A component carrier includes a baseboard, two sidewalls, and an ejector. The two sidewalls extend from opposite sides of the baseboard. The ejector includes a side plate, a handle, and a tab. The side plate is positioned in proximity to a first sidewall of the two sidewalls of the component carrier. The handle extends from a first end of the side plate in a first direction that is generally perpendicular to the side plate. The tab is positioned in proximity to the baseboard, and extends from a second opposing end of the side plate in a second direction that is generally perpendicular to the side plate and opposite to the first direction, the tab coupled to a first connector extending from the baseboard. The baseboard includes a first opening such that a portion of the tab of the ejector is configured to directly contact the electronic component therethrough.

A server includes a printed circuit board (PCB), an electronic component connected to the printed circuit board, and a chassis connected to the PCB. The chassis includes a first end with a first aperture configured to allow airflow into the server, a second end with a second aperture configured to allow the airflow out of the server after having passed across the electronic component, and a temporary bulkhead that is movable between a deployed position and a stowed position, wherein in the deployed position, the temporary bulkhead is connected to the PCB and extends across the server in a path of the airflow, and wherein in the stowed position, the temporary bulkhead is disconnected from the PCB and is positioned to open the path of the airflow.

Methods and systems for thermal management of hardware resources are disclosed. To improve the likelihood of the computer implemented services being provided, the systems may include information transmission topologies that are more likely to properly transmit operating point information (e.g., actual fan rates, rates at which fans are to operate, etc.) between management entities such as thermal managers and entities managed by the thermal managers such as fans (and/or other types of gas flow control components). By doing so, the system may be more likely to provide thermal management services as intended by using the transmitted information that is more likely to be accurate.

A server includes a printed circuit board (PCB), an electronic component connected to the PCB, and a chassis connected to the PCB. The chassis includes a first end with a first aperture configured to allow airflow into the server, a second end with a second aperture configured to allow the airflow out of the server after having passed across the electronic component, and a movable bulkhead comprising a first set of louvers, the movable bulkhead being movable between a closed position and an opened position, wherein each of the louvers includes a leading edge contact feature configured to interface with a trailing edge of a respective adjacent louver. In the closed position, the first set of louvers forms a wall in a primary path of the airflow, and, in the opened position, the first set of louvers are oriented in a direction of the primary path of the airflow.

A graphics subsystem includes a printed circuit board (PCB), a set of one or more fans, and a heat sink. A graphics processing unit (GPU) is integrated into the PCB. The PCB is shortened to occupy a portion of the width of the graphics subsystem. The heat sink is coupled to the PCB and/or GPU and configured to extend beyond an edge of the PCB, thereby occupying a larger portion of the width of the graphics subsystem compared to the PCB. A first fan is disposed partially or fully beyond the edge of the PCB and is configured to direct air through the portion of the heat sink that extends beyond the edge of the PCB, along a first airflow path, and out of the graphics subsystem. A second fan is configured to direct air through the heat sink, along a second airflow path, towards the GPU.

A system includes an enclosure having an air inlet end and an air outlet end, air movers positioned near the air outlet end, a first data connector positioned near the air outlet end between the air movers, a heat-generating electrical component positioned immediately between the data connector and the air inlet end, a first heat sink positioned immediately between at least one of the air movers and the air inlet end, and a first conductive pipe thermally coupled between the heat-generating electrical component and the first heat sink.

An information handling system may include a chassis having a first region and a second region, wherein the first region includes a memory module, and wherein the second region includes a processing unit; at least one air mover configured to provide airflow; and an airflow shroud including an airflow baffle. When the airflow shroud is installed in the information handling system in a first orientation, the airflow baffle may be configured to block at least a portion of the airflow from flowing through the first region. When the airflow shroud is installed in the information handling system in a second orientation, the airflow baffle may be configured to block at least a portion of the airflow from flowing through the second region.

A networking hardware system includes a housing; a board located in the housing and comprising a plurality of components; a liquid cooled heat exchanger; and one or more fans disposed near the liquid cooled heat exchanger and configured to provide cool airflow from the liquid cooled heat exchanger to any of the plurality of components. The housing can be substantially sealed from an external environment and includes no air intake thereon, removing a need for higher powered fans and for air filtering for dust. The housing can include a faceplate with no air intake thereon, providing increased density for ports on the faceplate.

A thermal ducting rail receives a rack device in a rack chassis. The thermal ducting rail includes air flow guiding elements that enable cooling air from a front face of the rack chassis to be directed to an external side of the thermal ducting rail and from the external side to a rear face of the rack chassis. The thermal ducting rail enables rack devices equipped with side-to-side cooling to receive cooling air in a rack chassis with front-to-back cooling, without extending beyond a unit height occupied by the rack device.

Embodiments herein describe a cooling system for a plurality of arrayed components arranged in a first bank and a second bank, the first bank being disposed upstream of the second bank along an airflow path. The system comprises a first wall configured to be positioned above the first bank and the second bank. The first wall defines an angled cavity such that a height of the angled cavity decreases from the front end of the angled cavity to a region between the front end and the back end of the angled cavity. The first wall defines the angled cavity such that a distance between the first wall and the first bank is greater than a distance between the first wall and the second bank. The first wall forms a top portion of the airflow path.