In one example a latching system is disclosed. The latching system has a handle that moves along an axis of motion between three positions: a latched position, an unlatched position and an engaged position. The handle moves a retention clip from a locked position into an unlocked position when the handle moves from the unlatched position into the engaged position.

Technology is provided for a pivoting memory drive adapter. The memory drive adapter is used for adapting memory drives for insertion into a drive bay that is larger than the memory drives. The memory drive adapter includes an adapter frame and a memory carrier. The adapter frame has an envelope compatible with a hard disc drive (HDD) drive bay, for example, and includes a pair of spaced apart sidewalls each including a slot. The memory carrier includes a pair of pins extending from opposite sides of the memory carrier engaging a corresponding one of the pair of slots. Thus, the memory carrier can pivot with respect to the adapter frame. A pair of spaced apart ledges divides the memory carrier into two memory drive locations, each sized to receive a memory drive, such as a solid state drive (SSD).

A base chassis supports a set of storage cages. The base chassis includes a front portion that is removably attachable to a first storage cage. The base chassis also includes an extension portion. The extension portion has a first end that is fixedly attachable to the front portion to extend a length of the base chassis to support an additional storage cage when the first storage cage is detached from the front portion. The extension portion also has a second end that is attachable to the first storage cage to support the first storage cage.

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 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 computing device caddy for housing a computing device is provided. The caddy includes a first caddy component. The first caddy component includes a first end wall including a first plurality of fins coupled to an outer surface of the first end wall. The first plurality of fins are configured relative to each other to create eddies within a flow. The caddy also includes a second caddy component. The second caddy component includes a second end wall. The second end wall is opposite the first end wall. The second caddy component is coupled to the first caddy component, thereby defining a cavity for housing the computing device.

Embodiments provide a terminal, and the terminal includes a body, a cover body covering the body, a circuit board mounted in the body, a central processing unit welded on the circuit board, a control part mounted on the cover body, and a protection switch welded on the circuit board. A hard disk slot for accommodating a hard disk is disposed in the body. The cover body is detachably mounted on the body, and is configured to seal the hard disk in the hard disk slot. The cover body is opened to drive the control part to open the protection switch. An electrical signal variation is generated due to opening of the protection switch. After detecting the electrical signal variation, the central processing unit instructs the hard disk to perform data protection and powers off the hard disk.

A component carrier with a tray, a slide cage, a level, and a tilting mechanism. The tray has a bottom surface with a groove formed therein. The slide cage is actuatably coupled with the tray and has a receiving space and an undercarriage. The lever is pivotally coupled with the slide cage and has a lower portion for engaging the groove to transition the slide cage between a first position and a second position. The tilting mechanism is coupled with the tray and configured for biasing the slide cage to the second position. In the first position the undercarriage of the slide cage is positioned proximal to the bottom surface of the tray. In the second position a first end portion of the undercarriage of the slide cage is displaced away from the bottom surface and a second end portion is positioned proximal to the bottom surface of the tray.

A latch and release mechanism for a computer component may allow release of the component with reduced force and easier access through a cam lever that rotates around a pivot point, such as a pin, to translate rotational motion into a force to unlock the drive from a bay of a chassis. Additionally, the cam lever may be configured to provide a force that ejects the drive from the bay nearly simultaneously with the unlocking of the drive. Thus, a user can remove a drive from a bay with a small application of a single type of force to the cam lever of a latch and release mechanism.

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 a motherboard that includes at least one designated base bracket. Each of the at least one designated base bracket is configured to enable a carrier of a computing component to be mounted on and detached from. A designated base bracket can include one or more movable pins, one or more fixed pins, and a close latch.