Contenido

El almacenamiento de calor latente puede lograrse mediante cambios en el estado de la materia de líquido→sólido, sólido→líquido, sólido→gas y líquido→gas. Sin embargo, sólo los cambios de fase sólido→líquido y líquido→sólido son prácticos para los PCM. Aunque las transiciones líquido-gas tienen un mayor calor de transformación que las transiciones sólido-líquido, los cambios de fase líquido→gas no son prácticos para el almacenamiento térmico porque se requieren grandes volúmenes o altas presiones para almacenar los materiales en su fase gaseosa. Los cambios de fase sólido-sólido suelen ser muy lentos y tienen un calor de transformación relativamente bajo.

Inicialmente, los PCM sólido-líquido se comportan como materiales de almacenamiento de calor sensible (SHS); su temperatura aumenta a medida que absorben calor. Sin embargo, a diferencia de los materiales SHS convencionales, cuando los PCM alcanzan su temperatura de cambio de fase (su punto de fusión) absorben grandes cantidades de calor a una temperatura casi constante hasta que todo el material se funde. Cuando la temperatura ambiente alrededor de un material líquido desciende, el PCM se solidifica, liberando su calor latente almacenado. Existe un gran número de PCM en cualquier intervalo de temperatura necesario, desde -5 hasta 190 °C.[1]​ Dentro del intervalo de confort humano entre 20 y 30 °C, algunos PCM son muy eficaces, ya que almacenan más de 200 kJ/kg de calor latente, frente a una capacidad calorífica específica de alrededor de un kJ/(kg*°C) para la mampostería. Por tanto, la densidad de almacenamiento puede ser 20 veces superior a la de la mampostería por kg si se admite una oscilación de temperatura de 10 °C.[2]​ Sin embargo, como la masa de la mampostería es muy superior a la del PCM, esta capacidad calorífica específica (por masa) queda algo compensada. Un muro de mampostería puede tener una masa de 200 kg/m, por lo que para duplicar la capacidad calorífica se necesitarían 10 kg/m adicionales de PCM.

Organic PCM

Hydrocarbons, mainly paraffins (CH) and lipids, but also sugar alcohols.[4][5][6] Another example of a phase change material in this category is beeswax. [7]​.

Inorganic

Salt hydrates (MN*·n*HO)[10]​.

Hygroscopic materials

Many natural building materials are hygroscopic, meaning they can absorb (water condenses) and release water (water evaporates). The process is as follows.

Although this process releases a small amount of energy, the large surfaces allow for significant heating or cooling (1-2°C) in buildings. Corresponding materials are wool insulation and earth/clay finishes.

Solid PCMs

A specialized group of PCMs that undergo a solid/solid phase transition with the consequent absorption and release of large amounts of heat. These materials change their crystalline structure from one lattice configuration to another at a fixed, well-defined temperature, and the transformation can involve latent heats comparable to those of the most effective solid/liquid PCMs. These materials are useful because, unlike solid/liquid PCMs, they do not require nucleation to prevent supercooling. Furthermore, as it is a solid/solid phase change, there is no visible change in the appearance of the PCM, and there are no problems associated with handling liquids, for example, containment, possible leaks, etc. Currently, the temperature range of solid-solid PCM solutions spans from -50 °C (-58 °F) to +175 °C (347 °F).[16]​.

The phase change material must possess the following thermodynamic properties:[17]​.

Kinetic properties.

Chemical properties.

Affordable properties.

The main thermophysical properties of phase change materials are: Melting point (Tm), Heat of fusion (ΔHfus), Specific heat (c) (solid and liquid phase), Density (ρ) (solid and liquid phase) and thermal conductivity. From there, values ​​such as volume change and volumetric heat capacity can be calculated.

The most commonly used PCMs are salt hydrates, fatty acids and esters, and various paraffins (such as octadecane). Recently, ionic liquids have also been investigated as new PCMs.

Since most organic solutions do not contain water, they can be exposed to air, but all salt-based PCM solutions must be encapsulated to prevent evaporation or absorption of water. Both types offer certain advantages and disadvantages and, if applied correctly, some of the disadvantages become advantages for certain applications.

They have been used since the turn of the century as a medium for thermal storage applications. They have been used in applications as diverse as refrigerated transport[18]​ to rail[19]​ and road applications[20]​ and their physical properties are therefore well known.

However, unlike the ice storage system, PCM systems can be used with any conventional water chiller, whether for a new application or retrofit. Positive temperature phase change allows for the use of centrifugal and absorption chillers, as well as conventional reciprocating and screw chiller systems, or even lower ambient conditions using a cooling tower or dry chiller to charge the TES system.

The temperature range offered by PCM technology provides a new horizon for refrigeration and building services engineers when it comes to medium and high temperature energy storage applications. The scope of application of this thermal energy is very wide: solar heating, hot water, heating rejection (i.e. cooling tower) and thermal energy storage applications in dry chiller circuits.

Since PCMs transform between solid and liquid in thermal cycling, encapsulation[21]​ naturally became the obvious storage choice.

PCM encapsulation.

Because phase change materials work best in small containers, they are often divided into cells. The cells are shallow to reduce static loading, based on the principle of shallow container geometry. The packaging material must conduct heat well; and must be durable enough to withstand frequent changes in the volume of the storage material as phase changes occur. You should also restrict the passage of water through the walls, so that the materials do not dry out (or become waterlogged, if the material is hygroscopic). The packaging must also resist leaks and corrosion. The most common packaging materials that show chemical compatibility with PCMs at room temperature are stainless steel, polypropylene, and polyolefin.

Nanoparticles such as carbon nanotubes, graphite, graphene, metal, and metal oxide can be dispersed in PCM. It should be noted that the inclusion of nanoparticles will not only alter the characteristic thermal conductivity of the PCM, but also other characteristics, such as latent heat capacity, subcooling, phase change temperature and its duration, density and viscosity. The new group of PCMs is called NePCM.[22]​ NePCMs can be added to metallic foams to build a combination of even higher thermal conductivity.[22]​.

Thermal composites are combinations of phase change materials (PCM) and other (usually solid) structures. A simple example is a copper mesh immersed in paraffin. The copper mesh within the paraffin can be considered a composite material, called a thermal composite. These types of hybrid materials are created to achieve specific global or volume properties (an example is the encapsulation of paraffin in different silicon dioxide nanospheres to increase the surface-to-volume ratio and, therefore, heat transfer rates).[23]​.

Thermal conductivity is a common property that is intended to be maximized through the creation of thermal compounds. In this case, the basic idea is to increase the thermal conductivity by adding a highly conductive solid (such as copper mesh or graphite)[24]​ to the relatively poorly conductive PCM, thus increasing the overall or bulk (thermal) conductivity.[25]​ If the PCM is required to flow, the solid must be porous, such as a mesh.

Solid composites, such as fiberglass or Kevlar prepreg for the aerospace industry, typically refer to a fiber (the Kevlar or glass) and a matrix (the glue, which solidifies to hold the fibers and provide compressive strength). A thermal compound is not as clearly defined, but could similarly refer to a (solid) matrix and the PCM, which of course is usually liquid and/or solid depending on conditions.

Applications[1][26]​ of phase change materials include, but are not limited to:

Some phase change materials are suspended in water and are relatively nontoxic. Others are hydrocarbons or other flammable materials, or are toxic. As such, PCMs must be selected and applied very carefully, in accordance with fire and building codes and proper engineering practices. Due to the increased risk of fire, flame spread, smoke, explosion potential when kept in containers, and liability, it may be advisable not to use flammable PCMs in residential or other regularly occupied buildings. Phase change materials are also being used in thermal regulation of electronics.

Contenido

El almacenamiento de calor latente puede lograrse mediante cambios en el estado de la materia de líquido→sólido, sólido→líquido, sólido→gas y líquido→gas. Sin embargo, sólo los cambios de fase sólido→líquido y líquido→sólido son prácticos para los PCM. Aunque las transiciones líquido-gas tienen un mayor calor de transformación que las transiciones sólido-líquido, los cambios de fase líquido→gas no son prácticos para el almacenamiento térmico porque se requieren grandes volúmenes o altas presiones para almacenar los materiales en su fase gaseosa. Los cambios de fase sólido-sólido suelen ser muy lentos y tienen un calor de transformación relativamente bajo.

Inicialmente, los PCM sólido-líquido se comportan como materiales de almacenamiento de calor sensible (SHS); su temperatura aumenta a medida que absorben calor. Sin embargo, a diferencia de los materiales SHS convencionales, cuando los PCM alcanzan su temperatura de cambio de fase (su punto de fusión) absorben grandes cantidades de calor a una temperatura casi constante hasta que todo el material se funde. Cuando la temperatura ambiente alrededor de un material líquido desciende, el PCM se solidifica, liberando su calor latente almacenado. Existe un gran número de PCM en cualquier intervalo de temperatura necesario, desde -5 hasta 190 °C.[1]​ Dentro del intervalo de confort humano entre 20 y 30 °C, algunos PCM son muy eficaces, ya que almacenan más de 200 kJ/kg de calor latente, frente a una capacidad calorífica específica de alrededor de un kJ/(kg*°C) para la mampostería. Por tanto, la densidad de almacenamiento puede ser 20 veces superior a la de la mampostería por kg si se admite una oscilación de temperatura de 10 °C.[2]​ Sin embargo, como la masa de la mampostería es muy superior a la del PCM, esta capacidad calorífica específica (por masa) queda algo compensada. Un muro de mampostería puede tener una masa de 200 kg/m, por lo que para duplicar la capacidad calorífica se necesitarían 10 kg/m adicionales de PCM.

Organic PCM

Hydrocarbons, mainly paraffins (CH) and lipids, but also sugar alcohols.[4][5][6] Another example of a phase change material in this category is beeswax. [7]​.

Inorganic

Salt hydrates (MN*·n*HO)[10]​.

Hygroscopic materials

Many natural building materials are hygroscopic, meaning they can absorb (water condenses) and release water (water evaporates). The process is as follows.

Although this process releases a small amount of energy, the large surfaces allow for significant heating or cooling (1-2°C) in buildings. Corresponding materials are wool insulation and earth/clay finishes.

Solid PCMs

A specialized group of PCMs that undergo a solid/solid phase transition with the consequent absorption and release of large amounts of heat. These materials change their crystalline structure from one lattice configuration to another at a fixed, well-defined temperature, and the transformation can involve latent heats comparable to those of the most effective solid/liquid PCMs. These materials are useful because, unlike solid/liquid PCMs, they do not require nucleation to prevent supercooling. Furthermore, as it is a solid/solid phase change, there is no visible change in the appearance of the PCM, and there are no problems associated with handling liquids, for example, containment, possible leaks, etc. Currently, the temperature range of solid-solid PCM solutions spans from -50 °C (-58 °F) to +175 °C (347 °F).[16]​.

The phase change material must possess the following thermodynamic properties:[17]​.

Kinetic properties.

Chemical properties.

Affordable properties.

The main thermophysical properties of phase change materials are: Melting point (Tm), Heat of fusion (ΔHfus), Specific heat (c) (solid and liquid phase), Density (ρ) (solid and liquid phase) and thermal conductivity. From there, values ​​such as volume change and volumetric heat capacity can be calculated.

The most commonly used PCMs are salt hydrates, fatty acids and esters, and various paraffins (such as octadecane). Recently, ionic liquids have also been investigated as new PCMs.

Since most organic solutions do not contain water, they can be exposed to air, but all salt-based PCM solutions must be encapsulated to prevent evaporation or absorption of water. Both types offer certain advantages and disadvantages and, if applied correctly, some of the disadvantages become advantages for certain applications.

They have been used since the turn of the century as a medium for thermal storage applications. They have been used in applications as diverse as refrigerated transport[18]​ to rail[19]​ and road applications[20]​ and their physical properties are therefore well known.

However, unlike the ice storage system, PCM systems can be used with any conventional water chiller, whether for a new application or retrofit. Positive temperature phase change allows for the use of centrifugal and absorption chillers, as well as conventional reciprocating and screw chiller systems, or even lower ambient conditions using a cooling tower or dry chiller to charge the TES system.

The temperature range offered by PCM technology provides a new horizon for refrigeration and building services engineers when it comes to medium and high temperature energy storage applications. The scope of application of this thermal energy is very wide: solar heating, hot water, heating rejection (i.e. cooling tower) and thermal energy storage applications in dry chiller circuits.

Since PCMs transform between solid and liquid in thermal cycling, encapsulation[21]​ naturally became the obvious storage choice.

PCM encapsulation.

Because phase change materials work best in small containers, they are often divided into cells. The cells are shallow to reduce static loading, based on the principle of shallow container geometry. The packaging material must conduct heat well; and must be durable enough to withstand frequent changes in the volume of the storage material as phase changes occur. You should also restrict the passage of water through the walls, so that the materials do not dry out (or become waterlogged, if the material is hygroscopic). The packaging must also resist leaks and corrosion. The most common packaging materials that show chemical compatibility with PCMs at room temperature are stainless steel, polypropylene, and polyolefin.

Nanoparticles such as carbon nanotubes, graphite, graphene, metal, and metal oxide can be dispersed in PCM. It should be noted that the inclusion of nanoparticles will not only alter the characteristic thermal conductivity of the PCM, but also other characteristics, such as latent heat capacity, subcooling, phase change temperature and its duration, density and viscosity. The new group of PCMs is called NePCM.[22]​ NePCMs can be added to metallic foams to build a combination of even higher thermal conductivity.[22]​.

Thermal composites are combinations of phase change materials (PCM) and other (usually solid) structures. A simple example is a copper mesh immersed in paraffin. The copper mesh within the paraffin can be considered a composite material, called a thermal composite. These types of hybrid materials are created to achieve specific global or volume properties (an example is the encapsulation of paraffin in different silicon dioxide nanospheres to increase the surface-to-volume ratio and, therefore, heat transfer rates).[23]​.

Thermal conductivity is a common property that is intended to be maximized through the creation of thermal compounds. In this case, the basic idea is to increase the thermal conductivity by adding a highly conductive solid (such as copper mesh or graphite)[24]​ to the relatively poorly conductive PCM, thus increasing the overall or bulk (thermal) conductivity.[25]​ If the PCM is required to flow, the solid must be porous, such as a mesh.

Solid composites, such as fiberglass or Kevlar prepreg for the aerospace industry, typically refer to a fiber (the Kevlar or glass) and a matrix (the glue, which solidifies to hold the fibers and provide compressive strength). A thermal compound is not as clearly defined, but could similarly refer to a (solid) matrix and the PCM, which of course is usually liquid and/or solid depending on conditions.

Applications[1][26]​ of phase change materials include, but are not limited to:

Some phase change materials are suspended in water and are relatively nontoxic. Others are hydrocarbons or other flammable materials, or are toxic. As such, PCMs must be selected and applied very carefully, in accordance with fire and building codes and proper engineering practices. Due to the increased risk of fire, flame spread, smoke, explosion potential when kept in containers, and liability, it may be advisable not to use flammable PCMs in residential or other regularly occupied buildings. Phase change materials are also being used in thermal regulation of electronics.