Various embodiments of the present technology provide systems and methods for mounting and dismounting a computing component (e.g., a HDD) of a server system. The server system contains one or more drawers, each of which can host a plurality of computing components. A computing component can have a side surface attached to a lever via a hinge. When the computing component is placed into a designated location of a drawer, pressing a first end of the lever in one direction can cause a second end of the lever to interact with at least one portion of the drawer and further cause the computing component to move into a close position or out of the close position.

A system and method for heat dissipation and vibration damping of electronic devices in which an assembly is formed by one or more surfaces comprised of thermally conductive plastic that combine to partially or completely enclose one or more electronic devices as a physical and thermal intermediary between the electronic devices and supporting structures.

A carrier device includes a base bracket, a device bracket, a lever, and a cable holder. The device bracket is coupled to the base bracket and is movable between an initial device bracket position and a final device bracket position. The lever is coupled to the base bracket and is movable between an initial lever position and a final lever position. The lever is configured to move from the initial lever position toward the final lever position in response to the device bracket moving from the initial device bracket position to the final device bracket position. The cable holder is coupled to the base bracket and the lever. The cable holder is configured to hold one or more cables. The cable holder is further configured to move from an initial cable holder position to a final cable holder position, in response to the lever moving to the final lever position.

A solid state drive (SSD) housing assembly includes an SSD housing and an extension frame. The SSD housing includes a first extension joint and a first mounting joint. The first mounting joint is a mechanism by which the housing can be mounted to an external device. The SSD housing has the form of a rectangular case in which an SSD module is held. The extension frame includes a second extension joint and a second mounting joint. The second mounting joint is a mechanism by which the frame can be mounted to the external device. The extension frame is attachable to and detachable from the SSD housing by virtue of the first extension joint and the second extension joint.

An electronic device includes a chassis defining an opening. A motherboard is received in the chassis and a data storage device comprising a circuit board with storage unit can be directly coupled to the motherboard. The data storage device is mounted to the chassis through the opening but is detachable.

A docking system for facilitating a connection of an electronics module to a mating connector comprises first and second rails. Each rail has an elongated guide slot for receiving a corresponding guide portion of the electronics module during sliding movement of the electronics module toward the mating connector. A first elastic structure is located on the first rail. The first elastic structure has a first engagement portion extending into the elongated guide slot of the first rail. A second elastic structure is located on the second rail. The second elastic structure has a second engagement portion extending into the elongated guide slot of the second rail. The first engagement portion and the second engagement portion are configured to engage the guide portions of the electronics module and to resist movement of the guide portions in a direction generally perpendicular to the sliding movement of the electronics module.

A server disk drive holder assembly includes an outer tray, an inner tray and a latch arm. The outer tray includes a locking hole. The inner tray overlaps on the outer tray. The inner tray is movable with respect to the outer tray. The inner tray includes a fastening hole. A latch arm is pivotally disposed on an outer side of the outer tray. The latch arm includes a hook portion. When the locking hole is aligned with the fastening hole, the hook portion is inserted through the locking hole to be engaged with the fastening hole. A disk drive can be clamped between the outer tray and the inner tray. By utilizing the movable latch arm to fasten the outer tray and the inner tray, the disk drive can be quickly mounted and dismounted.

A hard drive carrier and a method for removing a hard drive carrier from an enclosure are provided herein. In one example, the hard drive carrier includes a platform located in a center position on a front face of the hard drive carrier. The hard drive carrier includes a first pinch point and a second pinch point, where the second pinch point is located opposite of the first pinch point. The hard drive carrier also includes a first tab disposed adjacent to the first pinch point and a second tab, where the second tab is located opposite of the first tab.

The invention provides a Storage Bridge Bay system, comprising: plural hard disk drives, each arranged within a corresponding slot; one or more Storage Bridge Bay canisters, wherein there is provided in the or each canister one or more solid state drives. In addition in an embodiment, the invention provides a Storage Bridge Bay canister, the canister comprising: electrical connections in accordance with the Storage Bridge Bay standard; and, one or more solid state drives arranged within the canister and arranged in communication with the electrical connections, thereby enabling control of and transfer of data to or from the solid state drives via the electrical connections.

A backplane configured to receive electrical components is provided. The backplane in one example includes a substrate comprising an at least partially flexible material, a plurality of backplane traces formed as part of the substrate, at least one connector island formed in the substrate, with the at least one connector island located in an opening in the substrate and configured to receive at least one mating electrical component, and one or more spring elements bridging between the at least one connector island and the substrate, with traces of the plurality of backplane traces extending over the one or more spring elements to the at least one connector island and with the one or more spring elements allowing the at least one connector island to flex with respect to the substrate and absorb vibrations.