Systems and apparatuses are provided in which outlets are coupled to a power distribution unit (PDU) or PDU module in various configurations. The outlets may be coupled to a recessed surface within a PDU housing. The outlets and recessed surface may be formed as part of a single mold. The outlets may be coupled to a printed circuit board that is at least partially disposed within the PDU housing. The outlets may extend away from the recessed surface or printed circuit board towards or beyond a front face of the PDU housing.

An electronic device is provided. The electronic device includes a display module, a fingerprint identification module, and a first circuit board. The display module includes a display screen, a second circuit board, and a first connecting portion. The display screen is electrically connected to the second circuit board, and the second circuit board is electrically connected to the first circuit board through the first connecting portion. The fingerprint identification module includes a fingerprint sensor, a fingerprint driving unit, and a second connecting portion. The fingerprint sensor is provided on the side of the display screen away from a display surface, the fingerprint sensor and the fingerprint driving unit are distributed at intervals, and the fingerprint sensor and the fingerprint driving unit are electrically connected to the first circuit board through the second connecting portion.

The disclosure is directed to a PMF-transceiver (1) comprising a housing (2) with a recess (5) in which a printed circuit board (6) is arranged. The printed circuit board (6) comprises at least one radiating element (7) being in a mounted position inter-connected to a thereto related PMF-cable (18) by a PMF-interposer (13) arranged 5 between the printed circuit board (6) and the PMF-cable (18) and comprising a main body (14) arranged in a cavity (17) in the housing (2). The PMF-interposer (13) extends between the radiating element (7) and the PMF-cable (19).

An electronic device and a wearable electronic device are provided in implementations of the disclosure. The electronic device includes a housing frame, a button assembly, and a circuit assembly. The housing frame has an inner cavity and a first through hole. The first through hole communicates with the inner cavity and an external space outside the housing frame. The button assembly includes a first conductive member and a second conductive member. The first conductive member is connected to the housing frame and at least partially in the external space. The second conductive member is at least partially in the first through hole. The first conductive member elastically abuts against the second conductive member, so that the first conductive member is in electrical communication with the second conductive member. The circuit assembly is disposed in the inner cavity.

A container data center is provided. The data center is provided in a shipping container, and the container data center includes a cooling system including a plurality of cooling devices for cooling the data center; a power supply and distribution system including a power supply circuit for supplying power to the data center; and a control system electrically connected to the cooling system and the power supply and distribution system; wherein the control system comprises a plurality of control devices, the plurality of control devices each configured to control a part of the cooling devices, and when a first part of the plurality of control devices cannot work, a working mode of a second part of the control devices is adjusted to control the plurality of the cooling devices.

A system for storing data includes a discrete cooling module that can enable discrete cooling of mass storage devices installed in the chassis interior of a data storage module coupled to a rack. The discrete cooling module includes an air moving device and an air cover. The air moving device can induce and airflow through the chassis interior of the data storage module to remove heat from heat producing components of mass storage devices installed in the chassis interior. The air cover directs the airflow through the chassis interior. The discrete cooling module can isolate rotational vibrations generated by the air moving device from the mass storage devices installed in the chassis. Partial isolation can include indirectly coupling the discrete cooling module to the chassis via directly coupling with the rack.

A latch assembly and an electronic device using the same are provided. The electronic device includes a chassis, a fan module, and the latch assembly. The chassis has a chassis sidewall and a fixing bolt fixed on the chassis sidewall. The fan module is adapted to be accommodated in the chassis. The latch assembly is mounted on a module sidewall of the fan module. The latch assembly includes a latch is pivotally connected to the module sidewall, a moving member movably disposed on the module sidewall and connected to the latch, and a rotating hook pivoted on the module sidewall and connected to the moving member. The rotating hook and the latch are respectively connected to opposite sides of the moving member. When the fan module is placed in the chassis, the rotating hook of the latch assembly is adapted to be hooked to the fixing bolt of the chassis.

A cooling case provides cooling of electronic cards. The cooling case provides efficient cooling of electronic cards found in military electronics packaging, and includes a cold plate having a fin structure.

A power convertor has a casing and a power conversion circuit arranged in an internal chamber of the casing. The casing has a first wall member as a specific side wall. A plurality of connector opening parts are formed in the first wall member. At least two of the plurality of connector opening parts formed in the first wall member are arranged at different positions facing a different direction from each other.

A stabilizing fixture to hold and stabilize a server contained within different sizes of server cabinets includes a base, a pressing component and an adjusting component. The pressing component is slidably coupled with the base in a first direction. A first pressing surface is defined on the pressing component for pressing a server. The adjusting component includes a screw and a nut. When the screw is rotated relative to the nut, the nut is driven to move in a second direction, and the nut acts on the pressing component to drive the pressing component in the first direction to press the server. As the pressing component moves along the first direction, the distance between the two pressing component changes to accommodate servers of different sizes.