The disclosure relates to a housing comprising at least one composite wall comprising woven or braided carbon fibers covered with a thermoplastic or thermosetting resin, an electronic card carrying electronic components, and a heat transfer device having at least one portion facing an electronic component to be cooled of the electronic card, said heat transfer device being inserted inside the composite wall, the heat transfer device comprising at least one cooling conduit containing a cooling fluid.

Methods and system are provided for a heat exchanger. In one example, a system, comprises a mobile electronic device comprising a front cover and a rear cover, a heat exchanger arranged between the front cover and the rear cover, the heat exchanger comprising a fluid chamber arranged between an inner surface of a first plate and an inner surface of a second plate, and a wick material arranged within the fluid chamber, the wick material comprising a sintered material configured to allow a plurality of fluid passages to extend therethrough.

A refrigeration system for a data center includes an indoor module, a main outdoor heat-dissipation module and an auxiliary outdoor heat-dissipation module, inlets of the first compressor and the second compressor are respectively connected to an outlet of the indoor module, outlets of the first compressor and the second compressor are respectively connected to a gaseous refrigerant inlet of the first condenser, liquid refrigerant outlets of the first condenser and the second condenser are respectively connected to an inlet of the indoor module, in which a refrigeration cycle passage for the data center is formed by the indoor module, the first condenser and the first compressor when the main outdoor heat-dissipation module is in a normal condition, and the refrigeration cycle passage for the data center is formed by the indoor module, the second condenser and the second compressor when the main outdoor heat-dissipation module fails.

A rack cooling system includes a primary cooling condenser and a secondary cooling condenser. The primary cooling condenser is positioned above servers of a server rack and the secondary cooling condenser is position above the primary cooling condenser. Each of the severs, the primary cooling condenser, and the secondary cooling condenser is connected to a liquid manifold via one of a plurality of liquid ports on the liquid manifold, and to the vapor manifold via one of a plurality of vapor ports on the vapor manifold. A cooling capacity of the rack cooling system can be extended by switching on a vapor flow between the secondary cooling condenser and the primary cooling condenser using a first valve on the vapor manifold. Further, a second valve on a primary cooling loop can be used to control cooling fluid flowing into the secondary cooling condenser after the first valve is trigged open.

A projector includes a first cooling target, a cooling device, and an exterior housing that houses the first cooling target and the cooling device. The cooling device includes a first compressor configured to compress working fluid, a condenser configured to condense the working fluid, a first expander configured to decompress the working fluid, a first evaporator configured to change the working fluid to the working fluid in the gas phase with heat transferred from the first cooling target, a first connection pipe configured to lead the working fluid discharged from the first expander to the first evaporator, a second connection pipe configured to lead the working fluid discharged from the first evaporator to the first compressor, and a first case configured to seal the first expander, the first connection pipe, the first evaporator, and the second connection pipe on an inside.

A system and method for cooling an electronic datacenter component using a two-phase thermal management system with dynamic thermoelectric regulation. The system includes a thermoelectric cooler to transfer heat to a hot conduit of the thermal management system and initialize or maintain a natural convective flow of working fluid by maintaining a temperature difference between a hot and cold conduit.

A heat dissipation apparatus includes a heat dissipation substrate, a heat dissipation component, and a plurality of heat dissipation fins disposed on a first side of the heat dissipation substrate. The heat dissipation fins are configured to dissipate heat on the heat dissipation substrate. A first surface of the heat dissipation component is fastened on a second side of the heat dissipation substrate. There is a gap between a side surface of the heat dissipation component and the heat dissipation substrate, and a second surface of the heat dissipation component is used to be attached to a first to-be-heat-dissipated component, to dissipate heat on the first to-be-heat-dissipated component. An area that is on the second side of the heat dissipation substrate is used to be attached to another to-be-heat-dissipated component. Heating power of the first to-be-heat-dissipated component is greater than heating power of the another to-be-heat-dissipated component.

A coolant management unit for providing liquid cooling for backup battery unit (BBU) modules of an electronic rack includes a BBU return manifold, a BBU supply manifold, a balance loop, and a power bus. For example, a BBU supply manifold having a rack supply connector to receive cooling fluid from a rack supply manifold and a BBU supply connector to be connected to one of the BBU modules to distribute the cooling fluid. A BBU return manifold to be coupled to a rack return manifold, wherein the BBU return manifold is to receive vapor from the BBU modules. A balance loop connected to each of the BBU modules to establish a fluid connection amongst the BBU modules, such that a level of the cooling fluid in each of the BBU modules remains similar.

A heat dissipation apparatus includes a heat dissipation substrate, a heat dissipation component, and a plurality of heat dissipation fins disposed on a first side of the heat dissipation substrate. The heat dissipation fins are configured to dissipate heat on the heat dissipation substrate. A first surface of the heat dissipation component is fastened on a second side of the heat dissipation substrate. There is a gap between a side surface of the heat dissipation component and the heat dissipation substrate, and a second surface of the heat dissipation component is used to be attached to a first to-be-heat-dissipated component, to dissipate heat on the first to-be-heat-dissipated component. An area that is on the second side of the heat dissipation substrate is used to be attached to another to-be-heat-dissipated component. Heating power of the first to-be-heat-dissipated component is greater than heating power of the another to-be-heat-dissipated component.

Provided is a cooling apparatus for an electronic element having improved heat dissipation performance while minimizing the size. To this end, the cooling apparatus for an electronic element according to the present invention includes a first chamber in a non-vacuum state, the first chamber being configured such that a printed circuit board equipped with a heat-generating element is disposed in the first chamber, a second chamber in a vacuum state, the second chamber being configured such that a spray unit configured to spray a refrigerant and a refrigerant supply unit configured to supply the refrigerant to the spray unit are disposed in the second chamber, and an evaporation unit disposed between the first chamber and the second chamber, in which the spray unit sprays the refrigerant, which is supplied by the refrigerant supply unit and condensed in the second chamber, into the second chamber, and in which the evaporation unit evaporates the refrigerant, which is sprayed into the second chamber by the spray unit, by using sensible heat transferred from the first chamber to the evaporation unit and latent heat transferred from the evaporation unit to the second chamber.