A heat storage device includes: a heat storage material that absorbs or release latent heat with a phase transition between a liquid phase and a solid phase; and a heat conduction member that includes a contact surface contacting the heat storage material. The heat conduction member has a thermal conductivity higher than a thermal conductivity of the heat storage material. The contact surface includes an upstream region and a downstream region that is located at downstream side of the upstream region in a flowing direction of a heat medium. A wettability of the contact surface with respect to the heat storage material is higher in the downstream region than in the upstream region.

This relates to a cooling circuit comprising a liquid circulation path and arranged on the path: in series, an engine (2) and a radiator (8), mounted on a first branch in parallel between the inlet and outlet of the radiator, a store-exchanger (10) containing at least one volume: enclosing elements for storing and releasing thermal energy, involving a phase change material PCM, placed in a heat exchange relationship with said liquid (9), and around which are arranged at least one first layer containing a PCM and one second layer containing a porous thermally insulating material, and valves (14, 16, 18) so positioned as to direct the circulation of the liquid arriving from the engine toward the radiator and/or the store-exchanger.

A system and method of using the system is provided for cooling a building space through the use of thermal storage and release of energy by charging and discharging a phase change material comprising low temperature wax.

A heat store for storing at least 100 MWh of thermal energy of a relatively warmer gas in a charging state and for giving off thermal energy to a relatively colder gas in a discharging state is provided. In the charging state, the heat store has at least one inflow surface, provided with inflow openings, for introducing the gas, and at least one outflow surface, provided with outflow openings, for discharging the gas after giving off heat to a granular heat storage medium, wherein the inflow surface is formed at least in certain portions into a channel which is surrounded, in particular completely, by the outflow surface, and wherein an intermediate space in which the granular heat storage medium is arranged is defined between the inflow surface and the outflow surface.

A thermal conveyance system and process for absorbing, transporting, storing, and recovering thermal energy (both hot and cold energy) over a wide range of temperatures from up to 2,100 F., or higher, or cool energy at subzero temperatures in inert and stable particles without the need to maintain a minimum temperature or requiring high system pressures. The process involving the transferring thermal energy to a first transfer fluid and recovering thermal energy from a second transfer fluid wherein the first and the second transfer fluids comprise a two phase thermal media including a gaseous carrier containing a quantity of micron to millimeter sized solid particles.

An evaporative cooling system includes an indirect cooling coil containing a cooling fluid to be circulated and a blower assembly configured to generate an inlet air stream through the indirect cooling coil. The cooling fluid in the indirect cooling coil is a slurry of water and phase change material.

A transient cooling system includes a first phase change material (PCM) element and a second PCM element. The first PCM element includes a first PCM, a first surface, and a second surface, the first surface complementary to a surface to be cooled. The second PCM element includes a second PCM and a third surface in thermal contact with the second surface. The first PCM and the second PCM may have different thermal characteristics.

There is disclosed a cooling system. The cooling system comprises a main cooling unit and a main chilling unit in fluid communication with a heat exchanger, the main chilling unit being configured to cool a liquid coolant for use with the heat exchanger. The cooling system further comprises a back-up cooling unit that includes a cooling reservoir including a plurality of small-sized self-contained cooling accumulators; a secondary chilling unit configured to cool the plurality of small-sized cooling accumulators, during a charging phase; a valve configured to selectively couple the cooling reservoir to the main cooling unit during a release phase so that the plurality of small-sized cooling accumulators provide a heat sink to cool the cooling fluid for the main cooling unit.

An evaporative cooling system includes an indirect cooling coil containing a cooling fluid to be circulated and a blower assembly configured to generate an inlet air stream through the indirect cooling coil. The cooling fluid in the indirect cooling coil is a slurry of water and phase change material.

A thermal energy storage unit is disclosed. The system comprising: a tube having at least one inlet and at least one outlet for a first fluid; a plurality of plate-shaped or box-shaped capsules having a second fluid therein, wherein the plurality of capsules is arranged inside the tube to form a plurality of stacks of capsules; wherein: the first fluid is a heat transfer fluid for exchanging heat with the second fluid; the second fluid is a phase-change medium; wherein a plurality of defined narrow flow paths for the first fluid is provided between the capsules. The defined flow paths increase the efficiency of the system.