An information handling resource blank configured to populate a slot of an information handling system in lieu of an information handling resource may include a form factor having at least some features in common with that of the information handling resource and one or more false fans mechanically coupled to the form factor. Each of the one or more false fans may be configured to have a first airflow impedance when airflow through such false fan is below a threshold airflow and have a second airflow impedance when airflow through such false fan is above the threshold airflow.

A scalable graphics card assembly support system for a desktop chassis comprises an end support for coupling to an end of a graphics card assembly and a side support for coupling to a side of the card assembly. The side support can be coupled to any of several positions in a retention guide and the end support may couple to the card assembly or an extension coupled to the graphics card assembly, allowing the graphics card assembly support system to support graphic card assemblies of different lengths, widths and thicknesses. The graphics card assembly support system couples to one or more selected points within the chassis such that a chassis panel can be easily removed for servicing the information handling system. Cable parking connectors and conduit couplers provide better cable and conduit management for a more aesthetically pleasing appearance of an information handling system in the chassis.

In one or more embodiments, an information handling system fan may include: a hub; multiple fan blades radially attached to the hub and configured to rotate perpendicularly to a longitudinal axis of the information handling system fan; an electric motor; a drive shaft parallel to the longitudinal axis of the information handling system fan that attaches the electric motor to the hub; and a housing that houses the hub, the multiple fan blades, and the electric motor. In one or more embodiments, the housing may have a concave portion perpendicular to the longitudinal axis of the information handling system fan, in which the housing may include a first vent in the concave portion of the housing to intake air as the multiple fan blades rotate and in which the housing may include a second vent configured to exhaust the air as the multiple fan blades rotate.

A fan carrier system, including a fan carrier, including: a fan apparatus having i) a first end positioned opposite to a second end, and ii) a first side positioned opposite to a second side, the first and the second side extending between the first end and the second end; a first piston coupled to the fan apparatus, the first piston positioned along the first side, the first piston translatable between the first end and the second end; a connection assembly coupled to a first end of the first piston, the connection assembly including a first connector; a handle assembly, including: a first arm coupled to the first piston via a first handle pin, the first arm further including a first carrier pin; a handle coupled to the first arm; a chassis, including: a first wall and a second wall each including a respective slot.

Methods, apparatus, systems, and articles of manufacture are disclosed to monitor thermal degradation of a compute device. One such method includes calculating, by executing instructions with processor circuitry, a thermal degradation value based on an equation, the equation generated based on testing of thermal interface materials having varying degrees of degradation. The method also includes comparing, by executing instructions with the processor circuitry, the thermal degradation value to a thermal degradation threshold to determine whether the thermal degradation threshold is satisfied, and, when the thermal degradation threshold is satisfied, triggering generation of a thermal degradation alert.

A charger may include: a casing including an air inlet and an air outlet; an inner wall extending from an inner surface of the casing and defining an accommodating space between the inner surface of the casing and the inner wall; and a centrifugal fan including an air feed port and disposed in the accommodating space. The air outlet may be disposed to face the air feed port. The air inlet may be disposed closer to the centrifugal fan than the inner wall is. In a direction of a rotation axis of the centrifugal fan, a width between the inner wall and the centrifugal fan may be less than or equal to 150% of a width of the centrifugal fan.

An air flow generating device includes an enclosing wall, a frame sheet, a cover film, and a vibrating part. The frame sheet is disposed inside an air flow passage formed by the enclosing wall and closely contacts the air flow passage by its periphery. The cover film includes a central connection portion fixed to a central portion of the frame sheet, and a plurality of movable cover portions connected to the central connection portion. The cover film is between the frame sheet and an outlet of the air flow passage. The movable cover portions selectively cover a plurality of through holes of the frame sheet. The vibrating part is fixed on the frame sheet. When the vibrating part vibrates, the central portion and the central connection portion move together with the vibrating part so that the movable cover portions seal the through holes or move relative to the through holes.

A charger is provided with an intake hole through which outside air may flow into the interior of and through the body of the charger, and an exhaust hole from which the outside air is discharged through by the driving a cooling fan. A first vertical wall that surrounds the intake hole or a region exposed to water that drops down the intake hole in a fence-shaped manner, and a second vertical wall that surrounds the exhaust hole or a region exposed to water that drops down the exhaust hole in a fence-shaped manner are provided on a bottom plate of the housing. An electrical circuit board is disposed outward of an area where the first vertical wall surrounds the intake hole and also disposed outward of an area where the second vertical wall surrounds the region exposed to water that drops down the exhaust hole etc.

A heat dissipation assembly can be applied to the electronic device. By providing a heat dissipation fan and a temperature sensor for the heat dissipation assembly, and arranging the heat dissipation assembly in an accommodation space defined by a processor cover plate and a control mainboard, the heat dissipation fan can improve a heat dissipation effect on the processor by utilizing air flow generated by the heat dissipation fan in the accommodation space in cooperation with heat dissipation openings in the processor cover plate.

A modular data center (MDC) includes a volumetric container comprising an enclosure having first and second exterior walls at a forward and an aft end, connected by lateral exterior walls. Information technology component(s) are positioned longitudinally within the container between a cold aisle and a hot aisle. An air handling system includes two or more air handling units (AHUs) each having a return air inlet and a supply air outlet. A supply air plenum directs cooling air flow from the supply air outlets to a supply air opening positioned adjacent to the cold aisle. Backflow prevention mechanisms are positioned respectively at each supply air outlet of the AHUs. Each backflow prevention mechanism is moveable into an open position to allow cooling air flow out of the supply air outlet of a corresponding AHU and a closed position in response to deactivation of an air mover of the corresponding AHU.