Disclosed herein are cooling systems, methods of making cooling systems, and methods of cooling using cooling systems. A cooling system includes a compression container with a coolant that includes a fluid. A valve is arranged on the compression container through which the coolant is released from the compression container. The cooling system further includes a component positioned to receive droplets of the coolant. The component has a surface with a three-dimensional topography that includes a plurality of pillars and a plurality of trenches. The component is an electronic component or a photoelectronic component.

A nozzle arrangement for cooling an electronic component. The nozzle arrangement comprises: a nozzle for discharging liquid coolant; and a mount configured to disperse the liquid coolant, the mount further configured to be coupled with the electronic component. The nozzle is coupled to the mount such that, in use, the liquid coolant is discharged from the nozzle through the mount and dispersed by the mount.

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 removably 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.

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 in the chassis. The heat dissipation assembly includes evaporator, condenser and fin assembly. The evaporator is in thermal contact with the heat source. The condenser has outer surface, condensation space and liquid-cooling space. The outer surface faces away from the condensation space and the liquid-cooling space. The condensation space and the liquid-cooling space are not in fluid communication with each other. The condensation space is in fluid communication with the evaporator. The liquid-cooling space is configured to be in fluid communication with the external heat dissipation device. The fin assembly is in thermal contact with the condenser and protrudes from the outer surface of the condenser along direction away from the condensation space or the liquid-cooling space.

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.

In some examples, a controller for air and liquid cooling of electrical equipment is provided. The controller can include a cooling profile assignment module to assign a hybrid cooling profile based on temperature readings of electrical equipment; an air cooling control module to control a forced airflow cooling system for the electrical equipment in accordance with the assigned hybrid cooling profile; and a liquid cooling control module to control a liquid cooling system for the electrical equipment in accordance with the assigned hybrid cooling profile. The assigned hybrid cooling profile can indicate that the forced airflow cooling system is to be used as a primary cooling system for the electrical equipment unless temperature readings indicate that a heat profile of the electrical equipment is above a thermal threshold.

A computer module includes a substrate having redistribution layers comprising conductors and dielectrics formed on both sides of the substrate. Selected thin film conductors have a half pitch of 2 μm or less. Semiconductor components selected from bare die, chiplets, stacked devices, and low-profile packaged devices are flip chip mounted on the substrate. After grinding and polishing operations, a polished planar surface extends across each side of the substrate, coincident with the back side of the semiconductor components. Copper sheets are bonded to the polished planar surfaces using die attach films. A water-cooled server comprises multiple computer modules disposed in a tank with cooling water circulating around the modules. It dissipates 6.3 MW at a water flow rate of 339 gallons per minute and has a power density of 1 kW/in.sup.3.

A system comprises a rack, a support member, and a component configured for being supported in the rack by the support member. The support member is selectively insertable in the rack and comprises a plate at its rear end, the plate extending at an angle from a direction of insertion of the support member in the rack, the support member further comprising a first liquid connector mounted to the plate. The component comprises a second liquid connector mounted on a rear edge of the component, the second liquid connector being connectable to the first liquid connector when the support member and the component are inserted in the rack. A method comprises mounting the first and second liquid connectors to the support member and to the component, respectively, inserting the support member to the rack, and inserting the component in the rack until both liquid connectors are connected.

Systems and methods for testing in a datacenter cooling system are disclosed. In at least one embodiment, cooling hardware is associated with multiple computing devices within multiple racks of a test environment and is able to support a test for the multiple computing devices to cause different electronic stresses and different cooling stresses for the multiple computing devices in reference to established benchmarks.

A cold plate for cooling microchip. Fluid channels are formed in a semiconductor plate, each channel being defined by sidewalls. The sidewalls are doped with series of interchanging n-type and p-type regions, thereby generating a plurality of p-n junction in each sidewall. Electrical contacts are provided across the p-n junctions, thereby creating a plurality of thermoelectric cooling (TEC) devices within the sidewalls. Upon application of current to the contacts, the TEC devices transport and draw heat flux away from the microchip. The heat is then fully or partially collected by the cooling fluid flowing inside the channels.