A cooling system including a support structure, a cooling element, and a bottom plate is described. The cooling element has a central region and a perimeter. The cooling element is supported by the support structure at the central region. At least a portion of the perimeter is unpinned. The cooling element undergoes vibrational motion when actuated to drive a fluid toward a heat-generating structure. The bottom plate has orifices and at least one cavity therein. The at least one cavity is adjacent to and fluidically connected with the orifices. The at least one cavity and the orifices define an orifice distance between the orifices and the heat-generating structure and an orifice length within the bottom plate. The heat-generating structure and the bottom plate define a gap between a portion of the bottom plate and a portion of the heat-generating structure.

The present disclosure relates to heat dissipation apparatuses. In an example, a node includes a structural module, a circuit board, a liquid pipe, and a liquid leakage monitoring apparatus. The circuit board is securely mounted on the structural module, and an electronic component including a chip is disposed on the circuit board. The liquid pipe is disposed on the circuit board, and is configured to dissipate heat for the electronic component on the circuit board. The liquid leakage monitoring apparatus includes a drainage pipe sleeved outside the liquid pipe. There is a specific gap between the drainage pipe and the liquid pipe. In response to at least that leakage occurs in the liquid pipe, leaked coolant flows in the drainage pipe.

A self-contained mobile high performance computing platform for cryptocurrency mining is disclosed. The self-contained mobile high performance computing platform includes a mobile cabinet, which includes wheels for easy movement and placement within, for example, a warehouse facility, a garage, a basement, an office tower, or a vehicle such as a truck or van. The cabinet is configured to enclose at least one computing apparatus, which includes computing blades immersed in an oil or other dielectric fluid for immersion cooling. The computing blades are configured to be connected to respective interface boards via connectors that are located within a tank of the dielectric fluid. Each computing blade may be individually removed or replaced, thereby enabling an inoperable or low performance computing blade to be disconnected without affecting the operations of the other computing blades.

An electronic equipment chassis comprises a chassis housing and two or more cooling compartments in the chassis housing. At least a first one of the two or more cooling compartments in the chassis housing utilizes a first type of cooling for a first set of electronic equipment housed therein, and at least a second one of the two or more cooling compartments in the chassis housing utilizes a second type of cooling for a second set of electronic equipment housed therein. The first type of cooling comprises liquid immersion cooling and the second type of cooling comprises non-liquid immersion cooling.

An information handling system includes a first set of components, a second set of components, and a hybrid cooling system. The hybrid cooling system includes a fan structure, a liquid cooling system, and a fan insert. The fan structure includes multiple cooling fans to provide air cooling to the first components of the information handling system. The liquid cooling system provides liquid cooling to one or more of the second components. The liquid cooling system includes a first liquid line routed through an empty fan cavity of the fan structure. The fan insert is located within the empty fan cavity and provides a seal against air-bypass and recirculation within the information handling system.

A nipple assembly includes nipple bodies configured so that one end portion of each of the nipple bodies is inserted into a housing so as to be coupled to a cooling medium inlet or a cooling medium outlet of a heat exchanger and a remaining end portion of each of the nipple bodies protrudes outwards from the housing, at least one first sealing unit sealing a gap between the one end portion of each of the nipple bodies and the cooling medium inlet or the cooling medium outlet, a flange portion formed at a position between two end portions of each of the nipple bodies to be coupled to the housing, and a second sealing unit including a first sealing portion sealing a gap between the flange portion and the housing and a second sealing portion configured to extend from the first sealing portion.

An adapter plate and a fastening system for fastening a manifold to a rack in a datacenter is disclosed. The adapter plate is associated with the manifold and has holes to receive buttons in configurable positions. The configurable positions enable the buttons to mate with keyholes of a bracket of the rack in order to fasten the manifold to the bracket.

A cold plate apparatus that has an outlet plenum leading to an outlet opening includes an outlet transition that connects the outlet opening to the outlet plenum. The outlet transition defines a smoothly curving flow path from a direction along a long dimension of the outlet plenum, which is parallel to a plane defined by the outlet opening, to a direction along a centerline of the outlet opening, which is at an angle from the plane defined by the outlet opening. The outlet transition provides a smooth variation of cross-sectional area from the outlet plenum to the outlet opening.

A cooling apparatus includes a cold plate made of a metal, a casing, a pump, a ground wire, and a conductive component. The pump includes a motor to drive an impeller, and a circuit board to control the motor. The circuit board is connected to the ground wire. The conductive component electrically connects the cold plate to the ground wire.

A cooling liquid flow control device includes a heat dissipation bottom plate, a fixing holder, a cooling module, and a temperature control element. The heat dissipation bottom plate has a bottom surface configured to be in contact with a heating element on a substrate. The fixing holder is connected to the heat dissipation bottom plate and configured to be fixed with the substrate. The cooling module is connected to a top surface of the heat dissipation bottom plate to form a cavity. The cavity is configured to circulate a cooling liquid. The temperature control element is disposed in the cavity and is configured to deform based on a temperature of the cooling liquid in the cavity, thereby adjusting a flow rate of the cooling liquid in and out of the cavity.