A data storage enclosure can have one or more data storage devices positioned in an enclosure slot having one or more stops. A data storage device can be attached to a rail having a rail width and having first and second protrusions offset from one another. The first and second protrusions may each have protrusion widths that are less than the rail width with the second protrusion shaped to provide a positive stop that retains the rail in an enclosure slot.

A method of manufacturing a chassis of an HIS includes manufacturing a chassis having a base panel with an upper chassis surface. The method further includes attaching at least one resilient component to the upper chassis surface and that upwardly presents an adhesive surface to fixedly engage and to provide vibration damping for a storage drive that is inserted on the adhesive surface during assembly of the IHS.

A combination device includes a base, a hinged bottom, a motherboard, and a frame. A first space for accommodating a HDD, a second space for accommodating a cable, and a compartment for accommodating the motherboard are provided in the base and the frame. The compartment includes two grooves at front and rear ends respectively, an opening, and a through hole. A lock member and a first biasing member are disposed in each groove. A pivotal arm is formed with the lock member. The base includes four first bossed holes at four corners respectively, and four second bossed holes. Second biasing members are anchored in the second bossed holes respectively. The frame includes an opening on a central portion of a top for accommodating the connector. The HDD is mounted on the connector. Tops of the second biasing members urge against an inner surface of the top of the frame.

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).

An electronic apparatus and a hot-swappable storage device thereof are provided. The hot-swappable storage device includes a carrier, a connector, a controller, and a wireless communication interface. The carrier is configured to carry a plurality of storage components. The connector is configured to be electronically connected to a host end for performing a data transfer operation. The controller detects a connection status between the connector and the host end. The wireless communication interface decides whether to perform the data transfer operation according to the connection status.

A drive carrier includes a latch wire, and a track that includes first and second segments. The latch wire is configured to move along a channel in the track to enable a handle of the drive carrier to transition between multiple positions within the track. The first segment is to be placed in physical communication with the latch wire while the latch wire is at a first position and a second position within the track. The second segment is in physical communication with the first segment. The second segment is to transition between a misaligned position and an aligned position with respect to the first segment, and the latch wire is to transition from the second position to a third position within the track in response to the second segment being in the aligned position.

A storage drive configured for use in a storage drive block and a storage drive block are provided. The storage drive block in one example includes a plurality of storage drives joined together into a substantially rigid storage drive block, a block communication element extending to the plurality of storage drives and adapted to communicatively link a plurality of communication boards of the plurality of storage drives to a mass storage chassis assembly, and one or more joining elements affixing the one or more mounting elements of each storage drive to form the storage drive block.

A mounting apparatus for data storage devices includes a plurality of installing racks and a plurality of data storage devices. The installing racks are stackable together and can be fixed together. Each installing rack defines a receiving space into which one data storage device can be received.

A method of controlling a computing device includes detecting a user input request to disengage a drive component from a computing device, the computing device comprising a multiple-drive storage system having a plurality of drive components forming a single logical unit, and determining whether or not disengaging the drive component would cause failure of the multiple-drive storage system. The method includes disallowing disengagement of the drive component from the computing device in response to determining that disengaging the drive component would cause failure of the multiple-drive storage system, and allowing disengagement of the drive component from the computing device in response to determining that disengaging the drive component would not cause failure of the multiple-drive storage system.