In accordance with some embodiments, an apparatus that controls device re-configuration for security is provided. The apparatus includes a storage storing a first firmware image for a re-configurable data communication device. In some embodiments, the first firmware image provides one or more operating parameter configurations for the re-configurable data communication device. The apparatus also includes a controller, which is coupled to the storage and the re-configurable data communication device and operable to manage transport of data by the re-configurable data communication device, including obtaining the first firmware image from the storage and loading the first firmware image to the re-configurable data communication device. The apparatus additionally includes a housing at least partially supporting the storage and the controller.

A component-level cooling system for cooling components in a chassis includes a fan in a housing positioned on a circuit board. The housing has a fan inlet on a side, a first fan outlet on one end and a second fan outlet on a second end opposite the first end. The first fan outlet may direct a first airflow in a first direction to a vent on a first panel of the chassis. The second fan outlet may direct a second airflow in a second direction opposite the first direction. A duct comprises a duct inlet for receiving the second airflow, an elbow for redirecting the second airflow in a third direction to avoid the second airflow from colliding with a main airflow to reduce acoustic noise, and a duct outlet located to avoid heated air exiting the duct from re-entering the fan inlet.

An apparatus may include a chassis that can receive a sled and a locking mechanism. The locking mechanism can mechanically lock the sled to the chassis to prevent a sudden power loss that can be caused from an unexpected removal of the sled from the chassis. To avoid a sudden power loss, a voltage-sensing electrical switch lock can be implemented to the chassis to mechanically lock the sled to the chassis until the sled is ready to be removed. The sled may include one or more computing devices that need to be inactive before removing the sled. The apparatus includes a controller that may detect whether at least one of computing devices in the sled are in an active state or in an inactive state. Based on the determination of the state of the computing devices in the sled, the controller may activate the locking mechanism or de-active locking mechanism.

An electronic device can include first and second housing components and an electrical grounding feature located therebetween to provide a grounding path. The grounding feature can include an outer portion formed from an electrically conductive material and an internal region containing a removable expansion element. The grounding feature can exert an expansion force against the housing components when the device is assembled and the expansion element remains, and exert no expansion force against the housing components when the expansion element is removed. The device can also include an adhesive coupling the electrical grounding feature to the housing components, which adhesive can be electrically conductive. The expansion element can be deformable and removable from an open end of the grounding feature outer portion, which outer portion can be elastic and can deform to contact more of the housing components when the grounding feature is compressed therebetween.

A thermal management device with electromagnetic (EM) shielding includes a fin pack with a plurality of channels. The fin pack has an upper and lower surface. The fin pack has a pack length, pack height, and pack width. The fin pack has fins are oriented connecting the upper surface to the lower surface. The plurality of channels extends from a first end toward a second end. A first channel of the plurality of channels is adjacent the upper surface, and a second channel of the plurality of channels is adjacent the lower surface.

Provided herein is an apparatus including circuitry as well as membrane that is configured to pass air, to remove heat from the circuitry, and to prevent the circuitry from being exposed to moisture. The membrane is additionally includes pores.

An electronic apparatus includes a cylindrical housing, a first functional member, a second functional member, and a heat dissipation assembly. The cylindrical housing includes an air inlet structure and an air outlet structure. The first functional member and the second functional member are arranged in the cylindrical housing. The first functional member and the second functional member are alternately arranged. The heat dissipation assembly is arranged in the cylindrical housing. The first functional member and the second functional member are thermally connected to two heat transfer contact surfaces of the heat dissipation assembly, respectively. The heat dissipation assembly is configured to perform heat dissipation processing on the first functional member and the second functional member.

Example computing devices are disclosed herein that include a housing member that is to be placed on a support surface. The housing member includes an internal cavity and a biasing member mounted within the internal cavity. The biasing member is to engage with an inner surface of the internal cavity to deform the inner surface.

A modular mounting for a computer motherboard. An outer cabinet is designed to provide a protective enclosure for electrical components, and designed to permit throughhole drilling to facilitate mounting on a wall while avoiding disturbance of contents to be mounted within the outer cabinet. A subpanel plate is designed to detachably and securely attach a computer motherboard and cage assembly, and designed to removably mount the motherboard and cage assembly within the outer cabinet as a modular component, mounting of the motherboard and cage assembly being independent of power supply and nonvolatile storage. An inner cage is designed to protectably mount and enclose a computer motherboard and heat sink, and mount to the subpanel plate. A multipole switch may have a set of contacts for each conductor of a network cable entering the outer cabinet, one throw of the switch connecting all conductors of the cable, another throw of the switch disconnecting all contacts of the cable.

Examples herein relate to intrusion switch. In particular, implementations herein relate to a computer system including a housing enclosing at least one electronic component therein. The housing includes a base and a removable cover. The cover is movable between engaged and disengaged positions relative to the base and extends over at least a portion of the base and is secured to the base in the engaged position. The cover is removable from the base when the cover is in the disengaged position. The computer system further includes an intrusion switch configured to detect access to an interior of the computer system. A portion of the cover extends through a slot in one of the sidewalls of the base and contacts the intrusion switch when the cover is in the engaged position. Contact between the cover and the intrusion switch is released when the cover is in the disengaged position such that the intrusion switch can detect when the cover is moved to the disengaged position.