A hard disk supporting structure is provided. The hard disk supporting structure includes a hard disk rack, a crawler mechanism, and a motor. The hard disk rack is for disposing at least one hard disk. A crawler of the crawler mechanism is fixedly connected with the hard disk rack. The motor is connected to a driving gear of the crawler mechanism. The motor drives the rotation of the driving gear, to enable the crawler to drive the hard disk rack to move back and forth. The hard disk supporting structure can automatically move the hard disk rack back and forth through a structure with automatic telescopic function, which greatly saves labor, and improves efficiency.

A server apparatus includes a casing having a first engaging structure, a tray mechanism including a tray, a handle and an elastic member, and a server module disposed on the tray. The handle is pivoted to the tray. The elastic member connected to the tray and has an interfering structure. The interfering structure interferes with the handle to position the handle for making the handle not interfere with the first engaging structure when the tray is inserted into the casing along an insertion direction.

A control cabinet for at least one electrical drive controller includes a control cabinet housing a first cabinet compartment formed in the control cabinet housing and having at least one inlet opening for fresh air, at least one first transfer opening and a fresh air duct flow-connecting the inlet opening to the first transfer opening. A second cabinet compartment is formed in the control cabinet housing and has at least one outlet opening for exhaust air, at least one second transfer opening, and an exhaust air duct flow-connecting the outlet opening to the second transfer opening. A third cabinet compartment is formed in the control cabinet housing and is sealed off in terms of flow from the first cabinet compartment, the second cabinet compartment, and the environment outside the control cabinet. A partition delimits the third cabinet compartment in terms of flow from the first cabinet compartment and the second cabinet compartment, and has the at least one first transfer opening and the at least one second transfer opening. The third cabinet compartment is in the form of a rack with at least one drawer, wherein each drawer is designed to receive an insertable control device.

A cable management system for an enclosed chamber includes a fixed member which has attachment formations associated therewith for attachment to the enclosed chamber and a displaceable member which is displaceable relative to the fixed member between at least an extended condition and a retracted condition and which has cable fixing formations. The cable management system includes a guide mechanism for guiding the relative displacement of the displaceable member relative to the fixed member, wherein the cable fixing formations are configured to fix at least one cable at a first point to the displaceable member, such that displacement of the displaceable member causes the cable to be displaced therewith. The cable management system may also form part of a cable management assembly which includes an enclosed chamber to which the fixed member is attached or attachable.

An electronic module, such as a power module, may include a latch having two or more protrusions where a first protrusion can fix the electronic module into a shelf and the second protrusion can be a curved protrusion that activates the latch when an adjacent electronic module is inserted into or removed from the shelf. In some embodiments, a third protrusion may be included, where the first protrusion and the third protrusion both fix the electronic module to the shelf and are activated by the latch. Also, a shelf may include a partition between two electronic module receptacles that has a width that is less than a protrusion extending from a side wall of one of the electronic modules.

An adaptor for incorporating a function of an Open Compute Project (OCP) mezzanine card into a storage device includes a framework, a baseboard mounted to the framework and arranged to have the Open Compute Project (OCP) mezzanine card mounted thereon, an adapting part on the baseboard, the adapting part including an insertion slot for receiving a first interface of the OCP mezzanine card, and a connector on the baseboard, the connector configured to connect with the storage device, the baseboard including interconnections between the connector and the adapting part to provide for data exchange between the OCP mezzanine card and the storage device.

A locking mechanism for applying in a computer case is disclosed. The locking mechanism comprises: an actuating unit and a locking member. The actuating unit is pivotally connected to one of two vertically-disposed side plates of the computer case by one end thereof, and comprises a pivot member and a latching member. In the present invention, the actuating unit rotates along a first direction parallel to the vertically-disposed side plate, so as to decrease space required by operating the locking mechanism. Such that the locking mechanism brought advantages of great space-saving, high capacity and low cost of production cost.

An apparatus includes: a 1 U drive chassis divided into a plurality of compartments by a partition, the plurality of compartments including an interior compartment; an interior cage installed in the interior compartment, the interior cage including a plurality of pockets into which storage media are mounted when in use and having a back edge; a hinge by which the interior cage is rotatably mounted to the 1 U drive chassis along the back edge of the interior cage; a lift to rotate the interior cage at least partially to an open position when the first latch is released; and a latch to maintain the interior cage in a closed position and to maintain the interior cage in the opened position according to the rotation of the interior compartment.

An electronic device includes a housing, a first electronic component, a second electronic component, two resilient assemblies, and two rotating levers. The housing defines an accommodating space. The second electronic component is fixed in the accommodating space. Each rotating lever includes a first end and a second end. A distance between the second end and a rotation shaft is less than a distance between the first end and the rotation shaft. A handle is rotationally fixed on the first electronic component. When the first electronic component slides into the accommodating space, the handle is rotated toward the first electronic component, the handle drives the two rotating levers to rotate and resist against the resilient assemblies, and the handle overcomes an elastic force applied by the resilient assemblies onto the rotating levers, so that the first electronic component connects with the second electronic component without gaps.

A system includes a chassis and a top cover assembly. The top cover assembly is coupled to the chassis. The top cover assembly includes a first lid, a second lid, a middle cover between the first lid and the second lid, and a hinge coupling together the first lid, the second lid, and the middle cover.