An insertion tool for assisting in the insertion of an OCP 3.0 type expansion card in an expansion card slot of a computer system is disclosed. The expansion card may be a pull tab type form factor that does not have a mechanism such as an ejector latch to assist in applying force to insert the card. The expansion card has a front panel opposite a distal edge connector. The tool has a handle and a head coupled to the handle. The head has two contact areas that contact different areas of the front panel of the expansion card. For example, one of the contact areas may be an extended side arm and the other area may be a lateral rib extending from the head.

A system and method are directed to a fan board sled assembly comprising a fan circuit board including a first end and an opposing second end, a fan cage module including a front section for receiving and removably securing the first end of the fan circuit board to the fan cage module, and a guide bracket including a base section for receiving and removably securing the second end of the fan circuit board to the guide bracket. The fan cage module further includes a back section for receiving one or more fan bodies. The combined fan circuit board, fan cage module and guide bracket are a single integrated unit insertable and extractable from a chassis opening of a computer chassis.

An enclosure assembly for housing printed circuit boards and related electrical components having a secured faceplate that may be removed by use of a hand tool.

A computing device rack for housing a computing device. The rack comprises a frame to which a computing device is mountable, a retaining member mounted to the frame, and the retaining member having a latch that is movable relative to the frame, and an actuator movably coupled to the frame and the retaining member. Movement of the actuator relative to the frame and the retaining member from a first position to a second position deforms the retaining member to move the latch from an initial position to a final position relative to the frame, and thereby engages or disengages with the computing device that is mounted on the frame for locking or unlocking, respectively.

A tiered locking mechanism secures a component card to a printed circuit board and includes a base, a top slider structure, and a biasing element. The base includes a first-tier side wall and a coupling structure configured to engage the PCB. The top slider structure includes a second-tier side wall along with protrusions having a beveled edge. The top slider structure is slidable between locked and unlocked positions. The unlocked position includes the protrusions being displaced away from a component card engagement side relative to the locked position. A bottom one of the protrusions and the first-tier side wall form a first receiving slot in the locked position. Atop one of the plurality of protrusions and the second-tier wall form a second receiving slot. The biasing element is configured to urge the top slider structure toward the locked position and to compress as the top slider structure moves away from the component card engagement side.

The present disclosure discloses a node safe locking device and a server. An outer rail is disposed between two adjacent node modules. A middle rail is slidably assembled at the outer rail. Each middle rail is driven by one node module to translate in a same direction. When the middle rail moves, the linking and interlocking rod may be driven to reach different positions. When the middle rail moves outwards from the initial position together with one of the node modules, the locking guiding lean edge drives the linking and interlocking rod to move to the locking position. At this time, the blocking locking edge of the middle rail corresponding to the other node module is blocked by the linking and interlocking rod located at the locking position, and the node module may not move outwards to realize locking.

Electronic device such as a camera for a vehicle, including: a supporting frame, a main electronic substrate, provided with at least one electric or electronic component or circuit and coupled to the supporting frame; a secondary electronic substrate, provided with at least one electric or electronic component or circuit and coupled to the supporting frame; wherein the supporting frame has at least one main projecting tab and at least one secondary projecting tab, each capable to occupy a non-twisted position or a twisted position, wherein the main projecting tab, when in the twisted position, is providing an attachment of the main electronic substrate to the supporting frame, and wherein the secondary projecting tab, when in the twisted position, is providing an attachment of the secondary electronic substrate to the supporting frame.

Housing structure for PCI Express expansion electronic boards able to mechanically stabilize said PCI Express expansion electronic boards so as to guarantee the correct functioning, performance and integrity of the electric interconnection between them and the basic electronic board to which they are connected if there are mechanical stresses such as knocks or vibrations, in order to be able to use PCI Express expansion electronic boards in the automotive field, or in scenarios characterized by perturbations of the important mechanical type. The present invention also concerns an assembly method of the housing structure.

A circuit board is applied to be inserted an expansion card, the expansion card includes a positioning part. The circuit board includes a board body, a slot, a release structure and a transmission mechanism. The slot is disposed on the board body. The release structure is movably disposed beside the slot along a first direction, and includes a first inclined surface and a blocking portion for limiting the positioning part. The transmission mechanism includes a linkage part and a forcing part which are linked with each other. The linkage part is connected to the release structure. When the forcing part receives an external force, the linkage part moves to move the release structure to the first direction, and releases the limitation of the positioning part by the blocking portion.

A locking mechanism for a computing device controls movement of a removable module within a computer chassis. The locking mechanism comprises a lock pin, a head, and a spring stopper. The lock pin includes an elongated shaft and a head. The spring stopper is disposed on the elongated shaft. The spring is disposed about the elongated shaft such that the spring extends from the spring stopper toward an end of the elongated shaft. As the lock pin moves along a longitudinal axis of the elongated shaft from a first position to a second position, the spring is configured to compress between the spring stopper and a fixed bracket in the computer chassis. The opposite second end extends through a hole in the removable module, thereby preventing the removable module from being removed from the computer chassis.