The embodiments herein describe a computing device (e.g., a storage server) that includes at least one telescoping unit which includes a plurality of removable (or pluggable) hardware components. The computing device includes a chassis which defines a form factor of the computing device. The telescoping unit, when prompted by the user, can extend vertically from a top surface of the computing device. By doing so, the pluggable hardware components are then exposed to the user who can add or replace the components. In one embodiment, the telescoping unit includes telescoping links disposed on opposite sides which are used to guide or urge the telescoping unit vertically from the chassis. Cross links may be coupled between first and second rails where one end of each of the links is coupled to a sliding member in the rail while the other end is fixably attached to the rail.

A portable computing system includes a transit case for providing structure for the mobile computing system, and has a power supply for providing power to the portable computing system. The portable computing system further includes a slidably removable sled disposed inside the transit case, configured to hold a plurality of computing components and to enable access to the plurality of computing components. The slidable removable sled includes a top chamber configured to hold a first type of computing device; a bottom chamber configured to hold a second type of computing device; and a floor disposed between the top chamber and a bottom chamber. The portable computing system further includes a switch, disposed in the bottom chamber, to provide computer networking and communications functions. The portable computing system further includes a plurality of computing blades, disposed in the top chamber, to provide computing capabilities, wherein each of the plurality of computing blades comprises a central processing unit (CPU) comprising a software multiplexer for interfacing directly with a plurality of solid state drives (SSDs).

Electrical and electronic devices are often installed in so-called racks. Racks of this type are shelf-like frames into which the devices are inserted and can be fastened, for example by means of screws. The racks commonly provide a pair of support rails for each device, upon which rails the device can be placed and can be inserted into the rack. The device can be subsequently fixed to the rack, for example screwed in. Within the scope of the invention, a device arrangement (1) is disclosed comprising at least one stacking device (4), wherein the stacking device (4) has adjustable feet (15) on the bottom surface (11) for supporting on a placement surface, comprising a base device (3), wherein the at least one stacking device (4) is arranged on the base device (3) so that these form a device tower (13), wherein the adjustment feet (15) of the stacking device (4) stand on the base device (3), wherein the device arrangement (1) comprises a 19-inch frame (2) and the stacking device (4) and the base device (3) are designed as insert devices with front plates (6) for the 19-inch frame (2), wherein the base device (3) and the at least one stacking device (4) are arranged as a device tower (13) in the 19-inch frame (2), and wherein the front plates (6) are connected to the 19-inch frame (2).

An example multi-configuration bay for housing resource modules for a computing device. The multi-configuration bay includes a common bay and an adaptor that may be removably installed within the common bay. The common bay includes first rails on its top and bottom walls, the first rails being to hold resource modules in vertically oriented installed-positions within the common bay. The adaptor includes second rails on its side walls, the second rails being configured to hold resource modules in horizontally oriented installed-positions within the common bay (when the adaptor is installed in the common bay).

A rack includes first to fourth column members and first and second guide members. A case of an electric device has first and second side surfaces in a width direction that are supported by the first and second guide members, respectively. First and second restriction members are attached to inner surfaces of the first and second side surfaces of the case, respectively, for restricting the case from moving in a front direction of the rack. Second restriction member is attached to face the first restriction member in the width direction. In a state where the electric device is housed within the rack, the first restriction member is located between the first and third column members in a front-back direction. The second restriction member is located between the second and fourth column members in the front-back direction.

A method of maintaining a circuit card in a card rack and a circuit card rack system are disclosed. A card rack including a laterally oriented clamping slot is provided. The clamping slot is at least partially formed from a temperature-contractible material. A circuit card having a clamped side region is provided. At least a portion of the clamped side region is inserted into the clamping slot. A predetermined temperature differential is applied to the clamping slot to reduce a longitudinal dimension of at least a portion of the clamping slot. A compressive force is exerted on the portion of the clamped side region which is located longitudinally within the clamping slot, via thermal expansion of the clamping slot.

A fastening system for a mounting rack includes a terminal strip having bores through which screws may pass. The bores are arranged relative to one another in such a way that the screws can be screwed into the mounting rack. Also disclosed is a corresponding method for fastening assemblies to a mounting rack, a corresponding mounting rack and a corresponding power-electronics installation.

A sealing retainer may be coupled between a chassis and an electronic module. The sealing retainer includes a retainer body to be coupled to the chassis and a first cooling gas passageway that may be aligned with a chassis cooling gas passageway. A gas seal body has a second cooling gas passageway aligned with the first cooling gas passageway and coupled to the retainer body and movable between a retracted position that permits insertion and removal of the electronic module and an extended position that seals against the electronic module.

A modular, acoustic amplification apparatus (100) comprises: a first module (1), including a first casing (11) and an acoustic amplifier (12) positioned inside the first casing (11), wherein the first casing (11) has the shape of a parallelepiped having a first base and a first height (H1), wherein the first base has a first long side (L1) and a first short side (C1); a second module (2) including a second casing (21) and a power supply or an accumulator positioned inside the second casing (21), wherein the second casing (21) has the shape of a parallelepiped having a second base and a second height (H2), wherein the second base has a second long side (L2) and a second short side (C2).

A method of maintaining a circuit card in a card rack and a circuit card rack system are disclosed. A card rack including a laterally oriented clamping slot is provided. The clamping slot is at least partially formed from a temperature-contractible material. A circuit card having a clamped side region is provided. At least a portion of the clamped side region is inserted into the clamping slot. A predetermined temperature differential is applied to the clamping slot to reduce a longitudinal dimension of at least a portion of the clamping slot. A compressive force is exerted on the portion of the clamped side region which is located longitudinally within the clamping slot, via thermal expansion of the clamping slot.