A securing apparatus configured to mount a data storage device in an enclosure includes a shielding assembly configured to be secured to a panel of the enclosure and a sliding pole. The shielding assembly includes a frame and a rotating plate rotatably mounted to the frame. The sliding pole is slidably mounted to the frame and defines a plurality of latching slots. The frame defines an aperture for the data storage device to pass through; the rotating plate comprises a plurality of hooks. The sliding pole is slidable relative to the frame to engage the hooks in the latching slots. The rotating plate is secured to the frame and shields the aperture, preventing the data storage device from being taken out of the enclosure.

A mechanical enclosure provides a mechanism for coupling a storage device to a computer system. The mechanical enclosure can be removably coupled to the computer system and can allow for coupling of the storage device to the computer system without using specialty cables and connectors. The mechanical enclosure can allow the storage device to be coupled to computer system without significantly degrading the speed at which the data stored within the storage device is downloaded onto the computer. The storage device can be inserted into the mechanical enclosure which couples the storage device to the mechanical enclosure. The mechanical enclosure can be inserted into the computer system which similarly couples the computer system to the mechanical enclosure to effectively couple the storage device and the computer system. Once the storage device is effectively coupled to the computer system, the data stored within the storage device can be downloaded onto the computer without the need for specialty cables and connectors.

An approach for assembling a hard drive to a hard drive carrier is provided. The approach includes an ergonomic tool to aid with assembly. The ergonomic tool allows for a reduction in assembly time and prevents damage to the components. The ergonomic tool comprising of a base having a first surface and a first end open for receiving the components. The tool has a set of walls rising from the base, a first wall rising from the base proximate a second end opposite the first end and a pair of opposing side walls including voids rising from the first surface between the first end and the second end, to form a slot there between to receive the components within and adjacent the first surface. The tool has a releasable hold mechanism that aligns the components during assembly.

A data storage device carrier includes a first supporting bracket and an upper cover. The first supporting bracket includes a first bottom plate and two first side plates, each of the first side plates defines an opening on an upper end and a sliding slot; the upper cover is slidably attached to the first supporting bracket, the first supporting bracket is configured to accommodate the first data storage device, the limiting columns are respectively received in the sliding slots via the openings, the top plate is configured to resist the upper surface of the first data storage device, the top plate comprises a connecting piece for connecting with another supporting bracket. A data storage system is further disclosed.

The present invention relates to an assembly (10) for attaching a data storage device (12) to an on-board computer including an encapsulation structure (17), and a receiving structure (18) for receiving the encapsulation structure (17) comprising a first connector complementary to a connector of the storage device and a second connector complementary to a connector of the onboard computer.

The encapsulation structure (17) and the storage device (12) mounted therein are movable relative to the receiving structure (18) between an inserted configuration in which the encapsulation structure (17) and the storage device (12) are inserted into the receiving structure (18) and the connector of the storage device (12) is connected to the first connector, and a removed configuration in which the encapsulation structure (17) and the storage device (12) are removed from the receiving structure (18).

A storage device frame assembly is configured to be mounted on a first side plate. The storage device frame assembly includes a support frame and a handle. The support frame is configured to be removably mounted on the first side plate. The handle includes a pivotable component and a slidable component. The pivotable component is pivotably disposed on the support frame. The slidable component is slidably disposed on the pivotable component.

A fixing bracket is used to fix a plurality of storage devices in a housing. Each of the storage devices has a first sidewall and a second sidewall opposite and respectively having plurality of fixing holes. The fixing bracket includes a frame body and two pivotal members. The frame body has an opening and an accommodating space. The frame body includes a plurality of first fixing pins in the accommodating space. The storage devices can be accommodated in the accommodating space. Each of the first fixing pins is for being inserted into the corresponding fixing hole on the first sidewall. The pivotal members are pivotally connected to the frame body. Each of the pivotal members includes a plurality of second fixing pins. When the pivotal members cover parts of the opening, each of the second fixing pins is for being inserted into the corresponding fixing hole on the second sidewall.

Apparatus is provided in which digital data is processed and the apparatus including processing means for processing received and/or stored data, a data storage media can be selectively mechanically located with said apparatus via mounting means to allow the transfer of the data between the storage media and the processing means when connected. The mounting means includes one or more biasing means to ensure that the storage media, when inserted into the mounting means, is moved into the required location for connection to the power and/or data connection means of the apparatus.

A device for mounting a hard disk in a server or other housing includes a frame, a hard disk, and a rotatable element. The frame defines a receiving space thereon and includes an end wall. The hard disk is slidably received in the receiving space. The hard disk includes a fastening element facing to the end wall. The hard disk is slidably attached to the end wall and the fastening element is locked to the end wall. The rotatable element is attached to the end wall and can rotate from a first position to a second position to abut the fastening element. The rotatable element can be pressed against the fastening element to unlock and the hard disk can be slidably detached from the end wall.

In one embodiment, a computer-implemented method includes determining whether a medium in a drive is in motion, the drive being mounted in a receptacle, in response to determining that the medium is in motion, preventing physical removal of the drive from the receptacle, and in response to determining that the medium is not in motion, allowing physical removal of the drive from the receptacle. In another embodiment, a computer program product for controlling removal of a drive includes a computer readable storage medium having program instructions embodied therewith. The computer readable storage medium is not a transitory signal per se. The program instructions are readable and/or executable by a computer to cause the computer to perform the foregoing method.