One feature pertains to an acoustic attenuation device. The acoustic attenuation device comprises a fan assembly, the fan assembly including at least one fan module that directs airflow in at least one direction, wherein the at least one fan module includes a top surface and a bottom surface, a plurality of air deflectors mounted to the top surface and the bottom surface of the at least one fan module, wherein the plurality of air deflectors include a plurality of surfaces, and wherein at least one of the plurality of surfaces is an angled surface that redirects the airflow 90-degrees, and acoustic attenuating foam, wherein the acoustic attenuating foam has a two-dimensional (2-D) surface and is applied to interior surfaces of the plurality of surfaces.

One feature pertains to a data storage cooling module. The data storage cooling module comprises a fan cage assembly, the fan cage assembly including a fan cage that includes at least one fan bay, at least one fan assembly removably coupled to the at least one fan bay, and an interface board removably coupled to the fan cage assembly, the interface board including a first interface surface that includes at least one power connector configured to interface with the at least one fan assembly, and a second interface surface that includes at least one drive connector configured to interface with a baseboard.

An electronic device includes a first body including a first part and a second part hinged to each other, a second body, and a hinge structure hinged between an edge of the second body and the second part. The first part has a recess. When the second body is unfolded relative to the first body from a folded state to a first unfolded state, the hinge structure pushes against the first part to rotate the first part relative to the second part. When the second body is continuously unfolded relative to the first body from the first unfolded state to a second unfolded state, the edge of the second body pushes against the first part, so that the first part continues to rotate relative to the second part. When the second body is in the folded state, the hinge structure is at least partially accommodated in the recess.

A fan tray, for a fan module of a network device chassis, may include an inner assembly that includes an inner cassette, one or more fans connected to the inner cassette, a first latch connected to the inner cassette and configured to removably connect to an outer assembly of the fan tray, and a fan controller connected to the inner cassette and configured to control operation of the one or more fans. The outer assembly may be configured to receive and retain the inner assembly, and may include an outer cassette with one or more openings configured to communicate with the one or more fans, a second latch connected to the outer cassette and configured to removably connect to a rear portion of the network device chassis, and an adaptor connected to the outer cassette and configured to connect and provide power to the fan controller.

A cooling system and method for using the cooling system are described. The cooling system includes a plurality of individual piezoelectric cooling elements spatially arranged in an array extending in at least two dimensions, a communications interface and driving circuitry. The communications interface is associated with the individual piezoelectric cooling elements such that selected individual piezoelectric cooling elements within the array can be activated based at least in part on heat energy generated in the vicinity of the selected individual piezoelectric cooling elements. The driving circuitry is associated with the individual piezoelectric cooling elements and is configured to drive the selected individual piezoelectric cooling elements.

The present invention relates to a heat dissipation device for an electronic element, the heat dissipation device including a first chamber in which a printed circuit board having heating elements mounted thereon is disposed, a second chamber configured to exchange heat with heat transferred from the first chamber and configured such that an injection part configured to inject a refrigerant and a refrigerant supply part configured to supply the refrigerant to the injection part are disposed in the second chamber, a heat transfer part disposed between the first chamber and the second chamber and configured to receive heat from the heating elements of the first chamber and supply the heat to the second chamber, and a condensing part configured to condense the refrigerant injected into the second chamber, in which a plurality of evaporation-inducing ribs is provided on a surface of the heat transfer part exposed to the second chamber and allows the liquid refrigerant injected by the injection part to be adsorbed and then flow downward along wave-pattern flow paths having zigzag shapes, thereby providing an advantage of improving heat dissipation performance without increasing a size thereof.

A fan cage is at least adapted to a first fan and a second fan smaller than the first fan. The fan cage includes a cage body and an adjustment member. The cage body defines a first accommodation portion in a size fitting the first fan. The adjustment member is movably disposed on the cage body and switchable between a laid down status and an upright status within the first accommodation portion. When the adjustment member is in the upright status, the adjustment member is upright in the first accommodation portion so that the adjustment member and the cage body together define part of the first accommodation portion as a second accommodation portion in a size fitting the second fan.

In one embodiment, a method for managing a heatsink of an information handling system includes: determining, by a controller unit of the information handling system, that a vibration event is to occur, the vibration event associated with a vibration unit of the information handling system, the controller unit communicably coupled to the vibration unit, the vibration unit removably coupled to the heatsink; and causing, by the controller unit, the vibration unit to generate the vibration event, the vibration event causing the vibration unit to apply one or more vibrations to the heatsink, the one or more vibrations causing a boundary layer of particles to be removed from a surface of the heatsink.

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.

An electronic device includes an enclosure, an air mover assembly, and a printed circuit board. The enclosure houses electrical components. The air mover assembly includes at least a portion of a motor, and the printed circuit board is spaced from the enclosure and includes stator coils of the motor within the printed circuit board.