In accordance with embodiments of the present disclosure, a vibrational isolator may include at least one supporting section and at least one attachment member mechanically coupled to the at least one supporting section and configured to mechanically couple to a chassis, such that when disposed in a chassis, the at least one supporting section suspends from the chassis and is configured to support vibration-generating equipment. In accordance with these and other embodiments of the present disclosure, a method may include forming at least one supporting section and forming at least one attachment member mechanically coupled to the at least one supporting section and configured to mechanically couple to a chassis, such that when disposed in a chassis, the at least one supporting section suspends from the chassis and is configured to support vibration-generating equipment.

A system for performing computing operations includes a rack, one or more shelves coupled to the rack, and two or more computing modules. Each computing module may include a chassis, one or more circuit board assemblies in a primarily vertical orientation, and one or more hard disk drives in a primarily vertical orientation. The circuit board assemblies and the hard disk drives are coupled to the chassis of the computing module.

A removable storage cartridge system may include a linear push-push mechanism comprising a carriage having a lock bar and a lock bar spring, and an enclosure having a mounting bracket having a lock guide. The lock guide is configured to interact with the lock bar and spring such that, in response to a first pushing force, reception of the carriage into the mounting bracket positions the carriage into a locked position within the enclosure and, in response to a second pushing force, the carriage is released from the locked position and ejected from the system.

A housing includes a housing body formed with an engaging groove and a carrier device disposed in the housing body. The carrier device includes a carrier frame and a latching assembly. The carrier frame is configured to carry an electronic component and includes a pivoting sidewall rotatably pivoted to the housing body. The carrier frame is rotatable between a first position, where the carrier frame is disposed in the housing body, and a second position, where the carrier frame is pivoted out of the housing body. The latching assembly is disposed on the pivoting sidewall and is releasably engaged to the engaging groove so as to position the carrier frame at the second position.

A storage module installed with multiple M.2 SSDs includes a frame, at least one circuit assembly, and plural M.2 SSDs. The circuit assembly is fixed to the frame along a direction. The circuit assembly includes plural circuit modules and a power connector. The circuit modules are electrically connected to each other in series. Each of the circuit modules includes a circuit board, a M.2 slot, and a signal connector. The circuit board is fixed to the frame. The M.2 slot is fixed to the circuit board. The signal connector is electrically connected to the circuit board and located outside the frame. The power connector is electrically connected to the circuit board of a corresponding one of the circuit modules. The M.2 SSDs plug into the M.2 slots of the circuit modules respectively.

A blank cartridge includes an impedance portion to control a flow of cooling media through the blank cartridge to a plurality of computing components, and an actuator to change an impedance level of the impedance portion. The actuator receives a control signal to change the impedance level of the impedance portion based on a location of the plurality of computing components relative to the blank cartridge.

Disclosed is a two-way adjustable structure of hard disk box, comprising a first board, a first side wall, a second side wall and a plurality of fixing bolts. The first board has a first surface and a second surface. The first side wall is vertically mounted at one side of the first board, and is divided into a first portion and a second portion by the first board. The second side wall is vertically mounted at the other side of the first board, and is divided into a first portion and a second portion by the first board. Each pair of some fixing bolts respectively pass through the first side wall and the second side wall at two symmetrical positions. A first accommodating space and a second accommodating space are formed by the first board, the first side wall, and the second side wall.

The present disclosure relates to a vibration reduction device, an electronic device and mobile equipment containing same. The vibration reduction device comprises: a first fixing component (10) which is a frame structure (11); a second fixing component (100) arranged in the center or near the center position of the first fixing component (10); and a vibration reduction connecting component (50) positioned between the first fixing component (10) and the second fixing component (100) and used for connecting both together. The vibration reduction connecting component (50) comprises a vibration reduction connecting frame (53) connected to the frame structure (11), and an inverted U-shaped structure (51) positioned in the vibration reduction connecting frame (53), connected to the lower part of the vibration reduction connecting frame (53) through supporting legs and connected with the second fixing component (100). The vibration reduction device of the present disclosure can provide excellent vibration reduction and impact-prevention protection for electronic products and precision electronic equipment. It is especially able to protect electronic products and precision electronic equipment installed on mobile equipment, such as a vehicle, against physical damage while under severe travelling conditions, as well as ensure their normal operation. The vibration reduction device according to the present disclosure not only has a simple structure and occupies little space, but also has simple installation and long service life, and can be suitable for varying load conditions.

An example carrier module may comprise a carrier board, which may include a storage drive interface. The storage drive interface may engage with a storage drive so the storage drive can electrically communicate with the storage drive interface. The carrier board may further include an adapter connector in electrical communication with the storage drive interface. The adapter connector may removably engage with a complementary adapter receiver and may include multiple signal pins, and a ground pin and a power pin which are longer than the signal pins. The pins may facilitate electrical communication between the adapter receiver and the adapter connector. The carrier board may also include a power storage component in electrical communication with the storage drive interface and the adapter connector. The power storage component may receive and store a power input from the adapter receiver and may provide the power input to the storage drive interface.

Disclosed is a two rack unit chassis and low profile tool-less hard disk drive carrier (HDD). The two rack chassis including a plurality of HDD bays and a backplane including a plurality of connectors corresponding to the plurality of bays, each bay configured to receive a low profile tool-less carrier. The low profile tool-less carriers each comprising a first latch configured to release a sidewall of the low profile tool-less carrier and receive an HDD, a second latch configured to release a lever having at least one protraction at an inward end, and the lever configured to couple the at least one protrusion of the low profile tool-less carrier to the connector of the corresponding bay to which the low profile tool-less carrier is inserted.