A heat exchanger includes a housing configured to contain a working fluid. The heat exchanger also includes a plurality of chambers disposed within the housing and arranged so as to be surrounded by the working fluid when the working fluid is within the housing, each chamber configured to contain a phase change material (PCM) that expands upon freezing. The walls of each chamber are formed of a high thermal conductivity material that allows transfer of thermal energy between the working fluid and the PCM in each chamber. The walls of each chamber include expandable bellows configured to deform to increase an internal volume of the chamber as the PCM expands upon freezing.

A method and device for supplying an inert gas in a beverage filling plant are provided. The method includes feeding surplus process heat from the beverage filling plant to a heat exchanger, feeding an inert gas from an inert gas source to the heat exchanger, heating the inert gas in the heat exchanger, and supplying the heated inert gas for use in the beverage filling plant.

A method and device for supplying an inert gas in a beverage filling plant are provided. The method includes feeding surplus process heat from the beverage filling plant to a heat exchanger, feeding an inert gas from an inert gas source to the heat exchanger, heating the inert gas in the heat exchanger, and supplying the heated inert gas for use in the beverage filling plant.

Liquid cooling station comprises at least one pump and at least one motor connected to the pump for operating the pump to circulate cooling liquid between the cooling station and an object to be cooled, a first cooling liquid outlet port for supplying the cooling liquid towards the object to be cooled and a first cooling liquid inlet port for receiving the cooling liquid from the object to be cooled. The liquid cooling station further comprises at least one connection block, which comprises at least one first cavity for receiving an operating part of the pump, at least one second cavity for an additional operational part, the first cooling liquid inlet and outlet ports and an internal channel system connecting the first cavity to the first cooling liquid inlet and outlet ports.

Liquid cooling station comprises at least one pump and at least one motor connected to the pump for operating the pump to circulate cooling liquid between the cooling station and an object to be cooled, a first cooling liquid outlet port for supplying the cooling liquid towards the object to be cooled and a first cooling liquid inlet port for receiving the cooling liquid from the object to be cooled. The liquid cooling station further comprises at least one connection block, which comprises at least one first cavity for receiving an operating part of the pump, at least one second cavity for an additional operational part, the first cooling liquid inlet and outlet ports and an internal channel system connecting the first cavity to the first cooling liquid inlet and outlet ports.

The heat storage material storage container comprises a main body having a longitudinal direction and including a plurality of flow channels therein, the flow channels extending parallel to each other in the longitudinal direction and separated from each other by porous walls and a heat storage material contained in only one or some of the plurality of flow channels. The plurality of flow channels include a plurality of first flow channels each having an open end on a first side in the longitudinal direction and a closed end on a second side in the longitudinal direction and a plurality of second flow channels each having open ends on both the first side and the second side in the longitudinal direction. The heat storage material is contained in only the first flow channels.

The heat storage material storage container comprises a main body having a longitudinal direction and including a plurality of flow channels therein, the flow channels extending parallel to each other in the longitudinal direction and separated from each other by porous walls and a heat storage material contained in only one or some of the plurality of flow channels. The plurality of flow channels include a plurality of first flow channels each having an open end on a first side in the longitudinal direction and a closed end on a second side in the longitudinal direction and a plurality of second flow channels each having open ends on both the first side and the second side in the longitudinal direction. The heat storage material is contained in only the first flow channels.

A liquid-encapsulation heat dissipation member is prepared by encapsulating a thermally conductive fluid in a closed container nd dissipates heat transferred from an electronic device in contact with the closed container, wherein the closed container includes an elastic portion composed of a thin elastomer serving as a surface to come into contact with the electronic device and following the shape of the electronic device and a heat dissipation portion composed of a hard material for dissipating heat, and the thermally conductive fluid contains a thermally conductive powder and has a viscosity of 200,000 mPa.Math.s to 3,000,000 mPa.Math.s.

A liquid-encapsulation heat dissipation member is prepared by encapsulating a thermally conductive fluid in a closed container nd dissipates heat transferred from an electronic device in contact with the closed container, wherein the closed container includes an elastic portion composed of a thin elastomer serving as a surface to come into contact with the electronic device and following the shape of the electronic device and a heat dissipation portion composed of a hard material for dissipating heat, and the thermally conductive fluid contains a thermally conductive powder and has a viscosity of 200,000 mPa.Math.s to 3,000,000 mPa.Math.s.

A data center cooling system includes a modular heat sink and a working fluid. The modular heat sink includes an evaporator configured to thermally contact a heat-generating electronic device to receive heat from the data center heat-generating electronic device; a condenser coupled to the evaporator and configured to transfer the heat from the heat-generating electronic device into a cooling fluid; and a plurality of transport tubes that fluidly couple the evaporator and the condenser, at least one of the plurality of transport tubes including an open end positioned in the evaporator and a closed end positioned in the condenser. The working fluid vaporizes in the evaporator based on receipt of the heat from the heat-generating electronic device, and circulates, in vapor phase, from the evaporator to the condenser in the transport member, and circulates, in liquid phase, from the condenser to the evaporator.