A regenerative heat exchanger includes a refrigerant pipe, a regenerator, and an air passage fin. The air passage fin is disposed in an air passage defined outside of the refrigerant pipe and the regenerator, and is thermally connected with the regenerator directly or through the refrigerant pipe. At least one of the regenerator and the air passage fin is configured such that a thermal resistance between a part of a regenerative material located on an upstream side and air flowing through the air passage becomes larger than a thermal resistance between a part of the regenerative material located on a downstream side and air flowing through the air passage.

The invention relates to thermal management aimed at maintaining the temperature inside a space. The proposed assembly includes the space and a device arranged around same, placed in an outdoor environment exposed to a non-constant temperature and including at least one thermally insulating element inserted between the inner space and the outdoor environment and, from the inside towards the outside: an inner heat-storage element made of PCM material and an outer thermal barrier containing several PCMs. The invention also includes a cooling unit for provisionally providing, in the inner space, a charge fluid, at least at a temperature that is different from those of the temperature to be maintained, in heat transfer with the PCM of the inner element, so as to store thermal energy.

Certain aspects of the present disclosure provide a heat-dissipating device with enhanced interfacial properties. One example heat-dissipating device generally includes a first heat spreader configured to be thermally coupled to a region configured to generate heat, a second heat spreader, an interposer thermally coupled to at least one of the first heat spreader or the second heat spreader, at least one interfacial layer comprising a graphene material disposed on at least one surface of the interposer, and a phase change material disposed between the at least one interfacial layer and at least one of the first heat spreader or the second heat spreader and thermally coupled to at least one of the first heat spreader or the second heat spreader.

In one aspect, methods of managing the temperature of a room are described herein. In some embodiments, such a method described herein comprises disposing a fixture in an interior of the room, wherein the fixture comprises or contains a phase change material. Additionally, in some cases, the fixture is a decorative fixture, such as a piece of artwork.

The invention provides an energy storage apparatus comprising: a sensible heat storage body having a heat exchanger channel and a heating element channel adapted to receive a removable heating element; and a heat exchanger having an inlet and an outlet, wherein at least a portion of the heat exchanger is disposed along the channel. Also provided are methods or reversibly storing and/or extracting energy, a heating element and an energy storage array comprising a plurality of energy storage apparatus as described herein.

The invention relates to a tube (1) for a heat exchange bundle (100) of a vehicle heat exchanger, said tube (1) comprising: two circulation plates (3) configured to be assembled together in a sealed manner and to form at least one conduit (31) in which a first heat transfer fluid circulates between said circulation plates (3), at least one reservoir plate (5) comprising cavities (51), said reservoir plate (5) being configured to be assembled in a sealed manner on a face of one of the two circulation plates (3) so as to close the cavities (51), the cavities (51) being projections on the face of the reservoir plate (5) such that a second heat transfer fluid can circulate between the cavities (51), the tube (1) further containing a phase change material stored in the housings formed by the cavities (51), the phase change material having a solidification temperature between 6 and 8 degrees Celsius.

A three fluid phase change material (PCM) heat exchanger for a vehicle comprises (i) an intake air channel having a first set of fins disposed therein and configured to receive and output intake air prior to combustion by an engine of the vehicle, (ii) a PCM layer surrounding the intake air channel and configured to cool the intake air, the PCM layer comprising a second set of fins, a PCM fluid that expands when freezing, and a set of elastomeric devices are configured to compress to compensate for the PCM fluid expansion during freezing, and (iii) a refrigerant channel surrounding the PCM layer and configured to circulate a refrigerant to cool the PCM layer to a solid, frozen state.

A refrigerator includes a cabinet, a first inner case that defines a freezing compartment, a second inner case that defines a refrigerating compartment, a thermal siphon unit that is configured to carry a working fluid for heat transfer and that has a closed loop shape that includes a first part arranged at an outer side of the first inner case and a second part arranged at an outer side of the second inner case, and a cool air storage unit arranged in a space partitioned in the first inner case. The cool air storage unit is configured to accommodate cool air of the freezing compartment and transfer the cool air to the first part of the thermal siphon unit arranged outside of the first inner case.

Provided are a latent heat storage material having a melting point within a prescribed temperature range; a latent heat. The latent heat storage material includes a compound (A) represented by a formula (A), an inorganic salt (B) represented by a formula (B) and composed of a cation of an alkali metal and an anion of the same element as the anion of the quaternary alkyl salt, and water. The compound (A) is a material that forms a clathrate hydrate together with the water, the composition ratio of the compound (A) and water is a composition ratio that gives a congruent melting point of the clathrate hydrate, and the molar ratio of the inorganic salt (B) to the compound (A) is 0.1 or more and 10 or less.

In one aspect, thermal energy storage systems are described herein. In some embodiments, such a system includes at least one active thermal storage battery and at least one passive thermal storage battery. The at least one active thermal storage battery includes a container, a heat exchanger disposed within the container, and a first phase change material disposed within the container and in thermal contact with the heat exchanger. The at least one passive thermal storage battery comprises a plurality of thermal storage cells, individual thermal storage cells comprising a container having an interior volume, and a second phase change material disposed within the interior volume of the container.