An electronic apparatus and heat dissipation and EMI shielding structure thereof are provided. The electronic apparatus includes a substrate, at least one chip disposed on the substrate, and the heat dissipation and EMI shielding structure. The heat dissipation and EMI shielding structure covers the chip and includes a shielding frame and a heat dissipation element. The shielding frame has an opening to expose the chip, and the heat dissipation element is disposed on the shielding frame and covers the opening. The conjunction of the shielding frame and the heat dissipation element can protect the chip from being interfered with electromagnetic waves, and the heat generated by the chip can be dissipated by the heat dissipation element.

Example embodiments relate to a shield for an electronic device. The shield may be shaped to enclose the electronic device. The shield may include a number of traces. Each trace may include an electrically conductive inner portion and an electrically non-conductive outer portion.

A split enclosure apparatus for fan-less cooling may be provided. The apparatus may comprise a device and a housing. The device may comprise a plurality of components. The housing may enclose the device and may comprise a first external surface, a second external surface, and a joint between the first external surface and the second external surface. The first external surface may be dedicated to cooling a first one of the plurality of components. The second external surface may be dedicated to cooling a second one of the plurality of components. The joint between the first external surface and the second external surface may be electrically conductive and thermally resistive.

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.

A mobile electronic device includes: a housing; an acoustic-component contained in the housing; a sound hole formed in the housing, the sound hole being configured to allow communication between an inside and an outside of the housing; a non-breathable waterproof film disposed inside the housing, the waterproof film being configured to cover the sound hole; a compressible member compressed by being pressed against the housing during assembly of the acoustic-component to the housing, the compressible member being configured to form an acoustic-component chamber together with at least the waterproof film, the acoustic-component chamber being configured to hermetically seal the acoustic-component; and an opening configured to allow communication between an inside and an outside of the acoustic-component chamber within the housing, the opening being configured to allow air in the acoustic-component chamber to escape to the outside before the opening is closed in the process of compressing the compressible member.

Examples relate to adjusting load power consumption based on a power option agreement. A computing system may receive power option data that is based on a power option agreement and specify minimum power thresholds associated with time intervals. The computing system may determine a performance strategy for a load (e.g., set of computing systems) based on a combination of the power option data and one or more monitored conditions. The performance strategy may specify a power consumption target for the load for each time interval such that each power consumption target is equal to or greater than the minimum power threshold associated with each time interval. The computing system may provide instructions the set of computing systems to perform one or more computational operations based on the performance strategy.

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 semiconductor die comprises a first active device, at least one of a second active device and a passive component, and electromagnetic shielding configured to at least partially electromagnetically isolate the first active device from the at least one of the second active device and the passive component. The electromagnetic shielding includes one of a grounded metal layer and via stack, and a grounded metal layer disposed one of above and below the first active device.

A wall mount includes a wall attachment assembly with spaced apart top and bottom rails. A pair of display mount assemblies hang from the wall attachment assembly and attach to a television or other electronic display such as a computer monitor. The display mount brackets include an engaging assembly, a display mount member, a scissors assembly, and a carrier assembly. The engaging assembly has hooks and a swivel guide engaged with the top rail of the wall attachment assembly, and a latch assembly engaged with the bottom rail of the wall attachment assembly. The swivel guide and a contact portion of the latch assembly enable the display mount assemblies to swivel or pivot about a vertical axis relative to the wall attachment assembly. This enables an attached television or monitor to be laterally swiveled relative to the wall.

A camera integrates a magnet at one end of a housing to magnetically attract and attach the camera to a front side of a peripheral display, such as to support a video conference through an information handling system interfaced with the display. Camera position at a display panel front face is maintained by magnetic attraction to a ferromagnetic material backplate having crossbeams to strengthen the backplate construction and sized so that a substantially equal magnetic attraction is provided for the camera magnet across plural adjacent crossbeams.