An information handling system includes a computing device, a computing component of the computing device that is housed in a chassis, and a chilled air filter that reduces a humidity level of a portion of an airflow when the chilled air filter is in an active state. The portion of the airflow thermally manages the computing component. The airflow is received by the chassis via an air receiving exchange and exhausted by the chassis via an air expelling exchange.

A system includes a cabinet having a first wall, a second wall opposite the first wall, and a back wall extending from the first wall to the second wall. The system also includes a flow plate disposed at least partially within the cabinet and partitioning the inner space into a first portion and a second portion. The system also includes a shelf disposed at least partially within the first portion of the inner space, and a flow device fluidly connected to the cabinet. The flow device is configured to remove air from the first portion of the inner space, and the flow plate is configured to substantially prohibit removal of air by the flow device from the second portion, via the first portion, when the cabinet is in a closed condition.

A platform includes a housing with a front side, a rear side opposite the front side, a right side adjacent to both the front side and the rear side, and a left side opposite the right side and adjacent to both the front side and the rear side, wherein airflow in the platform is between the front side and the rear side or between the front side and the front side; one or more modules in the housing each including a plurality of cages supporting removable interface cards, wherein the airflow includes an air path that is over the one or more modules between a bottom portion of the one or more modules and a top portion of the one or more modules; and at least one dust cap in one of the plurality of cages, wherein the dust cap includes an air filter medium enabling airflow at an intermediate point of the air path.

The present invention includes a lateral support member for a server computer constructed to permit advantageous airflow. The present invention can be operated to shunt organized airflow into multiple computer cases and/or organized airflow from multiple computer cases to a dedicated heat reservoir.

A frame having a perimeter defines a planar opening. A set of louvers may span from a first edge of the opening to a second edge of the opening. Each louver may be capable of rotating between a closed position and an open position. A set of physical obstructions may prevent the louvers from rotating beyond the open position. Each louver may be offset from the planar opening by a first acute angle when in a closed position, and by a second, larger, acute angle when in the open position. A flow of air in a first direction through the opening may rotate the set of louvers to the closed position. A flow air in the opposite direction through the opening may rotate the set of louvers to the open position such that the flow of air in the opposite direction moves freely through the opening.

A heating and air purifying apparatus using electronic device heat includes: a cabinet accommodating electronic devices including a central processing unit (CPU), a graphic processing unit (GPU), a power supply unit (PSU), and a main board, having an air inlet on a side, and having an air outlet on a top; one or more partition plates disposed vertically, horizontally, or diagonally across the inner surface of the cabinet; and a discharge fan installed at the air outlet and discharging air in the cabinet to the outside, in which a cooling fan of the GPU is disposed on a side of the one or more partition plate, a GPU body including a graphic card of the GPU is disposed on the opposite side, and the CPU, the PSU, and the main board are accommodated in a space facing a side of the one or more partition plate.

Proposed is an electronic apparatus with which it is possible to increase design freedom concerning a wall section formed with vent holes. A rear wall section (20D) includes a rectilinear wall section (21i) spaced rearward from a rear edge (41c) of a circuit board (41), and an inclined wall section (21j) located on the rear side relative to the rectilinear wall section (21i). An inner wall section (42e) is located between the inclined wall section (21j) and the rear edge (41c) of the circuit board (41), and is not located between the rectilinear wall section (21i) and the rear edge (41c) of the circuit board (41).

Cooling arrangement of data center configured for backup operation, the arrangement including an active cooling system having: fluid cooling systems. The arrangement further including an intake louvers assuming a closed position separating interior space of the data center from the exterior environment during normal mode of operation and an open position enabling free flow of outside air into the interior space during backup operation; exhaust louvers assuming a closed position separating interior space of the data center from the exterior environment and an open position enabling free flow of interior air out to the exterior environment; and controller configured to direct the intake louvers and exhaust louvers to assume the open position when electrical power supply to the active cooling system has been interrupted. The arrangement further includes a fluid system which functions as an open loop in the normal mode and a closed loop in the backup mode.

A fan system and a computing system with the fan system are disclosed. The fan system includes a fan module. The fan module includes a housing configured to retain a fan and a motor to rotate the fan. The housing includes an air inlet aperture on an air inlet side of the housing and an air outlet aperture on an air outlet side of the housing. The fan system further includes an outlet fan guard coupled to the fan module on the air outlet side of the housing. The outlet fan guard includes at least one flap rotatable between a closed position, covering the air outlet aperture of the housing, and an open position, uncovering the air outlet aperture of the housing. The outlet fan guard further includes at least one spring urging the at least one flap into the closed position.

A multi-device chassis air filter characterization system includes a multi-device chassis, an air filter that is included on the multi-device chassis, and a plurality of computing devices that are housed in the multi-device chassis. Each of the computing devices determines that a current time corresponds to a predetermined air filter characterization time period and, in response, operates a cooling system in that computing device at a predetermined cooling system operating level for the predetermined air filter characterization time period. A first computing device that is included in the plurality of computing devices measures an air filtering characteristic provided by the air filter during the predetermined air filter characterization time period and, based on the air filtering characteristic, determines whether to generate an air filter replacement alert.