An electronic device includes: a housing which has two side walls which are spaced apart from one another along an apposition direction and form an accommodation space between them; a printed circuit board which is insertable into the accommodating space of the housing along an insertion direction pointing transversely to the apposition direction and, in a mounting position, is accommodated in the accommodating space in a position perpendicular to the apposition direction and has a side edge extending along the insertion direction; and at least one attachment part which has at least one engagement receptacle by which the at least one attachment part is attachable to the side edge of the printed circuit board and, in an attached position, is connected to the printed circuit board.

A modular system for producing an electronic device includes: a housing, which forms an accommodating space; a printed circuit board which is insertable along an insertion direction into the accommodating space of the housing and, in a mounting position, is accommodated in the accommodating space; and a plurality of attachment parts, which are connectable to the printed circuit board and which, when viewed along the insertion direction, each have a division corresponding to a predetermined smallest dividing unit or an integral multiple of the predetermined smallest dividing unit. Each attachment part has a first guide device for guiding on a second guide device of the housing and a combination of attachment parts is connectable to the printed circuit board in a manner arranged next to one another along the insertion direction such that when the printed circuit board is inserted into the accommodating space, the combination is guided.

An electronic component module assembly includes a printed wiring board, and a stiffener assembly affixed to a first side of the printed wiring board. The stiffener assembly includes an outer stiffener secured to the printed wiring board, an inner stiffener removably located in an opening of the outer stiffener. The inner stiffener has one or more inner stiffener pockets formed therein, and one or more electronic components are installed in one or more inner stiffener pockets, and electrically connected to the printed wiring board.

A pull-out aiding device is configured for mounting on an object, in which a corresponding apparatus is mounted. The pull-out aiding device includes a pulling member and a handle member. The pulling member includes a first pivot section and an abutting section for abutting against the corresponding apparatus to move the latter forward. The handle member includes a second pivot section and an operating section. The second pivot section is pivotally connected to the first pivot section, such that the handle member is turnable about the second pivot section relative to the pulling member and brings the latter to move forward.

A circuit board separation mechanism may include a separation block positioned within a separation block cut-out of a heatsink. The heatsink may be positioned between a first circuit board including a first component of at least one connector and a second circuit board including a second component of the at least one connector. The circuit board separation mechanism may include a set screw inserted in the separation block. A portion of the set screw may be configured to engage a surface of the heatsink. The separation block may be configured to lift against a surface of the first circuit board when the set screw is rotated. The first component of the at least one connector and the second component of the at least one connector may be configured to separate when the set screw is rotated and the separation block lifts against the surface of the first circuit board.

In one embodiment, an apparatus is provided. The apparatus includes a printed circuit board. The apparatus also includes a first connector coupled to the printed circuit board. The first connector is configured to couple the apparatus to a computing device. The apparatus further includes a second connector coupled to the printed circuit board. The second connector is configured to couple the apparatus to a data storage device. The apparatus further includes a securement mechanism comprising a first portion and a second portion. The securement mechanism is movable about the apparatus between a first position and a second position. The first portion is configured to maintain the securement mechanism at the first position. The second portion is configured to secure the data storage device to the apparatus when the securement mechanism is in the first position.

Ruggedized avionics assemblies for use on kinetically launched space vehicles are disclosed. The avionic assemblies are able to maintain structural integrity and functionality under high acceleration forces generated during kinetic launch, including acceleration forces of >5,000 times Earth's gravity in a single direction of loading. The avionics assembly is ruggedized to withstand this level of acceleration force during launch via a plurality of constraining elements to constrain a plurality of printed circuit boards aligned in parallel to an acceleration vector. Further, a high specific strength and stiffness composition of the plurality of constraining elements aids in supporting the printed circuit boards and preventing them from bending and dislodging electronic components mounted to the printed circuit boards.

Embodiments for electronic device fasteners that enable an electronic device to be reliably and quickly secured on a host board are presented. In one exemplary embodiment, a fastening assembly includes a glider component that supports an electronic device such as an M.2 solid state drive, and slides on tracks installed on a host board to bring a handle bar in a locking position above the electronic device securing the electronic device in place. The glider component and the tracks are designed with sloped surfaces such that as the glider component slides over the tracks, when it reaches an end of the track, a stable engagement secures the electronic device in place without the need for any additional fastening mechanisms.

A resource circuit board is configured for use by a physical migration system, the resource circuit board including at least one common interface shaped and configured to connect to an interconnect of a base circuit board; and at least one migration-support interface the at least one common interface being different from the at least one migration-support interface, the at least one migration-support interface: shaped to connect to at least one corresponding migration-support interface of the physical migration system; and configured to provide at least one of power and connectivity to the resource circuit board during a physical migration of the resource circuit board.

A case module that is capable of installing a first electronic module and a second electronic module, includes a cage and a restraining component. The first electronic module can move relative to the cage to a first installation position along a first direction. The second electronic module can move relative to the cage to a second installation position along a second direction perpendicular to the first direction. When the first electronic module moves relative to the cage toward the first installation position along the first direction, the restraining component is driven to move relative to the cage toward a restraining position along the first direction. The second electronic module can be stopped by the restraining component when the restraining component is located at the restraining position.