A module for a networking node is disclosed. The module includes a Printed Circuit Board (“PCB”), one or more circuits mounted to the PCB and a faceplate. The faceplate includes a middle plate, a first side plate, and a second side plate. The first side plate extends from the middle plate at an obtuse angle relative to the middle plate towards a first side and back of the module. The second side plate extends from the middle plate, opposite to the first side plate, at an obtuse angle relative to the middle plate towards a second side and the back of the module.

A connector gap between a module connector mating surface and the backplane connector of a chassis may be eliminated through a mechanism that forcefully pushes (or pulls) the module towards the backplane and/or forcefully pushes (or pulls) the backplane toward the module. A spring-loaded or resilient element may be used to fasten the module in a way that effectively fills any designed-in and tolerance-induced gap in the connector interface, allowing the connector to fully seat. In addition, a gasket or other compressible member may be included at the connector mating interface. The gap in the connector interface may be reduced by introducing adjustable card cage members that are capable of being set during the assembly or manufacturing process using special alignment fixtures. The gap in the connector interface may also be reduced by introducing a higher tolerance capable manufacturing process, such as machining, to the card cage sub-assembly.

A rail vehicle control relay board includes a main frame, a mother board and a daughter board assembly which are arranged in the main frame, the main frame includes a board face mounting frame and a daughter board mounting frame which protrudes from the board face mounting frame, the mother board is arranged in the board face mounting frame, and multiple daughter board assemblies perpendicular to the mother board are arranged side by side in the daughter board mounting frame, the daughter board assemblies are electrically connected to the mother board, and multiple first connectors configured to perform output outwards are arranged on the mother board. The rail vehicle control relay board has a high strength, and may reduce the daughter board loosening faults, extend a wiring space and increase the number of relays arranged.

A chassis includes at least one slot and a plurality of guiding extensions. The at least one slot is configured for receiving a plurality of first storage devices (e.g., E1.S carriers) or a second storage device (e.g., 1×2.5 inch hard drive disk (HDD)). The at least one slot is formed by a top wall, a bottom wall, a first side wall, and a second side wall. The guiding extensions extend into the at least one slot. The guiding extensions include a first set of guiding extensions and a second set of guiding extensions. The first set of guiding extensions configured to receive and secure one of the first storage devices. The second set of guiding extensions configured to receive and secure a second one of the first storage devices.

A system, a shelf, and a high density platform optimize the physical arrangement of cards to maximize cooling effectiveness and line card pitch while minimizing backplane trace lengths between line interface and switch fabric cards. The shelf and system and associated card arrangement supports scaling to a larger, double-size system that maintains the required length of backplane traces for card communications without compromising card cooling. Advantageously, the shelf and system maintains full NEBS compliance through an arrangement supporting full air intake/outtake through a front and/or back of the shelf or system, i.e. no side ventilation, and includes a false front to ensure all cards (switch fabric and line interface cards) are substantially flush with one another.

The invention relates to an assembly for securing at least one expansion card (comprising a half-open chassis for receiving a first circuit board of a server module having at least one first plug connector, a carrier component for receiving at least one expansion card and at least one second circuit board secured to the carrier component. The carrier component comprises at least one securing point for rotatably and releasably receiving the carrier component on the half-open chassis and at least one first bearing surface for supporting the carrier component on a second bearing surface of the half-open chassis, arranged in the region of opposite ends of the carrier component. Here, a first mating plug connector of the second circuit board is arranged such that the second circuit board is electrically connected to the first circuit board by receiving and pivoting the carrier component around the securing point.

The invention relates to an automation module for building automation, which is designed to be installed in a wall of a house as an at least partially concealed installation. The automation module comprises a high voltage region (6) and a low voltage region (4). It additionally comprises an insulation region (5) for separating said high (6) and low (4) voltage regions, a first circuit board (41, 41′) having at least one input interface (411, 414), a second circuit board (42) having at least one control unit (422), and a third circuit board (61) having at least one switching element (611). Said first, second and third circuit boards (41, 41′; 42, 61) and the insulation region (5) are arranged one above the other in layers.

A server including chassis, motherboard, mounting cage, first guide pillar and expansion card. Motherboard is stacked on chassis bottom plate. Mounting cage includes bearing base, handle and first pivot. Bearing base is located on a side of motherboard located away from the chassis bottom plate and located between two chassis side plates. One of two bearing base side plates includes first guide slot, and handle is pivotally connected to the one of two bearing base side plates via first pivot and includes engagement hole. First guide pillar is fixed to the one of two chassis side plates and slidably disposed in first guide slot of the one of two chassis side plates. First guide pillar is engaged into engagement hole of handle. Expansion card is stacked on bearing base bottom plate and electrically connected to motherboard.

A mount cage configured to mount disk drive to rack and including first cage part, second cage part, first positioning pillar and second positioning pillar. First cage part includes first plate portion, second plate portion, and third plate portion. Second plate portion and third plate portion stand on same side of first plate portion and spaced apart from each other. Second cage part includes fourth plate. Fourth plate is pivotally connected to a side of second plate portion located away from first plate portion to be detachably engaged with a side of third plate portion located away from first plate portion. First plate portion, second plate portion, third plate portion, and fourth plate together form accommodation space and two apertures connected to accommodation space. First positioning pillar is fixed in first positioning hole of disk drive. Second positioning pillar is fixed in second positioning hole of disk drive.

An electronic device includes a slot, and a backboard that is disposed on the depth side in the slot and is electrically connected to a printed circuit board inserted in the slot. The electronic device further includes a casing having the slot formed therein, the casing being configured to accommodate therein at least part of the backboard, and a cover member configured to be attachable to and removable from the casing. When attached to the casing, the cover member together with the casing forms the external appearance of the electronic device. The cover member is attached to the backboard integrally.