A geo-thermal inverter cooling system for using the temperature of the ground to cool the fluid in the system. The geo-thermal inverter cooling system may include an inverter assembly including a housing and conversion electronic components for converting electrical energy to electrical power and which heat up during use; and a cooling assembly including a fluid reservoir in communication with the housing, and a pump in communication with the fluid reservoir for pumping fluid to cool the electronic components, wherein the fluid reservoir has a reservoir outlet port and reservoir inlet ports.

A rack system for housing an electronic device comprising: an immersion case configured to provide housing to the electronic device, and to receive an immersion cooling liquid, wherein the immersion case includes a drainage opening, wherein the drainage opening is configured to remove at least a part of the immersion cooling liquid from the immersion case, based on a user actuated action, during a de-racking operation of the immersion case; and a rack frame configured to slidably accommodate racking and de-racking operations of the immersion case.

A rack system for use, e.g., in data centers is disclosed. The rack system includes a rack frame and a rack-mounted assembly, including an electronic device disposed within the rack-mounted assembly, the electronic device including a heat-generating component. The heat-generating component is in thermal contact with a liquid cooling block through which a channelized cooling fluid is conveyed. The electronic device is immersed in a dielectric immersion cooling liquid. The rack-mounted assembly includes a non-sealed immersion case in which the electronic device is immersed in the dielectric immersion cooling liquid, the non-sealed immersion case configured to permit the rack-mounted assembly to be individually inserted into or removed from the rack frame. Also disclosed are container-based data center modules based on the disclosed rack system, and a data center using numerous such container-based modules.

An imaging system is provided that includes a gantry, plural radiation detector head assemblies, a cooling unit, and a manifold. The radiation detector head assemblies are disposed about a bore of the gantry. Each radiation detector head assembly includes a detector housing and a rotor assembly. The rotor assembly is configured to be rotated about an axis. The rotor assembly includes a detector unit that in turn includes an absorption member and associated processing circuitry. The cooling unit is mounted to the gantry and is configured to provide an output flow of air at a controlled temperature. The manifold is coupled to the cooling unit and the plural radiation detector head assemblies, and places the cooling unit and radiation detector head assemblies in fluid communication with each other. The output flow of air from the cooling unit is delivered to the plural radiation detector head assemblies.

A method and an extraction system for extracting an electronic device from a container filled with an immersion cooling liquid are disclosed. The extraction system includes a lifting device for lifting the electronic device from an open end of the container, a liquid dispersing device for dispersing immersion cooling liquid from the electronic device by generating an air flow, and a nozzle configured to be positioned above the open end of the container to limit a spread of immersion cooling liquid caused by the liquid dispersing device.

A rack system which includes a rack frame and at least one reservoir for housing at least one rack-mounted immersion case is disclosed. The rack frame is configured to slidably accommodate racking and de-racking operations of the at least one rack-mounted immersion case. The at least one collapsible reservoir, which is configured to store a fluid therein, is fluidly connected to the at least one rack-mounted immersion case, has a first portion fixedly connected to the at least one rack-mounted immersion case, and a second portion fixedly connected to the rack frame. The at least one collapsible reservoir is configured to respectively collapse and expand along a racked space and a de-racked space, the racked and de-racked spaces being defined between a backplane of the at least one rack-mounted immersion case and a backplane of the rack frame, the de-racked space being larger than the racked space.

A power conversion device includes a casing, a structural plate, a converter module, an auxiliary circuit board module and a top cover. The casing includes a base plate and a side wall, and the base plate and the side wall form a chamber. The structural plate is located in the chamber. The converter module is located between the base plate and the structural plate. The auxiliary circuit board module is located at a side of the structural plate in the chamber away from the base plate, and is electrically connected with the converter module. The top cover seals the chamber.

An arrangement for cooling components of a subsea electric system including a tank filled with a dielectric fluid. The tank includes first and second sections. The arrangement includes one first electric component within the first section, and one second electric component within the second section. The arrangement includes a first heat exchanger located outside the tank and in fluid contact with the tank, and arranged during operation to be in thermal contact with sea water. The arrangement includes a pump arranged to force a flow of dielectric fluid through the first heat exchanger. Flow of dielectric fluid in the tank is by both natural and forced convection generated by the pump. The first electric component generates more heat than the second electric component. Within the first section the share of the flow by natural convection is greater than within the second section.

A thermosiphon system includes a condenser and an evaporator fluidly coupled to the condenser by a condensate line. The evaporator includes a housing having an opening to the condensate line, a wick located in the housing, and a flow restrictor located in the housing configured to restrict flow of a working fluid from the condensate line onto a portion of the wick

A cooling system includes a first liquid cooling plate, a second liquid cooling plate, a first thermosiphon device, and a second thermosiphon device. The first liquid cooling plate has a first parallel flow channel formed by two flow channels connected in parallel. The second liquid cooling plate also has a second parallel flow channel formed by two flow channels connected in parallel. The first parallel flow channel and the second parallel flow channel are connected in series. The first thermosiphon device and the second thermosiphon device are both thermally coupled to the first liquid cooling plate and the second liquid cooling plate, and the first thermosiphon device and the second thermosiphon device are located between the first liquid cooling plate and the second liquid cooling plate.