A heat storage device of the present disclosure includes a latent heat storage material and a container. The latent heat storage material is water-soluble. The container houses the latent heat storage material and is formed of a main material being aluminum or an aluminum alloy. The container has a joining portion and a first coating. The first coating covers at least the joining portion on an inner surface of the container. On a surface of the first coating, a first element and fluorine are present. The first element is an element other than aluminum and having a lower ionization tendency than potassium.

A thermal energy storage system including an enclosure having an internal volume. An incompressible phase change material (PCM) is provided within the internal volume of the enclosure, where the PCM contracts into a solid state when its temperature falls below a certain temperature and expands into a liquid state when its temperature goes above the certain temperature. An elastic bladder is positioned adjacent to the PCM within the internal volume of the enclosure and is filled with a compressible material, where the PCM pushes against the bladder when it is expanded to the liquid state and causes the compressible material to be compressed within the bladder and the enclosure.

This invention provides a heat reservoir exhibiting improved thermostability at abnormally high temperatures. The heat reservoir 1 of the invention comprises: a plate-shaped porous substrate 10 having 2 main surfaces 11 and 12; a heat storage material composition impregnating into the porous substrate 10; and a coat layer 20 covering at least one of the 2 main surfaces 11 and 12 of the porous substrate 10, wherein the heat storage material composition comprises a latent heat storage material and a thermoplastic elastomer and the coat layer 20 is thermostable and radiant heat reflective.

Thermal energy storage and heat exchanger, distinctive in that it comprises: a number of hardened concrete thermal energy storage elements; a housing, into which said elements have been arranged; an active heat transfer and storage medium in the volume between said elements and said housing, in the form of either: a stagnant liquid or phase change material, or a dynamic fluid arranged to flow in the volume between said elements and said housing; at least one means for delivery of thermal energy to the thermal energy storage; at least one means for taking out thermal energy from the thermal energy storage; and thermal insulation.

The invention relates to a system for the storage and recovery of thermal energy, using, as its medium, at least one phase change material (solid-liquid) and a sensible heat solid material for storing/recovering the heat obtained from an external source in the form of phase change latent heat and sensible heat. The aforementioned materials are duly housed inside a single tank containing at least two zones which are differentiated by the range of temperatures to which they are subjected, each zone containing a different material. The most common configuration consists of three different zones located inside the tank, namely: a hot zone in the upper part of the tank, enclosing an encapsulated phase change material characterized by a high melting temperature; a cold zone housed in the lower part of the tank, containing a phase change material with a low melting temperature; and a middle zone containing a sensible heat solid material.

Embodiments of the present invention relate to compressed gas storage units, which in certain applications may be employed in conjunction with energy storage systems. Some embodiments may comprise one or more blow-molded polymer shells, formed for example from polyethylene terephthalate (PET) or ultra-high molecular weight polyethylene (UHMWPE). Embodiments of compressed gas storage units may be composite in nature, for example comprising carbon fiber filament(s) wound with a resin over a liner. A compressed gas storage unit may further include a heat exchanger element comprising a heat pipe or apparatus configured to introduce liquid directly into the storage unit for heat exchange with the compressed gas present therein.

The invention provides, in some aspects, a thermal storage system that has one or more fluid-transport vias that contain a heat transfer fluid and that are disposed in thermal coupling with a form of graphite, e.g., expanded graphite. The graphite form is, in turn, disposed in thermal coupling with a bonded aggregate material.

A thermal energy storage and power generation system includes a thermal energy storage device including a container, a heating element in the container, a pair of fins in the container and arranged on opposite sides of the heating element, a thermal storage material in the container, and a tube in the container and extending around the thermal storage material. The system also includes a generator in communication with the thermal energy storage device for converting thermal energy into electrical energy as well as subsystems for regulating and controlling the system.

A heat or cold storage multilayer tower has athermo-insulated housing with a multilayer system of rigid blocks, Each rigid block has a set of narrow vertical ducts, when these narrow ducts are alternatively open or provided with sealed flexible bags, which are ufabricated from polymer film or metal foil and contain a phase change material (PCM). The rigid block are fabricated from ceramics, glass, glass ceramics, polymer fibro reinforced concrete or glass-fiber reinforced concrete. Hydrostatic pressure of molten PCM in the sealed flexible bags ensures good thermal contact of the sealed flexible bags with internal walls of the corresponding ducts. This construction provides effective heat transfer between a heat transfer fluid (HTF) and PCM in the processes of charging and discharging of the sealed flexible bags with heat or coldwith high values of stored thermal energy for specific volume.

A thermal energy storage system including an enclosure having an internal volume. An incompressible phase change material (PCM) is provided within the internal volume of the enclosure, where the PCM contracts into a solid state when its temperature falls below a certain temperature and expands into a liquid state when its temperature goes above the certain temperature. An elastic bladder is positioned adjacent to the PCM within the internal volume of the enclosure and is filled with a compressible material, where the PCM pushes against the bladder when it is expanded to the liquid state and causes the compressible material to be compressed within the bladder and the enclosure.