An electronic assembly including motherboard, first slide rail, second slide rail, expansion card and engagement component. Motherboard includes main circuit board and first connector. First and second slide rails are fixed on main circuit board. First slide rail has first engagement hole. Expansion card includes expansion circuit board and second connector. Expansion circuit board is disposed on first and second slide rails and has first positioning recess. Second connector is plugged into first connector. Engagement component includes connecting portion, first movable end portion, second movable end portion, first protruding portion, and second protruding portion. First and second movable end portions are respectively connected to two opposite sides of connecting portion. First protruding portion protrudes from first movable end portion and is removably engaged with first positioning recess. Second protruding portion protrudes from second movable end portion and is removably engaged with first engagement hole.

An ejector device comprising a housing block; an ejector handle adapted to alternate between an open position and a closed position, having first and second rack engagement features, a sloped feature, and a notch; a trigger latch adapted to alternate between a latched position and an unlatched position, and having a sloped feature adapted to engage the sloped handle feature, and a hook adapted to engage the ejector handle notch; and an ejector button adapted to alternate between a pressed position and an unpressed position; wherein the housing block comprises a space for receiving the ejector handle and the latching trigger; the ejector handle is pivotally attached to the housing block and is adapted to urge the latching trigger to the unlatched position when the ejector handle moves to the closed position and the sloped handle feature engages with the sloped latching trigger feature; and the latching trigger is pivotally attached to the housing block, and is adapted to be urged to the unlatched position as the ejector button moves to the pressed position and impinges on the latching trigger.

A quick release connecting device includes an actuating retainer and a fixing member movably assembled to the actuating retainer. The fixing member includes a pivot portion and a pivot member movably mounted to the pivot portion; and the pivot member is coupled with a second object. The fixing member includes a limiting section and the pivot member includes a corresponding limiting section, such that the limiting section and the corresponding limiting section limit or stop each other at a specific location when the fixing member is moved or rotated. With these arrangements, the quick release connecting device can be applied to conveniently and repeatedly connect and separate a circuit board, a drawer, or a window to and from a corresponding rack, chassis, cabinet or window frame.

An electrical connector assembly includes an electrical connector and a CPU. The electrical connector includes an insulative housing defining a receiving cavity, and a plurality of contacts retained to the housing with corresponding contacting sections exposed in the receiving cavity. A first securing piece is attached upon the CPU, and a second securing piece is attached upon the housing. When the CPU is received within the receiving cavity, the first securing piece is locked with the second securing piece so as to have the CPU retained to the connector in position wherein the corresponding contacts of the electrical connector are mechanically and electrically connected to the corresponding contacting pads of the CPU in a compression manner reliably.

A fluid distribution system is incorporated into a server chassis. Connector plates have fluid connectors designed to connect with fluid cooling receptacles on server boards. A linkage system can be manually manipulated to translate the connector plates so as to engage the electronics boards and connect the fluid connectors to the receptacle. A pair of main connectors connect to the rack's fluid manifold to circulate cooling fluid to cool devices mounted onto the server boards. A locking mechanism can be included to mechanically lock the chassis to the rack to prevent accidental dismount of the chassis from the rack. Also, an anchor mechanism may be provided to apply counter force when engaging the connector plates with the server boards so as to prevent accidental dismount of the server board by the moving connector plate.

A controller for an e-machine of a turbomachine including a support structure, a printed circuit board, and a fastener arrangement that retains the printed circuit board on the support structure, the fastener arrangement including a resilient member that resiliently biases the printed circuit board towards the support structure.

A server information handling system is secured by a bezel that couples to an access location, such as an air vent at a front or rear face of a housing. The bezel includes a security structure having a lock and configured to couple directly at the front face or with a bezel extension at the rear face so that the server information handling system can use the same bezel with both a front face or rear face rack mount. The bezel has a lock integrated with the security structure, an air filter that fits over the security structure to filter air flowing into the housing, and a filter brace that captures the air filter by coupling to the security structure over the air filter. The filter brace attaches and detaches at the security structure when the security structure locks a server information handling system housing so that the air filter can be changed while the housing remains secure.

A system includes a computing system, a snap rivet, and a printed circuit board assembly (PCBA). The computing system includes a chassis. The snap rivet includes a rivet and a cap, and the cap is secured to the chassis. The PCBA includes a pin base. The pin base has a washer portion with a hole. The pin base is configured to receive the cap through the hole. The cap protrudes through the hole and mechanically engages the rivet to secure the PCBA to the chassis. The snap rivet provides for tool-less installation and removal of the PCBA from the chassis of the computing system.

A slot cover and an integrated circuit access device having the slot cover are provided. The slot is used to be removably inserted into a slot of an electronic device and includes a frame, a positioning portion, an engaging portion, and at least one conductive elastic plate. The frame includes a center sheet, a first-side sheet configured to connect to an integrated circuit access module, and a second-side sheet. The first-side sheet and the second-side sheet are respectively located at a first side and a second side of the center sheet. The positioning portion and the engaging portion are respectively located above and below the center sheet. The at least one conductive elastic plate is disposed at the second-side sheet. When the slot cover is inserted in the slot of the electronic device, the center sheet blocks an opening of the slot.

A securing apparatus configured to mount a data storage device in an enclosure includes a shielding assembly configured to be secured to a panel of the enclosure and a sliding pole. The shielding assembly includes a frame and a rotating plate rotatably mounted to the frame. The sliding pole is slidably mounted to the frame and defines a plurality of latching slots. The frame defines an aperture for the data storage device to pass through; the rotating plate comprises a plurality of hooks. The sliding pole is slidable relative to the frame to engage the hooks in the latching slots. The rotating plate is secured to the frame and shields the aperture, preventing the data storage device from being taken out of the enclosure.