 260,000 m3 water cistern under Mustikkamaa (fully charged or discharged in 4 days at capacity), operating from 2021 to offset days of peak production/demand;[22] while the 300,000 m3 rock caverns 50 m under sea level in Kruunuvuorenranta (near Laajasalo) were designated in 2018 to store heat in summer from warm seawater and release it in winter for district heating.[23] In 2024, it was announced that the municipal energy supplier of Vantaa had commissioned an underground heat storage facility of over 1,100,000 cubic metres (39,000,000 cu ft) in size and 90GWh in capacity to be built, expected to be operational in 2028.[24]

Hot silicon technology

[edit]

Solid or molten silicon offers much higher storage temperatures than salts with consequent greater capacity and efficiency. It is being researched as a possible more energy efficient storage technology. Silicon is able to store more than 1 MWh of energy per cubic meter at 1400 °C. An additional advantage is the relative abundance of silicon when compared to the salts used for the same purpose.[25][26]

Molten aluminum

[edit]

Another medium that can store thermal energy is molten (recycled) aluminum. This technology was developed by the Swedish company Azelio. The material is heated to 600 °C. When needed, the energy is transported to a Stirling engine using a heat-transfer fluid.

Heat storage using oils

[edit]

Using oils as sensible heat storage materials is an effective approach for storing thermal energy, particularly in medium- to high-temperature applications. Different types of oils are used based on the temperature range and the specific requirements of the thermal energy storage system: mineral oils, synthetic oils are more recently, vegetable oils are gaining interest because they are renewable and biodegradable.[27][28] Numerious criteria are used to select an oil for a particular application: high energy storage capacity and specific heat capacity, high thermal conductivity, high chemical and physical stability, low coefficient of expansion, low cost, availability, low corrosion and compatibility with compounds materials, limited environmental issues, etc.[29] Regarding the selection of a low-cost or cost-effective thermal oil, it is important to consider not only the acquisition or purchase cost, but also the operating and replacement costs or even final disposal costs. An oil that is initially more expensive may prove to be more cost-effective in the long run if it offers higher thermal stability, thereby reducing the frequency of replacement.[29]

Heat storage in hot rocks or concrete

[edit]

Water has one of the highest thermal capacities at 4.2 kJ/(kg⋅K) whereas concrete has about one third of that. On the other hand, concrete can be heated to much higher temperatures (1200 °C) by for example electrical heating and therefore has a much higher overall volumetric capacity. Thus in the example below, an insulated cube of about 2.8 m3 would appear to provide sufficient storage for a single house to meet 50% of heating demand. This could, in principle, be used to store surplus wind or solar heat due to the ability of electrical heating to reach high temperatures. At the neighborhood level, the Wiggenhausen-Süd solar development at Friedrichshafen in southern Germany has received international attention. This features a 12,000 m3 (420,000 cu ft) reinforced concrete thermal store linked to 4,300 m2 (46,000 sq ft) of solar collectors, which will supply the 570 houses with around 50% of their heating and hot water. Siemens-Gamesa built a 130 MWh thermal storage near Hamburg with 750 °C in basalt and 1.5 MW electric output.[30][31] A similar system is scheduled for Sorø, Denmark, with 41–58% of the stored 18 MWh heat returned for the town's district heating, and 30–41% returned as electricity.[32]

“Brick toaster” is a recently (August 2022) announced innovative heat reservoir operating at up to 1,500 °C (2,732 °F) that its maker, Titan Cement/Rondo claims should be able cut global CO
2
output by 15% over 15 years.[33]

Latent heat storage

[edit]

Because latent heat storage (LHS) is associated with a phase transition, the general term for the associated media is Phase-Change Material (PCM). During these transitions, heat can be added or extracted without affecting the material's temperature, giving it an advantage over SHS-technologies. Storage capacities are often higher as well.

There are a multitude of PCMs available, including but not limited to salts, polymers, gels, paraffin waxes, metal alloys and semiconductor-metal alloys,[34] each with different properties. This allows for a more target-oriented system design. As the process is isothermal at the PCM's melting point, the material can be picked to have the desired temperature range. Desirable qualities include high latent heat and thermal conductivity. Furthermore, the storage unit can be more compact if volume changes during the phase transition are small.

PCMs are further subdivided into organic, inorganic and eutectic materials. Compared to organic PCMs, inorganic materials are less flammable, cheaper and more widely available. They also have higher storage capacity and thermal conductivity. Organic PCMs, on the other hand, are less corrosive and not as prone to phase-separation. Eutectic materials, as they are mixtures, are more easily adjusted to obtain specific properties, but have low latent and specific heat capacities.

Another important factor in LHS is the encapsulation of the PCM. Some materials are more prone to erosion and leakage than others. The system must be carefully designed in order to avoid unnecessary loss of heat.[9]

Miscibility gap alloy technology

[edit]

Miscibility gap alloys [35] rely on the phase change of a metallic material (see: latent heat) to store thermal energy.[36]

Rather than pumping the liquid metal between tanks as in a molten-salt system, the metal is encapsulated in another metallic material that it cannot alloy with (immiscible). Depending on the two materials selected (the phase changing material and the encapsulating material) storage densities can be between 0.2 and 2 MJ/L.

A working fluid, typically water or steam, is used to transfer the heat into and out of the system. Thermal conductivity of miscibility gap alloys is often higher (up to 400 W/(m⋅K)) than competing technologies[37] which means quicker "charge" and "discharge" of the thermal storage is possible. The technology has not yet been implemented on a large scale.

Ice-based technology

[edit]

Several applications are being developed where ice is produced during off-peak periods and used for cooling at a later time.[38][39] For example, air conditioning can be provided more economically by using low-cost electricity at night to freeze water into ice, then using the cooling capacity of ice in the afternoon to reduce the electricity needed to handle air conditioning demands. Thermal energy storage using ice makes use of the large heat of fusion of water. Historically, ice was transported from mountains to cities for use as a coolant. One metric ton of water (= one cubic meter) can store 334 million joules (MJ) or 317,000 BTUs (93 kWh). A relatively small storage facility can hold enough ice to cool a large building for a day or a week.

In addition to using ice in direct cooling applications, it is also being used in heat pump-based heating systems. In these applications, the phase change energy provides a very significant layer of thermal capacity that is near the bottom range of temperature that water source heat pumps can operate in. This allows the system to ride out the heaviest heating load conditions and extends the timeframe by which the source energy elements can contribute heat back into the system.

Cryogenic energy storage

[edit]

Cryogenic energy storage uses liquification of air or nitrogen as an energy store.

A pilot cryogenic energy system that uses liquid air as the energy store, and low-grade waste heat to drive the thermal re-expansion of the air, operated at a power station in Slough, UK in 2010.[40]

Thermo-chemical heat storage

[edit]

Thermo-chemical heat storage (TCS) involves some kind of reversible exotherm/endotherm chemical reaction with thermo-chemical materials (TCM) . Depending on the reactants, this method can allow for an even higher storage capacity than LHS.

In one type of TCS, heat is applied to decompose certain molecules. The reaction products are then separated, and mixed again when required, resulting in a release of energy. Some examples are the decomposition of potassium oxide (over a range of 300–800 °C, with a heat decomposition of 2.1 MJ/kg), lead oxide (300–350 °C, 0.26 MJ/kg) and calcium hydroxide (above 450 °C, where the reaction rates can be increased by adding zinc or aluminum). The photochemical decomposition of nitrosyl chloride can also be used and, since it needs photons to occur, works especially well when paired with solar energy.[9]

Adsorption (or Sorption) solar heating and storage

[edit]

Adsorption processes also fall into this category. It can be used to not only store thermal energy, but also control air humidity. Zeolites (microporous crystalline alumina-silicates) and silica gels are well suited for this purpose. In hot, humid environments, this technology is often used in combination with lithium chloride to cool water.

The low cost ($200/ton) and high cycle rate (2,000×) of synthetic zeolites such as Linde 13X with water adsorbate has garnered much academic and commercial interest recently for use for thermal energy storage (TES), specifically of low-grade solar and waste heat. Several pilot projects have been funded in the EU from 2000 to the present (2020). The basic concept is to store solar thermal energy as chemical latent energy in the zeolite. Typically, hot dry air from flat plate solar collectors is made to flow through a bed of zeolite such that any water adsorbate present is driven off. Storage can be diurnal, weekly, monthly, or even seasonal depending on the volume of the zeolite and the area of the solar thermal panels. When heat is called for during the night, or sunless hours, or winter, humidified air flows through the zeolite. As the humidity is adsorbed by the zeolite, heat is released to the air and subsequently to the building space. This form of TES, with specific use of zeolites, was first taught by Guerra in 1978.[41] Advantages over molten salts and other high temperature TES include that (1) the temperature required is only the stagnation temperature typical of a solar flat plate thermal collector, and (2) as long as the zeolite is kept dry, the energy is stored indefinitely. Because of the low temperature, and because the energy is stored as latent heat of adsorption, thus eliminating the insulation requirements of a molten salt storage system, costs are significantly lower.

Salt hydrate technology

[edit]

One example of an experimental storage system based on chemical reaction energy is the salt hydrate technology.[42][43] The system uses the reaction energy created when salts are hydrated or dehydrated. It works by storing heat in a container containing 50% sodium hydroxide (NaOH) solution. Heat (e.g. from using a solar collector) is stored by evaporating the water in an endothermic reaction. When water is added again, heat is released in an exothermic reaction at 50 °C (120 °F). Current systems operate at 60% efficiency. The system is especially advantageous for seasonal thermal energy storage, because the dried salt can be stored at room temperature for prolonged times, without energy loss. The containers with the dehydrated salt can even be transported to a different location. The system has a higher energy density than heat stored in water and the capacity of the system can be designed to store energy from a few months to years.[44]

In 2013 the Dutch technology developer TNO presented the results of the MERITS project to store heat in a salt container. The heat, which can be derived from a solar collector on a rooftop, expels the water contained in the salt. When the water is added again, the heat is released, with almost no energy losses. A container with a few cubic meters of salt could store enough of this thermochemical energy to heat a house throughout the winter. In a temperate climate like that of the Netherlands, an average low-energy household requires about 6.7 GJ/winter. To store this energy in water (at a temperature difference of 70 °C), 23 m3 insulated water storage would be needed, exceeding the storage abilities of most households. Using salt hydrate technology with a storage density of about 1 GJ/m3, 4–8 m3 could be sufficient.[45]

As of 2016, researchers in several countries are conducting experiments to determine the best type of salt, or salt mixture. Low pressure within the container seems favorable for the energy transport.[46] Especially promising are organic salts, so called ionic liquids. Compared to lithium halide-based sorbents they are less problematic in terms of limited global resources and compared to most other halides and sodium hydroxide (NaOH) they are less corrosive and not negatively affected by CO2 contaminations.[47]

However, a recent meta-analysis [48] on studies of thermochemical heat storage suggests that salt hydrates offer very low potential for thermochemical heat storage, that absorption processes have prohibitive performance for long-term heat storage, and that thermochemical storage may not be suitable for long-term solar heat storage in buildings.

Molecular bonds

[edit]

Storing energy in molecular bonds is being investigated. Energy densities equivalent to lithium-ion batteries have been achieved.[49] This has been done by a DSPEC (dys-sensitized photoelectrosythesis cell). This is a cell that can store energy that has been acquired by solar panels during the day for night-time (or even later) use. It is designed by taking an indication from, well known, natural photosynthesis.

The DSPEC generates hydrogen fuel by making use of the acquired solar energy to split water molecules into its elements. As the result of this split, the hydrogen is isolated and the oxygen is released into the air. This sounds easier than it actually is. Four electrons of the water molecules need to be separated and transported elsewhere. Another difficult part is the process of merging the two separate hydrogen molecules.

The DSPEC consists of two components: a molecule and a nanoparticle. The molecule is called a chromophore-catalyst assembly which absorbs sunlight and kick starts the catalyst. This catalyst separates the electrons and the water molecules. The nanoparticles are assembled into a thin layer and a single nanoparticle has many chromophore-catalyst on it. The function of this thin layer of nanoparticles is to transfer away the electrons which are separated from the water. This thin layer of nanoparticles is coated by a layer of titanium dioxide. With this coating, the electrons that come free can be transferred more quickly so that hydrogen could be made. This coating is, again, coated with a protective coating that strengthens the connection between the chromophore-catalyst and the nanoparticle.

Using this method, the solar energy acquired from the solar panels is converted into fuel (hydrogen) without releasing the so-called greenhouse gasses. This fuel can be stored into a fuel cell and, at a later time, used to generate electricity.[50]

Molecular Solar Thermal System (MOST)

[edit]

Another promising way to store solar energy for electricity and heat production is a so-called molecular solar thermal system (MOST). With this approach a molecule is converted by photoisomerization into a higher-energy isomer. Photoisomerization is a process in which one (cis trans) isomer is converted into another by light (solar energy). This isomer is capable of storing the solar energy until the energy is released by a heat trigger or catalyst (then, the isomer is converted into its original isomer). A promising candidate for such a MOST is Norbornadiene (NBD). This is because there is a high energy difference between the NBD and the quadricyclane (QC) photoisomer. This energy difference is approximately 96 kJ/mol. It is also known that for such systems, the donor-acceptor substitutions provide an effective means for red shifting the longest-wavelength absorption. This improves the solar spectrum match.

A crucial challenge for a useful MOST system is to acquire a satisfactory high energy storage density (if possible, higher than 300 kJ/kg). Another challenge of a MOST system is that light can be harvested in the visible region. The functionalization of the NBD with the donor and acceptor units is used to adjust this absorption maxima. However, this positive effect on the solar absorption is compensated by a higher molecular weight. This implies a lower energy density. This positive effect on the solar absorption has another downside. Namely, that the energy storage time is lowered when the absorption is redshifted. A possible solution to overcome this anti-correlation between the energy density and the red shifting is to couple one chromophore unit to several photo switches. In this case, it is advantageous to form so called dimers or trimers. The NBD share a common donor and/or acceptor.

Kasper Moth-Poulsen and his team tried to engineer the stability of the high energy photo isomer by having two electronically coupled photo switches with separate barriers for thermal conversion.[51] By doing so, a blue shift occurred after the first isomerization (NBD-NBD to QC-NBD). This led to a higher energy of isomerization of the second switching event (QC-NBD to QC-QC). Another advantage of this system, by sharing a donor, is that the molecular weight per norbornadiene unit is reduced. This leads to an increase of the energy density.

Eventually, this system could reach a quantum yield of photoconversion up 94% per NBD unit. A quantum yield is a measure of the efficiency of photon emission. With this system the measured energy densities reached up to 559 kJ/kg (exceeding the target of 300 kJ/kg). So, the potential of the molecular photo switches is enormous—not only for solar thermal energy storage but for other applications as well.[51]

In 2022, researchers reported combining the MOST with a chip-sized thermoelectric generator to generate electricity from it. The system can reportedly store solar energy for up to 18 years and may be an option for renewable energy storage.[52][53]

Thermal Battery

[edit]

A thermal energy battery is a physical structure used for the purpose of storing and releasing thermal energy. Such a thermal battery (a.k.a. TBat) allows energy available at one time to be temporarily stored and then released at another time. The basic principles involved in a thermal battery occur at the atomic level of matter, with energy being added to or taken from either a solid mass or a liquid volume which causes the substance's temperature to change. Some thermal batteries also involve causing a substance to transition thermally through a phase transition which causes even more energy to be stored and released due to the delta enthalpy of fusion or delta enthalpy of vaporization.

Thermal batteries are very common, and include such familiar items as a hot water bottle. Early examples of thermal batteries include stone and mud cook stoves, rocks placed in fires, and kilns. While stoves and kilns are ovens, they are also thermal storage systems that depend on heat being retained for an extended period of time. Thermal energy storage systems can also be installed in domestic situations with heat batteries and thermal stores being amongst the most common types of energy storage systems installed at homes in the UK.[54]

Types of thermal batteries

[edit]

Thermal batteries generally fall into 4 categories with different forms and applications, although fundamentally all are for the storage and retrieval of thermal energy. They also differ in method and density of heat storage.[citation needed]

Phase change thermal battery

[edit]

Phase change materials used for thermal storage are capable of storing and releasing significant thermal capacity at the temperature that they change phase. These materials are chosen based on specific applications because there is a wide range of temperatures that may be useful in different applications and a wide range of materials that change phase at different temperatures. These materials include salts and waxes that are specifically engineered for the applications they serve. In addition to manufactured materials, water is a phase change material. The latent heat of water is 334 joules/gram. The phase change of water occurs at 0 °C (32 °F).

Some applications use the thermal capacity of water or ice as cold storage; others use it as heat storage. It can serve either application; ice can be melted to store heat then refrozen to warm an environment. The advantage of using a phase change in this way is that a given mass of material can absorb a large quantity of energy without its temperature changing. Hence a thermal battery that uses a phase change can be made lighter, or more energy can be put into it without raising the internal temperature unacceptably.[citation needed]

Encapsulated thermal battery

[edit]

An encapsulated thermal battery is physically similar to a phase change thermal battery in that it is a confined amount of physical material which is thermally heated or cooled to store or extract energy. However, in a non-phase change encapsulated thermal battery, the temperature of the substance is changed without inducing a phase change. Since a phase change is not needed many more materials are available for use in an encapsulated thermal battery. One of the key properties of an encapsulated thermal battery is its volumetric heat capacity (VHC), also termed volume-specific heat capacity. Several substances are used for these thermal batteries, for example water, concrete, and wet or dry sand.[55][56]

An example of an encapsulated thermal battery is a residential water heater with a storage tank.[57][58] This thermal battery is usually slowly charged over a period of about 30–60 minutes for rapid use when needed (e.g., 10–15 minutes). Many utilities, understanding the "thermal battery" nature of water heaters, have begun using them to absorb excess renewable energy power when available for later use by the homeowner. According to the above-cited article,[57] "net savings to the electricity system as a whole could be $200 per year per heater — some of which may be passed on to its owner".

Research into using sand as a heat storage medium has been performed in Finland, where a prototype 8 MWh sand battery was built in 2022 to store renewable solar and wind power as heat, for later use as district heating, and possible later power generation.[59][60]

Ground heat exchange thermal battery

[edit]
Thermal battery
TypeEnergy
Working principleThermodynamics
InventedHeat pumps, as used by the GHEX depicted above, were invented in the 1940s by Robert C. Webber.
First production Heat pumps were first produced in the 1970s.

A ground heat exchanger (GHEX) is an area of the earth that is utilized as a seasonal/annual cycle thermal battery. These thermal batteries are areas of the earth into which pipes have been placed in order to transfer thermal energy. Energy is added to the GHEX by running a higher temperature fluid through the pipes and thus raising the temperature of the local earth. Energy can also be taken from the GHEX by running a lower-temperature fluid through those same pipes.

GHEX are usually implemented in two forms. The picture above depicts what is known as a "horizontal" GHEX where trenching is used to place an amount of pipe in a closed loop in the ground. They are also formed by drilling boreholes into the ground, either vertically or horizontally, and then the pipes are inserted in the form of a closed-loop with a "u-bend" fitting on the far end of the loop.

Heat energy can be added to or removed from a GHEX at any point in time. However, they are most often used as a Seasonal thermal energy storage operating on an annual cycle where energy is extracted from a building during the summer season to cool a building and added to the GHEX. Then that same energy is later extracted from the GHEX in the winter season to heat the building. This annual cycle of energy addition and subtraction is highly predictable based on energy modelling of the building served. A thermal battery used in this mode is a renewable energy source as the energy extracted in the winter will be restored to the GHEX the next summer in a continually repeating cycle. This type is solar powered because it is the heat from the sun in the summer that is removed from a building and stored in the ground for use in the next winter season for heating. There are two main methods of Thermal Response Testing that are used to characterize the thermal conductivity and Thermal Capacity/Diffusivity of GHEX Thermal Batteries—Log-Time 1-Dimensional Curve Fit[61] and newly released Advanced Thermal Response Testing.[62][63]

A good example of the Annual Cycle nature of a GHEX Thermal Battery can be seen in the ASHRAE Building study.[64] As seen there in the 'Ground Loop and Ambient Air temperatures by date' graphic (Figure 2–7), one can easily see the annual cycle sinusoidal shape of the ground temperature as heat is seasonally extracted from the ground in winter and rejected to the ground in summer, creating a ground "thermal charge" in one season that is not uncharged and driven the other direction from neutral until a later season. Other more advanced examples of Ground-based Thermal Batteries utilizing intentional well-bore thermal patterns are currently in research and early use. [citation needed]

Other thermal batteries

[edit]

In the defense industry primary molten-salt batteries are termed "thermal batteries". They are non-rechargeable electrical batteries using a low-melting eutectic mixture of ionic metal salts (sodium, potassium and lithium chlorides, bromides, etc.) as the electrolyte, manufactured with the salts in solid form. As long as the salts remain solid, the battery has a long shelf life of up to 50[65] years. Once activated (usually by a pyrotechnic heat source) and the electrolyte melts, it is very reliable with a high energy and power density. They are extensively used for military applications such as small to large guided missiles, and nuclear weapons.[citation needed]

There are other items that have historically been termed "thermal batteries", such as energy-storage heat packs that skiers use for keeping hands and feet warm (see hand warmer). These contain iron powder moist with oxygen-free salt water which rapidly corrodes over a period of hours, releasing heat, when exposed to air. Instant cold packs absorb heat by a non-chemical phase-change such as by absorbing the endothermic heat of solution of certain compounds.

The one common principle of these other thermal batteries is that the reaction involved is not reversible. Thus, these batteries are not used for storing and retrieving heat energy.

Electric thermal storage

[edit]

Storage heaters are commonplace in European homes with time-of-use metering (traditionally using cheaper electricity at nighttime). They consist of high-density ceramic bricks or feolite blocks heated to a high temperature with electricity and may or may not have good insulation and controls to release heat over a number of hours. Some advice not to use them in areas with young children or where there is an increased risk of fires due to poor housekeeping, both due to the high temperatures involved.[66][67]

With the rise of wind and solar power (and other renewable energies) providing an ever increasing share of energy input into the electricity grids in some countries, the use of larger scale electric energy storage is being explored by several commercial companies. Ideally, the utilisation of surplus renewable energy is transformed into high temperature high grade heat in highly insulated heat stores, for release later when needed. An emerging technology is the use of vacuum super insulated (VSI) heat stores.[68] The use of electricity to generate heat, and not say direct heat from solar thermal collectors, means that very high temperatures can be realised, potentially allowing for inter seasonal heat transfer—storing high grade heat in summer from surplus photovoltaics generation into heat stored for the following winter with relatively minimal standing losses.

Solar energy storage

[edit]

Solar energy is an application of thermal energy storage. Most practical solar thermal storage systems provide storage from a few hours to a day's worth of energy. However, a growing number of facilities use seasonal thermal energy storage (STES), enabling solar energy to be stored in summer to heat space during winter.[69][70][71] In 2017 Drake Landing Solar Community in Alberta, Canada, achieved a year-round 97% solar heating fraction, a world record made possible by incorporating STES.[69][72]

The combined use of latent heat and sensible heat are possible with high temperature solar thermal input. Various eutectic metal mixtures, such as aluminum and silicon (AlSi
12
) offer a high melting point suited to efficient steam generation,[73] while high alumina cement-based materials offer good storage capabilities.[74]

Pumped-heat electricity storage

[edit]

In pumped-heat electricity storage (PHES), a reversible heat-pump system is used to store energy as a temperature difference between two heat stores.[75][76][77]

Isentropic

[edit]

Isentropic systems involve two insulated containers filled, for example, with crushed rock or gravel: a hot vessel storing thermal energy at high temperature/pressure, and a cold vessel storing thermal energy at low temperature/pressure. The vessels are connected at top and bottom by pipes and the whole system is filled with an inert gas such as argon.[78]

While charging, the system can use off-peak electricity to work as a heat pump. One prototype used argon at ambient temperature and pressure from the top of the cold store is compressed adiabatically, to a pressure of, for example, 12 bar, heating it to around 500 °C (900 °F). The compressed gas is transferred to the top of the hot vessel where it percolates down through the gravel, transferring heat to the rock and cooling to ambient temperature. The cooled, but still pressurized, gas emerging at the bottom of the vessel is then adiabatically expanded to 1 bar, which lowers its temperature to −150 °C. The cold gas is then passed up through the cold vessel where it cools the rock while warming to its initial condition.

The energy is recovered as electricity by reversing the cycle. The hot gas from the hot vessel is expanded to drive a generator and then supplied to the cold store. The cooled gas retrieved from the bottom of the cold store is compressed which heats the gas to ambient temperature. The gas is then transferred to the bottom of the hot vessel to be reheated.

The compression and expansion processes are provided by a specially designed reciprocating machine using sliding valves. Surplus heat generated by inefficiencies in the process is shed to the environment through heat exchangers during the discharging cycle.[75][78]

The developer claimed that a round trip efficiency of 72–80% was achievable.[75][78] This compares to >80% achievable with pumped hydro energy storage.[76]

Another proposed system uses turbomachinery and is capable of operating at much higher power levels.[77] Use of phase change material as heat storage material could enhance performance.[16]

See also

[edit]

icon Renewable energy portal

References

[edit]
  1. ^ Wright, Matthew; Hearps, Patrick; et al. (October 2010). "Australian Sustainable Energy: Zero Carbon Australia Stationary Energy Plan" (PDF). Energy Research Institute, University of Melbourne. p. 33.
  2. ^ Innovation in Concentrating Thermal Solar Power (CSP), RenewableEnergyFocus.com website.
  3. ^ Stern, Ray (10 October 2013). "Solana: 10 Facts You Didn't Know About the Concentrated Solar Power Plant Near Gila Bend". Phoenix New Times.
  4. ^ Saeed, R.M.; Schlegel, J.P.; Castano, C.; Sawafta, R. (2018). "Preparation and enhanced thermal performance of novel (solid to gel) form-stable eutectic PCM modified by nano-graphene platelets" (PDF). Journal of Energy Storage. 15: 91–102. Bibcode:2018JEnSt..15...91S. doi:10.1016/j.est.2017.11.003.
    Saeed, R.M.; Schlegel, J.P.; Castano, C.; Sawafta, R.; Kuturu, V. (2017). "Preparation and thermal performance of methyl palmitate and lauric acid eutectic mixture as phase change material (PCM)" (PDF). Journal of Energy Storage. 13: 418–424. Bibcode:2017JEnSt..13..418S. doi:10.1016/j.est.2017.08.005.
  5. ^ Jacobson, Mark Z.; Delucchi, Mark A.; Cameron, Mary A.; Frew, Bethany A. (2015). "Low-cost solution to the grid reliability problem with 100% penetration of intermittent wind, water, and solar for all purposes". Proceedings of the National Academy of Sciences. 112 (49): 15060–5. Bibcode:2015PNAS..11215060J. doi:10.1073/pnas.1510028112. PMC 4679003. PMID 26598655.
  6. ^ Mathiesen, B.V.; Lund, H.; Connolly, D.; Wenzel, H.; Østergaard, P.A.; Möller, B.; Nielsen, S.; Ridjan, I.; Karnøe, P.; Sperling, K.; Hvelplund, F.K. (2015). "Smart Energy Systems for coherent 100% renewable energy and transport solutions". Applied Energy. 145: 139–54. Bibcode:2015ApEn..145..139M. doi:10.1016/j.apenergy.2015.01.075.
  7. ^ Henning, Hans-Martin; Palzer, Andreas (2014). "A comprehensive model for the German electricity and heat sector in a future energy system with a dominant contribution from renewable energy technologies—Part I: Methodology". Renewable and Sustainable Energy Reviews. 30: 1003–18. Bibcode:2014RSERv..30.1003H. doi:10.1016/j.rser.2013.09.012.
  8. ^ Bauer, Thomas; Steinmann, Wolf-Dieter; Laing, Doerte; Tamme, Rainer (2012). "Thermal Energy Storage Materials and Systems". Annual Review of Heat Transfer. 15 (15): 131–177. doi:10.1615/AnnualRevHeatTransfer.2012004651. ISSN 1049-0787.
  9. ^ a b c Sarbu, Ioan; Sebarchievici, Calin (January 2018). "A Comprehensive Review of Thermal Energy Storage". Sustainability. 10 (1): 191. doi:10.3390/su10010191.
  10. ^ Bauer, Thomas; Odenthal, Christian; Bonk, Alexander (April 2021). "Molten Salt Storage for Power Generation". Chemie Ingenieur Technik (in German). 93 (4): 534–546. doi:10.1002/cite.202000137. ISSN 0009-286X. S2CID 233913583.
  11. ^ Mancini, Tom (10 January 2006). "Advantages of Using Molten Salt". Sandia National Laboratories. Archived from the original on 5 June 2011. Retrieved 14 July 2011.
  12. ^ Jones, B. G.; Roy, R. P.; Bohl, R. W. (1977). "Molten-salt energy-storage system — A feasibility study". Heat Transfer in Energy Conservation; Proceedings of the Winter Annual Meeting: 39–45. Bibcode:1977htec.proc...39J.
  13. ^ Biello, David (18 February 2009). "How to Use Solar Energy at Night". Scientific American. Archived from the original on 13 January 2017.
  14. ^ Ehrlich, Robert (2013). "Thermal storage". Renewable Energy: A First Course. CRC Press. p. 375. ISBN 978-1-4398-6115-8.
  15. ^ "Solar heads for the hills as tower technology turns upside down". 30 January 2012. Archived from the original on 7 November 2017. Retrieved 21 August 2017.
  16. ^ a b "Using encapsulated phase change salts for concentrated solar power plant" (PDF). Archived (PDF) from the original on 10 July 2016. Retrieved 2 November 2017.
  17. ^ Mitran, Raul-Augustin; Lincu, Daniel; Buhǎlţeanu, Lucian; Berger, Daniela; Matei, Cristian (15 September 2020). "Shape-stabilized phase change materials using molten NaNO3 — KNO3 eutectic and mesoporous silica matrices". Solar Energy Materials and Solar Cells. 215: 110644. doi:10.1016/j.solmat.2020.110644. ISSN 0927-0248. S2CID 224912345.
  18. ^ "World's Largest Solar Thermal Plant With Storage Comes Online — CleanTechnica". cleantechnica.com. 14 October 2013. Retrieved 9 May 2018.
  19. ^ "Cerro Dominador concentrated solar power plant inaugurated in Chile". 9 June 2021. Retrieved 13 June 2021.
  20. ^ Epp, Baerbel (17 May 2019). "Seasonal pit heat storage: Cost benchmark of 30 EUR/m³".
  21. ^ Gebremedhin, Alemayehu; Zinko, Heimo. "Seasonal heat storages in district heating systems" (PDF). Linköping, Sweden: Linköping University. Archived (PDF) from the original on 13 January 2017.
  22. ^ "Gigantic cavern heat storage facility to be implemented in Mustikkamaa in Helsinki". 22 March 2018.
  23. ^ "The world's first seasonal energy storage facility of its kind is planned for the Kruunuvuorenranta rock caverns". 30 January 2018.
  24. ^ "Vantaan Ikean lähelle aletaan pian louhia valtavaa luolastoa". Helsingin Sanomat (in Finnish). 5 April 2024. Retrieved 5 April 2024.
  25. ^ "Molten silicon used for thermal energy storage". The Engineer. Archived from the original on 4 November 2016. Retrieved 2 November 2016.
  26. ^ "Energy-storage system based on silicon from sand". www.powerengineeringint.com. Archived from the original on 4 November 2016. Retrieved 2 November 2016.
  27. ^ Gomna, Aboubakar; N’Tsoukpoe, Kokouvi Edem; Le Pierrès, Nolwenn; Coulibaly, Yézouma (15 September 2019). "Review of vegetable oils behaviour at high temperature for solar plants: Stability, properties and current applications". Solar Energy Materials and Solar Cells. 200: 109956. Bibcode:2019SEMSC.20009956G. doi:10.1016/j.solmat.2019.109956. ISSN 0927-0248.
  28. ^ Gomna, Aboubakar; N’Tsoukpoe, Kokouvi Edem; Le Pierrès, Nolwenn; Coulibaly, Yézouma (15 April 2020). "Thermal stability of a vegetable oil-based thermal fluid at high temperature". African Journal of Science, Technology, Innovation and Development. 12 (3): 317–326. doi:10.1080/20421338.2020.1732080. ISSN 2042-1338.
  29. ^ a b N’Tsoukpoe, Kokouvi Edem; Le Pierrès, Nolwenn; Seshie, Yao Manu; Coulibaly, Yézouma (23 February 2021). "Technico-economic comparison of heat transfer fluids or thermal energy storage materials: A case study using Jatropha curcas oil". African Journal of Science, Technology, Innovation and Development. 13 (2): 193–211. doi:10.1080/20421338.2020.1838082. ISSN 2042-1338.
  30. ^ "World first: Siemens Gamesa begins operation of its innovative electrothermal energy storage system". Retrieved 27 July 2019.
  31. ^ "Siemens project to test heated rocks for large-scale, low-cost thermal energy storage". Utility Dive. 12 October 2016. Archived from the original on 13 October 2016. Retrieved 15 October 2016.
  32. ^ "Nyt energilager skal opsamle grøn energi i varme sten". Ingeniøren. 25 November 2016. Archived from the original on 26 November 2016. Retrieved 26 November 2016.
  33. ^ "Makers claim:Rondo Heat Battery".
  34. ^ "1414 Degrees Limited - Initiation: innovative silicon-based thermal energy storage system to harness liw-cost renewable power" (PDF).
  35. ^ "Miscibility Gap Alloy Thermal Storage Website". Archived from the original on 12 March 2018.
  36. ^ Rawson, Anthony; Kisi, Erich; Sugo, Heber; Fiedler, Thomas (1 October 2014). "Effective conductivity of Cu–Fe and Sn–Al miscibility gap alloys". International Journal of Heat and Mass Transfer. 77: 395–405. Bibcode:2014IJHMT..77..395R. doi:10.1016/j.ijheatmasstransfer.2014.05.024.
  37. ^ Sugo, Heber; Kisi, Erich; Cuskelly, Dylan (1 March 2013). "Miscibility gap alloys with inverse microstructures and high thermal conductivity for high energy density thermal storage applications". Applied Thermal Engineering. 51 (1–2): 1345–50. Bibcode:2013AppTE..51.1345S. doi:10.1016/j.applthermaleng.2012.11.029.
  38. ^ Saito, Akio (1 March 2002). "Recent advances in research on cold thermal energy storage". International Journal of Refrigeration. 25 (2): 177–189. doi:10.1016/S0140-7007(01)00078-0. ISSN 0140-7007.
  39. ^ "How Thermal Energy Storage Works". Retrieved 7 July 2024.
  40. ^ Harrabin, Roger (2 October 2012). "Liquid air 'offers energy storage hope'". BBC News, Science and Environment. BBC. Archived from the original on 2 October 2012. Retrieved 2 October 2012.
  41. ^ U.S. Pat. No. 4,269,170, "Adsorption solar heating and storage"; Inventor: John M. Guerra; Granted May 26, 1981
  42. ^ Le Pierrès, Nolwenn; Luo, Lingai (9 September 2024). Heat and Cold Storage 2: Thermochemical Storage (1 ed.). Wiley. doi:10.1002/9781394312559.ch1. ISBN 978-1-78945-134-4.
  43. ^ N’Tsoukpoe, Kokouvi Edem; Schmidt, Thomas; Rammelberg, Holger Urs; Watts, Beatriz Amanda; Ruck, Wolfgang K. L. (1 July 2014). "A systematic multi-step screening of numerous salt hydrates for low temperature thermochemical energy storage". Applied Energy. 124: 1–16. Bibcode:2014ApEn..124....1N. doi:10.1016/j.apenergy.2014.02.053. ISSN 0306-2619.
  44. ^ Rainer, Klose. "Seasonal energy storage: Summer heat for the winter". Zurich, Switzerland: Empa. Archived from the original on 18 January 2017.
  45. ^ MERITS project Compact Heat Storage. "MERITS". Archived from the original on 15 August 2017. Retrieved 10 July 2017.
  46. ^ De Jong, Ard-Jan; Van Vliet, Laurens; Hoegaerts, Christophe; Roelands, Mark; Cuypers, Ruud (2016). "Thermochemical Heat Storage — from Reaction Storage Density to System Storage Density". Energy Procedia. 91: 128–37. Bibcode:2016EnPro..91..128D. doi:10.1016/j.egypro.2016.06.187.
  47. ^ Brünig, Thorge; Krekic, Kristijan; Bruhn, Clemens; Pietschnig, Rudolf (2016). "Calorimetric Studies and Structural Aspects of Ionic Liquids in Designing Sorption Materials for Thermal Energy Storage". Chemistry: A European Journal. 22 (45): 16200–12. doi:10.1002/chem.201602723. PMC 5396372. PMID 27645474.
  48. ^ N’Tsoukpoe, Kokouvi Edem; Kuznik, Frédéric (1 April 2021). "A reality check on long-term thermochemical heat storage for household applications". Renewable and Sustainable Energy Reviews. 139: 110683. Bibcode:2021RSERv.13910683N. doi:10.1016/j.rser.2020.110683. ISSN 1364-0321.
  49. ^ Kolpak, Alexie M.; Grossman, Jeffrey C. (2011). "Azobenzene-Functionalized Carbon Nanotubes As High-Energy Density Solar Thermal Fuels". Nano Letters. 11 (8): 3156–62. Bibcode:2011NanoL..11.3156K. doi:10.1021/nl201357n. PMID 21688811.
  50. ^ "Storing energy in chemical bonds of molecules". Off Grid Energy Independence. 21 January 2014. Retrieved 27 January 2021.
  51. ^ a b Mansø, Mads; Petersen, Anne Ugleholdt; Wang, Zhihang; Erhart, Paul; Nielsen, Mogens Brøndsted; Moth-Poulsen, Kasper (16 May 2018). "Molecular solar thermal energy storage in photoswitch oligomers increases energy densities and storage times". Nature Communications. 9 (1): 1945. Bibcode:2018NatCo...9.1945M. doi:10.1038/s41467-018-04230-8. ISSN 2041-1723. PMC 5956078. PMID 29769524.
  52. ^ Hawkins, Joshua (15 April 2022). "New liquid system could revolutionize solar energy". BGR. Retrieved 18 April 2022.
  53. ^ Wang, Zhihang; Wu, Zhenhua; Hu, Zhiyu; Orrego-Hernández, Jessica; Mu, Erzhen; Zhang, Zhao-Yang; Jevric, Martyn; Liu, Yang; Fu, Xuecheng; Wang, Fengdan; Li, Tao; Moth-Poulsen, Kasper (16 March 2022). "Chip-scale solar thermal electrical power generation". Cell Reports Physical Science. 3 (3): 100789. Bibcode:2022CRPS....300789W. doi:10.1016/j.xcrp.2022.100789. hdl:10261/275653. ISSN 2666-3864. S2CID 247329224.
  54. ^ "Storing energy". Energy Saving Trust. Retrieved 18 June 2024.
  55. ^ ""There is a great deal of experience with solid-media high-temperature storages"". Solarthermalworld. 6 March 2024.
  56. ^ "Overview of high-temperature storage solution providers — status March 2024" (PDF). March 2024.
  57. ^ a b Mooney, Chris (24 February 2016). "Your home water heater may soon double as a battery". Washington Post.
  58. ^ Hledik, R.; Chang, J.; Lueken, R. (2016). "The hidden battery: Opportunities in electric water heating" (PDF). Prepared for NRECA, NRDC, and PLMA by the Brattle Group.
  59. ^ McGrath, Matt (5 July 2022). "Climate change: 'Sand battery' could solve green energy's big problem". BBC News.
  60. ^ "Sand Batteries provide heat to district heating networks in Finland". Solarthermalworld. 6 March 2024.
  61. ^ "Test Information | Main | Site Title". geotctest.com.
  62. ^ Liu, Xiaobing; Clemenzi, Rick; Liu, Su (1 April 2017). "Advanced Testing Method for Ground Thermal Conductivity". doi:10.2172/1354667. OSTI 1354667 – via www.osti.gov.
  63. ^ "Thermal Response Testing Takes a Step Forward, Geo Outlook 2017 Vol. 14 No. 3, Rick Clemenzi, Xiaobing Liu, Garen Ewbank and Judy Siglin".
  64. ^ "Performance of the HVAC Systems at the ASHRAE Headquarters Building, Jeffrey D. Spitler, Laura E. Southard, Xiaobing Liu, GeoExchange Organization, September 30, 2014, see Figure 2-7 (pdf pg 32): Ambient air and ground loop water supply temperatures during occupied hours".
  65. ^ Molten-salt battery#Uses
  66. ^ "report". Retrieved 20 February 2020.
  67. ^ Romero, I.B.; Strachan, P. (2013). An experimental investigation of an electrical storage heater in the context of storage technologies (PDF) (MSc). Sustainable Engineering: Renewable Energy Systems and the Environment, University of Strathclyde. Archived (PDF) from the original on 14 May 2016.
  68. ^ "Solarthermal world.og website". Retrieved 23 July 2023.
  69. ^ a b Wong B. (2011). Drake Landing Solar Community Archived 4 March 2016 at the Wayback Machine. Presentation at IDEA/CDEA District Energy/CHP 2011 Conference. Toronto, 26–29 June 2011.
  70. ^ SunStor-4 Project, Marstal, Denmark. The solar district heating system Archived 24 March 2021 at the Wayback Machine, which has an interseasonal pit storage, is being expanded.
  71. ^ "Thermal Energy Storage in ThermalBanks". ICAX Ltd, London. Archived from the original on 14 November 2011. Retrieved 21 November 2011.
  72. ^ "Canadian Solar Community Sets New World Record for Energy Efficiency and Innovation" (Press release). Natural Resources Canada. 5 October 2012. Archived from the original on 3 November 2016. Retrieved 11 January 2017.
  73. ^ Khare, Sameer; Dell'Amico, Mark; Knight, Chris; McGarry, Scott (2012). "Selection of materials for high temperature latent heat energy storage". Solar Energy Materials and Solar Cells. 107: 20–7. Bibcode:2012SEMSC.107...20K. doi:10.1016/j.solmat.2012.07.020.
  74. ^ Khare, S.; Dell'Amico, M.; Knight, C.; McGarry, S. (2013). "Selection of materials for high temperature sensible energy storage". Solar Energy Materials and Solar Cells. 115: 114–22. Bibcode:2013SEMSC.115..114K. doi:10.1016/j.solmat.2013.03.009.
  75. ^ a b c "Isentropic's Pumped Heat System Stores Energy at Grid Scale". Archived from the original on 22 July 2015. Retrieved 19 June 2017.
  76. ^ a b "ENERGY STORAGE:THE MISSING LINK IN THE UK'S ENERGY COMMITMENTS". IMechE. p. 27. Archived from the original on 12 July 2014.
  77. ^ a b "Pumped Heat Energy Storage" (PDF). Archived (PDF) from the original on 22 January 2017. Retrieved 16 July 2017.
  78. ^ a b c "Isentropic's PHES Technology". 20 October 2014. Archived from the original on 12 October 2017. Retrieved 16 July 2017.
[edit]

Further reading

[edit]