A small-volume push-push apparatus for mounting and demounting a hard disk includes a pressing member, a bracket, and an elastic rod. The bracket defines first to fourth sliding slots, and the elastic rod includes a sliding portion. The pressing member can drive the sliding portion to slide along the first to fourth sliding slots in sequence. When the sliding portion slides to an ending point of the first sliding slot and intersects with the second sliding slot, the bracket can move at a first direction. When the sliding portion slides to a starting point of the first sliding slot away from the fourth sliding slot, the bracket can move in a second direction opposite to the first direction.

A disk device includes a housing that includes a base with a through hole formed therein and a cover fixed to the base, wherein the housing contains a low density gas; a plurality of heads and a wiring member disposed within the housing that includes conductors that are electrically connected to the heads; a sealing substrate that is fixed to the base and covers the through hole; a control circuit board that is disposed outside the housing and adjacent to a back surface of the base; a first two-piece connector that is disposed within the housing and connects the sealing substrate and the wiring member; and a second two-piece connector that connects the sealing substrate and the control circuit board. The second two-piece connector includes a first connector mounted on the sealing substrate and a second connector that is mounted on the control circuit board.

A computing device is provided with a drive slot with a connector for engaging a corresponding connector of a HDD, and a first locking element. The computing device includes a removable a HDD carrier for insertion into the drive slot having a bracket, a handle and an enclosure slidably attached to the bracket for securing the HDD. The handle includes a second locking element extending therefrom and configured to receive the first locking element to restrict the removable HDD carrier to vertical motion. The first locking element engages with the second locking element when the handle is in the loading position and the bracket moves relative to the enclosure to secure the hard disk drive in the bracket and connect the connector of a hard disk drive to the connector located at the drive slot when the handle transitions from the loading position to the locked position.

A fastening structure including a base pillar, a pair of elastic arms, and a top pillar is provided. The base pillar is assembled to an object, the elastic arms are connected between the top and the base pillars, and a gap is provided between the elastic arms. The top pillar is adapted to stretch or compress the elastic arms when an external force is exerted to reduce or expand the gap. The top pillar and the elastic arms pass through a through hole of a connector when the elastic arms are stretched to reduce the gap to make the connector contact the base pillar. After the force is removed, the gap between the elastic arms is restored to fasten the fastening structure between the elastic arms and the base pillar in a floating state. An electronic assembly and an operating method of the fastening structure are also provided.

A fastening structure including a base pillar, a pair of elastic arms, and a top pillar is provided. The base pillar is assembled to an object, the elastic arms are connected between the top and the base pillars, and a gap is provided between the elastic arms. The top pillar is adapted to stretch or compress the elastic arms when an external force is exerted to reduce or expand the gap. The top pillar and the elastic arms pass through a through hole of a connector when the elastic arms are stretched to reduce the gap to make the connector contact the base pillar. After the force is removed, the gap between the elastic arms is restored to fasten the fastening structure between the elastic arms and the base pillar in a floating state. An electronic assembly and an operating method of the fastening structure are also provided.

An optical disk drive (ODD) including a shell and a locking module is provided. The shell includes a main body portion and a side portion, and the side portion is connected to the main body portion. A concave space is formed between a side surface of the main body portion and a top surface of the side portion. The locking module is disposed inside the concave space. The ODD is detachably held in a support frame of an electronic device through the locking module. In addition, a locking module is also provided.

A fastening structure including a base pillar, a pair of elastic arms, and a top pillar is provided. The base pillar is assembled to an object, the elastic arms are connected between the top and the base pillars, and a gap is provided between the elastic arms. The top pillar is adapted to stretch or compress the elastic arms when an external force is exerted to reduce or expand the gap. The top pillar and the elastic arms pass through a through hole of a connector when the elastic arms are stretched to reduce the gap to make the connector contact the base pillar. After the force is removed, the gap between the elastic arms is restored to fasten the fastening structure between the elastic arms and the base pillar in a floating state. An electronic assembly and an operating method of the fastening structure are also provided.

A hard disk tray adapted for accommodating a hard disk having a plurality of screw holes at two sides is provided. The hard disk tray includes a body and a cover. The body includes two body lateral walls and a plurality of fixing members protruding from the two body lateral walls and corresponding to at least a part of the screw holes. The cover is pivoted to the body and includes two cover lateral walls. When the hard disk is placed in the hard disk tray, the fixing members extend into the at least a part of the screw holes, and when the cover is closed to the body, the two cover lateral walls are located outside the two body lateral walls so as to prevent the two body lateral walls from moving outwardly. A hard disk rack assembly is further provided.

The disclosed technology provides an enclosure system for computing equipment and a method for manufacturing an enclosure system, which includes a front enclosure base configured to secure a plurality of tray modules, each of the plurality of tray modules comprising a printed circuit board to connect a plurality of electronic components and being connected at a rear end to a connectivity midplane. The front enclosure base has a front end taller than the rear end such that the front end is configured to structurally support the plurality of tray modules and the rear end allows connecting rear faces of each of the plurality of tray modules to the connectivity midplane.

The disclosed technology provides an enclosure system for computing equipment and a method for manufacturing an enclosure system, which includes a front enclosure base configured to secure a plurality of tray modules, each of the plurality of tray modules comprising a printed circuit board to connect a plurality of electronic components and being connected at a rear end to a connectivity midplane. The front enclosure base has a front end taller than the rear end such that the front end is configured to structurally support the plurality of tray modules and the rear end allows connecting rear faces of each of the plurality of tray modules to the connectivity midplane.