A server system is described. The server system includes a vapor chamber in thermal communication with a plurality of heat sources and an array of microelectromechanical system (MEMS) jets arranged to cause a fluid to impinge on a surface of the vapor chamber.

An electronic device connected to external heat dissipation device and including chassis, heat source, and heat dissipation assembly. Heat dissipation assembly includes evaporator, tubing, and liquid-cooling plate. Evaporator is in thermal contact with heat source. Tubing includes evaporation portion and condensation portion. Evaporation portion is in fluid communication with condensation portion and in thermal contact with evaporator. Liquid-cooling plate is disposed on chassis and spaced apart from heat source. Liquid-cooling plate includes liquid-cooling accommodation space and is configured to be in fluid communication with external heat dissipation device. Condensation portion is located in liquid-cooling accommodation space. Condensation portion includes first tube part, second tube part and connecting tube parts. Two opposite ends of each connecting tube part are respectively in fluid communication with first and second tube parts. Connecting tube parts are connected in parallel. First and second tube parts are in fluid communication with evaporation portion.

Systems, apparatuses and methods to provide a hybrid cooling for servers of a data center are described. A cooling plate comprises an inlet port to receive a coolant from a coolant source. The coolant is a two-phase coolant that transforms from a liquid state into vapor when being attached to an electronic device to extract heat from the electronic device. The cooling plate comprises an outlet port to output at least a portion of the coolant back to the coolant source. The cooling plate comprises a vapor port to output the vapor generated from the coolant to a condenser that is configured to condense the vapor back to the liquid state.

A method of operating a cooling apparatus is described that allows flexible cooling lines connecting an inlet manifold to an outlet manifold to be safely added or removed during operation of the cooling apparatus without causing unstable two-phase flow. The method can include providing a cooling apparatus having an inlet manifold, an outlet manifold, and a bypass extending from the inlet manifold to the outlet manifold. Each manifold can include a plurality of connection ports, such as quick-connect couplers, to accommodate adding and removing cooling lines between the inlet manifold and the outlet manifold. The method can include providing a flow rate of single-phase liquid coolant to the inlet manifold and setting a pressure regulator in the bypass to provide a certain flow rate through the bypass. The flow rate through the bypass can be determined as a function of an average flow rate through each of the cooling lines.

A heatsink for a plurality of memory modules that can be connected to an electronic board, each memory module including two heat exchange surfaces, includes at least one envelope including a top surface, at least two outer tabs, configured to be in thermal contact with at least one heat exchange surface of at least one memory module, at least one contact surface, in thermal contact with the fluid cooling system of said electronic board, a plurality of inner tabs, each inner tab being interposed between two memory modules in order to make thermal contact with at least one exchange surface of each of the two memory modules, the envelope is detachably placed against the two exchange surfaces of each memory module, the envelope is mechanically detachably fastened to the board.

A cooling device configured to cool a heat source includes a tank, a bellow and a solenoid valve. The tank contains a coolant, and the heat source is immersed in the coolant. The solenoid valve includes a first channel, a second channel, a third channel and a piston. The first channel is connected to the tank. The second channel is connected to the bellow. The third channel is connected to an external space. The piston is configured to seal the second channel and the third channel. The piston is configured to connect the first channel to one of the second channel and the third channel. When the heat source is initially activated, the piston is moved to connect the first channel to the third channel. When the heat source operates, the piston is moved to connect the first channel to the second channel.

A system and method for providing and using wickless capillary driven constrained vapor bubble heat pipes for application in electronic devices with various system platforms are disclosed. An example embodiment includes: a substrate; and a plurality of wickless capillary driven constrained vapor bubble heat pipes embedded in the substrate, each wickless capillary driven constrained vapor bubble heat pipe including a body having a capillary therein with generally square corners and a high energy interior surface, and a highly wettable liquid partially filling the capillary to dissipate heat between an evaporator region and a condenser region.

It is impossible to avoid the increase in device cost and maintenance cost in order to cool a heat source efficiently using a natural-circulation type phase-change cooling device; therefore, a cooling device according to an exemplary aspect of the present invention includes a heat receiving unit for receiving heat; a condensing unit for releasing heat; and a refrigerant intermediary unit for connecting the heat receiving unit with the condensing unit, and transporting refrigerant circulating between the heat receiving unit and the condensing unit, wherein the refrigerant intermediary unit includes a refrigerant retaining unit for retaining the refrigerant, a primary tube connecting the refrigerant retaining unit with the condensing unit, and a secondary tube connecting the refrigerant retaining unit with the heat receiving unit and including a bendable tube.

An information technology (IT) enclosure may have a hybrid architecture. Such an enclosure may include an immersion tank that holds a single-phase coolant fluid. One or more servers may be immersed in the tank. The server chassis may have electronics that are thermally coupled to a two-phase fluid via a thermosiphon loop. The server chassis includes a condensing unit forming the thermosiphon loop and the condensing unit is submerged in the single phase fluid.

A cooling system, includes: an evaporator configured to take heat from a heat source by latent heat of evaporation of liquid; an aspirator configured to suck vapor generated in the evaporator and decompress an inside of the evaporator; a liquid supplying unit configured to supply liquid to the aspirator and the evaporator; and a gas mixing unit configured to mix gas into the liquid to be supplied from the liquid supplying unit to the evaporator.