Self-contained server assemblies for housing servers or server blades and associated computing facilities are disclosed herein. In one embodiment, a server assembly includes an enclosure having an interior space housing a server blade, a dielectric coolant submerging heat producing components of the server blade, and a condenser assembly having a condenser coil in fluid communication with a vapor gap in the interior space. The condenser coil is configured to receive a coolant that removes heat from a vapor of the dielectric coolant in the vapor gap, thereby condensing the vapor into a liquid form to be returned to the server blade.

A cooling system includes a tank, a heat exchanger, a separation tank, a first tube, a second tube, a third tube, a gas storage device, a fourth tube, a first valve, a second valve and a third valve. A heating element is immersed in a dielectric liquid in the tank. The heat exchanger condenses dielectric vapor of the dielectric liquid. The separation tank is used for a separation operation. The first tube is connected to the tank and the heat exchanger. The second tube is connected to the heat exchanger and the separation tank. The third tube is connected to the separation tank and the tank. The gas storage device stores the dielectric vapor. The fourth tube is connected to the gas storage device and the separation tank.

A two-phase liquid immersion cooling system is described in which heat generating computer components cause a dielectric fluid cool the computer components. Advantageously, a pH indicator is employed to monitor the acidity of the dielectric fluid via, for example, a color change.

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.

A heat dissipation assembly and an electronic assembly, wherein the heat dissipation assembly includes condensers and fan, the condensers each include first chamber body, second chamber body, and pipes. Two opposite ends of each pipe are respectively in fluid communication with the first and second chamber bodies, every two of the pipes located adjacent to each other define a heat dissipation gap therebetween. The first and second chamber bodies and the pipes together define a heat dissipation channel which is in air communication with the heat dissipation gaps. The fan is disposed on the condensers and in air communication with the heat dissipation channel and configured to guide an airflow flowing through the heat dissipation channel and the heat dissipation gaps so as to cool the working fluid flowing through the pipes.

A heat dissipation system and an electronic device. The heat dissipation system configured to circulate working fluid and to cool heat source. Heat dissipation system includes casing, first tube, second tube, condenser and flow rate controller. Partition is fixed in the base and is located in the accommodation space to divide the accommodation space into a first and a second accommodation space. The first accommodation space is located above the second accommodation space along a gravitational direction. The inlet is in fluid communication with the first accommodation space. The outlet is in fluid communication with the second accommodation space. The partition includes a plurality of drip holes. The first and the second accommodation spaces are in fluid communication with each other via the drip holes. The working fluid is configured to drip onto the heat source via the plurality of drip holes.

Methods, systems, and devices for managing coolant in data centers are disclosed. Coolant may be used in data centers to regulate the temperatures of computing devices. The disclosed methods and system may provide for containment of vapor and condensation of the vapor into coolant. The coolant may be used as part of a two phase cooling system to cool the computing devices. The vapor may be generated when the coolant removes heat from computing devices during operation while at least partially submerged in the coolant. A mobile condenser is used for condensing the vapor within the containment.

A cooling plate for cooling high power density electronics has an internal cavity and an opening for fluid exchange with the cavity. A mounting structure is positioned within the opening. A coaxial port is attached to the mounting structure, the coaxial port having a center conduit and a ring conduit surrounding the central conduit such that rotational axis of the center conduit coincides with rotational axis of the ring conduit. A single coaxial port can serve to deliver cooling liquid to the cooling plate and return warmed fluid from the cooling plate. The coaxial port center conduit connected with a fluid distribution panel. Fluid distribution is regulated by the panel before it exits the port through the ring conduit.

A heat dissipating device includes a first casing includes a recessed portion, and a second casing coupled to the first casing. The recessed portion at least partially defines an evaporator section of the heat dissipating device, a condenser section of the heat dissipating device is disposed surrounding the recessed portion, and the first casing and the second casing enclose an internal space of the heat dissipating device. The heat dissipating device further includes a plurality of first support structures arranged in the recessed portion, a plurality of second support structures arranged in the condenser section, and a plurality of heat transfer structures arranged in the recessed portion.

A cold plate includes a first cooling surface comprising a first cooling structure bonded to an inner surface of the first cooling surface, a second cooling surface comprising a second cooling structure bonded to an inner surface of the second cooling surface, a manifold comprising an internal cavity defined by a first length, a first width, and a first height, and a flow divider defined by a second length, a second width, and a second height. The manifold is enclosed by the first cooling surface and the second cooling surface on opposing surfaces of the manifold separated by the first height. The flow divider is positioned within the internal cavity of the manifold. The flow divider supports and separates the first cooling structure and the second cooling structure by a portion of the second height of the flow divider.