Examples of the disclosure relate to a cooling system for cooling one or more electronic components. The cooling system comprises at least one two-phase cooling system configured to cool one or more electronic components that are thermally coupled to the at least one two-phase cooling system and at least one air-cooling system configured to cool one or more electronic components. The at least one air-cooling system comprises at least one heat exchanger within the at least one air-cooling system wherein the at least one heat exchanger is coupled to a two-phase cooling system or a liquid phase cooling system. The at least one air-cooling system also comprises recirculation means configured to re-circulate air through the at least one air-cooling system to the one or more electronic components.

Systems and methods for cooling a datacenter are disclosed. In at least one embodiment, a cold plate includes an evaporator to remove heat from at least one computing device using a two-phase fluid and using a buffer to perform flow stabilization represented by different volumes or different flow rates of a two-phase fluid that is enabled to flow between an evaporator and a condensing or compressor unit located external to a cold plate.

An electronic device configured to be connected to external heat dissipation device and including chassis, heat source and heat dissipation assembly. The heat source is disposed on the chassis. The heat dissipation assembly includes evaporator and condenser. The evaporator is in thermal contact with the heat source. The condenser is disposed on the chassis and comprises first thermally conductive plate, second thermally conductive plate and third thermally conductive plate that are stacked on one another. A condensation space is formed between the first thermally conductive plate and the second thermally conductive plate. A first liquid-cooling space is formed between the second thermally conductive plate and the third thermally conductive plate. The condensation space is in fluid communication with the evaporator. The first liquid-cooling space is not in fluid communication with the condensation space and is configured to be in fluid communication with the external heat dissipation device.

A vapor chamber is disclosed. The vapor chamber includes a first cover close to a heat source, and a second cover far from the heat source. The first cover and the second cover form a cavity, the cavity is divided into at least a first cavity and a second cavity, and the first cavity and the second cavity have different cross-sectional sizes. A first wick is disposed in the first cavity, and the first wick has one end connected to the first cover and the other end connected to the second cover. A second wick is disposed in the second cavity, and the second wick is parallel to the first cover. The first wick is connected to the second wick, and the first cavity communicates with the second cavity.

A heat sink is provided. The heat sink includes a base board and a rib board. The base board includes a base board cavity, and the rib board includes a rib board cavity. The base board includes a first board face and a second board face. A groove is disposed on the second board face. The base board cavity is filled with a liquid working medium. The rib board includes at least one partition board. The at least one partition board separates the rib board cavity into at least two chambers. The at least two chambers are separately connected to the base board cavity. One end of the rib board is inserted in the base board through the groove. One end of the partition board is located in the base board.

A hybrid heat sink includes a solid heat dissipation module and a TS heat dissipation module. The solid heat dissipation module includes a solid substrate and solid fins. The solid substrate has a first side surface and a second side surface opposite to each other. The first side surface is for contacting a heat source, and the solid fins are connected to the second side surface. The TS heat dissipation module includes a TS substrate and TS fins fixed to the TS substrate. A receiving cavity for receiving a phase-change working medium is formed in the TS substrate, condensation reflux cavities are formed in the TS fins and are communicated with the receiving cavity. The TS substrate is fixed at a mounting opening of the solid substrate with a side surface of the TS substrate being exposed to the first side surface for contacting the heat source.

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 wavelength conversion device includes a rotating device, a substrate rotated by the rotating device, a wavelength conversion element, and a first cooling device including, on an inside, a space in which working fluid is encapsulated, the first cooling device cooling the wavelength conversion element. The first cooling device is disposed in a position corresponding to the wavelength conversion element. The space extends from an outer edge side of the substrate to a rotation axis side. The first cooling device includes an evaporator and a condenser which are provided in the space. The evaporator includes a liquid retaining part configured to retain the working fluid in a liquid phase. The liquid retaining part is provided at the outer edge side in the space and disposed in the position corresponding to the wavelength conversion element.

An integrated power electronic assembly includes a power electronic device, a cooling assembly offset from and thermally coupled to a second edge of the power electronic device, and a thermal spreader offset from and thermally coupled to a first edge of the power electronic device. The first edge of the power electronic device is opposite the second edge of the power electronic device, and the thermal spreader is thermally coupled to the cooling assembly.

This invention describes the use of pre-packaged air shipping containers for delivery of edge data center equipment. The containers are capable of rapid deployment and positioning at the edge data center delivery site to minimize time between the order of equipment and deployment of a functioning edge data center. The containers allow for easy access, and rapid repair/replacement of modular edge data center equipment.