The present disclosure provides a tool-less assembly hard disk drive bracket, including: a fixation rack, including a fixation bracket portion and a fixation arm connected with a first side of the fixation bracket portion; a rotation rack, including a rotation arm connected with a second side of the fixation bracket portion, and a rotation bracket portion connected with the rotation arm, the rotation bracket portion is connected with the fixation bracket portion to support a hard disk drive; and at least two connecting components, arranged on an inner side of the fixation arm and the rotation arm, respectively, the connecting components connect and fix the hard disk drive in the structure formed by the fixation rack and the rotation rack. The present disclosure is simple in installation, convenient in assembly and disassembly, and easy to maintain, thereby having high economy and practicability.

A hard disk holder includes an integrated sheet metal framework. The integrated sheet metal framework is a main body structure of the hard disk holder, and a head and a tail of the integrated sheet metal framework are clamped to form a closed framework. The integrated sheet metal framework specifically includes a first side plate, a head end plate, a second side plate, and a tail end plate that are formed by sheet metal and are disposed in sequence. An inner side of the first side plate and an inner side of the second side plate each have a limiting bulge, and the hard disk body has limiting holes. The limiting bulges adapt to the limiting holes. When the hard disk body is mounted to the hard disk holder, the limiting bulges extend into the limiting holes to form a limiting structure.

A drive carrier for retaining a persistent storage drive in an enclosure. The drive carrier includes a mounting bracket, a handle coupled to the mounting bracket, and an electromagnetic interference (“EMI”) shielding apparatus disposed between mounting bracket and at least a portion of the handle. The mounting bracket is shaped to be coupled to the persistent storage drive. The EMI-shielding apparatus includes a plurality of EMI-shielding fingers. Each EMI-shielding finger includes a lower surface, an upper surface that is approximately parallel to the lower surface, and a contoured surface extending between the lower surface and the upper surface.

An electronic device includes a case module, a circuit board, a detachable module and a lever mechanism. The detachable module is detachably installed on the case module and slidable relative to the case module, and an electrical connector of the detachable module is mated with a mating electrical connector of the circuit board when the detachable module is installed on the case module and slides to an engaging position. The lever mechanism includes a lever component partially located between the case module and the detachable module, and an abutting component fixed on the case module. When the lever component is operated to pivot relative to the detachable module, the lever component cooperates with the abutting component in a contacting manner to drive the detachable module to slide, so as to disengage the electrical connector of the detachable module from the mating electrical connector of the circuit board.

A drive carrier for a device of an information handling system includes first and second portions. The first and second portions are placed in physical communication with the device. The first portion includes first and second side rails to secure the device within the drive carrier. The first and second side rails slide within a first slot of a bay of the information handling system. The second portion is located on top of the first portion and floats away from and toward the first portion when the drive carrier is inserted with the bay of the information handling system. An amount of float for the second portion is based on a bay pitch of the bay.

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.

Provided is a heat-dissipating, shock-absorbing structure which is applicable to an electronic module with a hard disk drive. The heat-dissipating, shock-absorbing structure includes a heat-dissipating frame, an elastomer, and a plurality of heat conduction layers. The heat-dissipating frame has a fixing segment and two extending segments. The extending segments connect with two ends of the fixing segment. The fixing segment connects with one side of the hard disk drive. The distance between the extending segments is greater than the thickness of the hard disk drive. At least a portion of the elastomer is disposed at the extending segments. The heat conduction layers cover the elastomer.

A system, information handling system and method are disclosed for accommodating multiple devices in a single bay. A bracket comprises a pair of sidewalls adapted for slidable insertion in slots in a bay. An upper portion of the bracket comprises inner walls formed with slots and a lower portion formed with flanges. A tray formed with rails on exterior surfaces may be inserted in the slots in the inner walls of the bracket. A first SFF device or devices may be positioned in the tray and a second SFF device may be positioned in the flanges to install multiple SFF devices in the bay.

An apparatus is provided for the simultaneous transferring of multiple storage devices from a chassis to reduce service time and associated server temperature fluctuations. The storage transfer device may be mounted to a chassis with a multitude of electronic devices, e.g., a JBOD with HDDs, above the devices to be removed. The storage device may then be manipulated to mechanically unlatch the devices from the chassis and simultaneously attach the devices to the transfer device. The devices may then be disconnected and withdrawn from the chassis and pulled into the storage transfer device. The devices may be re-installed later using the storage device and the reverse process.

A carrier for a storage device is provided. The carrier includes an accommodation bracket, a panel and an electromagnetic shielding element. The accommodation bracket has an open space. The panel has a handle. The electromagnetic shielding element is disposed between the accommodation bracket and the panel. The electromagnetic shielding element is engaged with the accommodation bracket.