A computing device comprises a housing, a heat-generating electronic component, at least one additional electronic component, and a liquid cooling module. The heat-generating component, the at least one additional electronic component, and the liquid cooling module are all positioned inside the housing. The liquid cooling module is configured to cool the heat-generating electronic component, and includes at least one movable radiator. The at least one movable radiator is configured to move between a first position and a second position. When the at least one movable radiator is in the first position tank, the at least one movable radiator blocks access to the at least one additional electronic component within the housing. When the at least one movable radiator is in the second position, the at least one movable radiator allows access to the at least one additional electronic component within the housing.

An electronic rack includes a rack manifold to be coupled to an external cooling fluid source, including a supply rack manifold and a return rack manifold, wherein the rack manifold includes a plurality of pairs of rack connectors disposed thereon. The electronic rack further includes a server chassis including a connector holder having a pair of a supply server connector and a return server connector to be connected with a corresponding pair of rack connectors of the rack manifold. The electronic rack further includes a controller, in response to detecting a leakage of the cooling fluid, configured to cause the supply server connector to disconnect from the supply rack manifold, while maintaining the return server connector connected with the return rack manifold, and to increase a flowrate of the cooling fluid on the return rack manifold to remove the cooling fluid residing within the server chassis.

A multiple phase cooling system is described for an electronic rack, a cluster of servers, and for a data centers. An inlet of a 3-way flow control valve (FCV) is coupled to a main coolant source. A first outlet of the FCV is coupled to a single-phase cooling system and a second outlet of the FCV is coupled to a two-phase cooling system. The FCV is configured to adjust an amount of coolant between the single-phase cooling system and the two-phase cooling system. Upon detecting a rise in vapor pressure in a return line of the two-phase cooling system, the FCV can be adjusted to direct more coolant to the two-phase cooling system and less coolant to the single-phase system. The FCV can continuously monitor the vapor pressure and adjust the amount of coolant to each cooling system accordingly.

A cooling arrangement for an electronic device comprises a primary cooling device and a secondary cooling device. The primary cooling device includes a fluidic input line receiving a cooling fluid from a cooling fluid source and a fluidic output line returning the cooling fluid toward a drain. The primary cooling device is thermally connected to the electronic device, receives the cooling fluid from the fluidic input line and transfers heat from the electronic device to the cooling fluid before returning the cooling fluid via the fluidic output line. A flow detection device monitors a flow of the cooling fluid in the primary cooling device. The secondary cooling device is thermally connected to the electronic device. A processor activates the secondary cooling device to absorb and dissipate heat from the electronic device when the flow detection device detects a lack of flow of the cooling fluid in the primary cooling device.

A server device includes a casing, an electronic assembly, a cover, and a heat dissipation device. The electronic assembly includes a circuit board and at least one heat source. The circuit board is disposed on the casing, and the heat source is disposed on the circuit board. The cover is slidably disposed on the casing. The heat dissipation device includes at least one air cooling heat exchanger and at least one liquid cooling heat exchanger. The air cooling heat exchanger is fixed on and thermally coupled with the heat source. The liquid cooling heat exchanger is fixed on the cover and thermally coupled with the air cooling heat exchanger.

A cooling plate for cooling microchip having redundant cooling fluid circulation. A primary fluid cooling loop removes heat directly from the microchip. A secondary cooling loop acts as a condenser for two phase cells, thus removing heat indirectly from the microchip. The cold plate may be fabricated as two parts bottom plate and top plate, wherein the primary cooling loop is formed in the bottom plate and the secondary cooling loop is formed in the top plate. Two-phase, self-contained cells may be immersed in the primary cooling loop and act to transport heat from the microchip to the secondary cooling loop.

A cooling device includes a cooling plate with a bottom wall portion with a lower surface which contacts a heat-generating component, a top wall portion which covers an upper surface of the bottom wall portion, a side wall portion which couples the bottom wall portion and the top wall portion, and an internal space which is surrounded by the bottom wall portion, the top wall portion, and the side wall portion to define a first cooling medium flow passage. The bottom wall portion includes blades on the upper surface. An inlet port or an outlet port is on one end side of the first cooling medium flow passage. An inner peripheral wall of the side wall portion includes a first bent portion which is bent convex inward between ends of the blades and the at least one of the inlet port and the outlet port.

This disclosure provides a nonaqueous coolant composition excellent in insulation property, heat transfer characteristic, and hydrolysis resistance. The embodiment is a coolant composition that includes at least one ketone compound having 6 or more carbon atoms as a nonaqueous base and is substantially free of water.

Presented herein is a plurality of arrangements of cold plates having interior chambers. The interior chamber includes a plurality of fins with a first fin zone and a second fin zone. The cold plate further includes a first fluid inlet and a first fluid outlet. The cold plates can be connected such that each cold plate allows unidirectional flow or counter flow configurations. Unidirectional flow or counter flow cold plates can be arranged in rows and in combination of rows.

A liquid-cooling radiator includes liquid pipes, heat-dissipating fins arranged on the liquid pipes, two reservoirs, a liquid-collecting box, a liquid pump, and a heat-dissipating base. The two reservoirs are mounted to two ends of the liquid pipes, respectively. The reservoir at one end is partitioned into a first cold liquid reservoir and a second cold liquid reservoir, and the reservoir at the other end is partitioned into a first hot liquid reservoir and a second hot liquid reservoir, thereby forming a bilateral circulation. The liquid-cooling radiator effectively improves the balance and stability of liquid flow and has a better heat dissipation effect.