A backplane and a communications device are disclosed. In one example, the backplane includes at least one fixing plate, multiple connectors, and multiple flexible cables, where signal connection is implemented between corresponding connectors by the flexible cables. Each of the connectors is provided with a housing, and multiple signal pins are installed on the housing. The housing is installed on the fixing plate and is provided with a jack for insertion of a connector of a subcard in the communications device. One end of each signal pin is inserted into the jack, and the other end is connected to each flexible cable.

An interconnection system for a rack of a system of an aircraft is provided. The rack includes at least one shelf with at least one frame adapted to receive an electronic device, the interconnection system comprising a rear panel, consisting of a printed circuit, the rear panel comprising as many coupling fittings as connectors of the shelf, each coupling fitting being connected to a connector, at least one interface for connecting a lateral panel consisting of an electronic circuit board, the lateral panel comprising: an interface for connecting the rear panel and connectors allowing a connection to the system of the aircraft, the printed circuit of the rear panel allowing a set of predefined electrical links between the connectors and the interface, the electronic circuit board of the lateral panel allowing a set of electrical links to be set up between the interface and the connectors to the system of the aircraft.

The disclosure provides a server including a housing, a plurality of hash boards, a power module and an electrical connection board. Each hash board is slidably arranged in a first accommodating space. The plurality of hash boards and the power module are respectively connected to the electrical connection board. The power module supplies power to the plurality of hash boards through the electrical connection board. The electrical connection board includes two conductive connection boards, each of which is provided with a plurality of conductive pins. The pins form multiple pairs of conductive pins in one-to-one correspondence. Each pair of conductive pins corresponds to each hash board and is electrically connected to supply power to the hash board. Each pair of conductive pins is detachably matched with each hash board to connect or disconnect the power supply path of the hash board.

In a stack or matrix of lockers, typically in two, three or more tiers or rows and in multiple columns, charge power strips are secured at the back sides of the lockers and exposed through openings in the back walls of the lockers so as to provide line power and also low-voltage DC charging power for smartphones and other portable devices, with a plurality of different charge port fittings provided. The power strips are of a length to extend to two or more lockers and preferably are installed vertically, but could be installed horizontally. The lockers have a protected channel at rear, within which the power strip is installed.

A modular printed circuit board assembly is provided. The modular printed circuit board assembly includes a housing unit. The housing unit includes a plurality of connectors, a heat transfer unit, and an identification unit. The plurality of connectors connects a host interface board of a plurality of host interface boards with a plurality of module boards and connects a module board of the plurality of module boards with the plurality of host interface boards. The host interface board includes information about an electronic device. The heat transfer unit dissipates the heat to a heat sink. The heat sink is a passive heat exchanger for conducting the heat generated by the electronic device. The identification unit is configured to read the unique identification of the electronic device from the host interface board to determine a structural combination of the electronic device.

A separated back plane design within a server rack is provided which allows for the hot-swapping of a control module board. The separated back plane design consists of a base plane board and a control module board which connects to the base plane board. The base plane board can draw power from a power supply and can connect a number of electrical components which are not significantly susceptible to damage or failure. The control module board can consist of a number of other electrical components, which are susceptible to damage or failure. The control module board connects to the base plane board, and can be removed during failure of the control module board. When the control module board is removed from the base plane board, the base plane board and its functions continue to operate, and power need not be shut off in order to replace the control module board.

A backplane and a communications device are disclosed. In one example, the backplane includes at least one fixing plate, multiple connectors, and multiple flexible cables, where signal connection is implemented between corresponding connectors by the flexible cables. Each of the connectors is provided with a housing, and multiple signal pins are installed on the housing. The housing is installed on the fixing plate and is provided with a jack for insertion of a connector of a subcard in the communications device. One end of each signal pin is inserted into the jack, and the other end is connected to each flexible cable.

A backplane and a communications device are disclosed. The backplane includes: at least one fixing plate, multiple connectors, and multiple flexible cables, where signal connection is implemented between corresponding connectors by means of the flexible cables, each of the connectors is provided with a housing and multiple signal pins installed on the housing, and the housing is installed on the fixing plate and is provided with a jack for insertion of a connector of a subcard in the communications device; one end of each signal pin is inserted into the jack, and the other end is connected to each flexible cable. When the communications device provided with the backplane transmits a high-rate signal, transmission quality and a transmission rate are relatively high.

A system is provided herein. The system includes a cage and a handle mechanism. The handle mechanism includes a handle member and a cam member. The handle member is formed to rotate between a closed position, a top open position, and a bottom open position. In the closed position, a handle latch holds the handle in the closed position. In the top open position, the handle rotates a first amount to the top open position and engages with a top cam surface. Rotation of the handle member to rotate a cage a second amount. In the bottom open position, the handle member rotates the first amount to the bottom open position and engages with a bottom cam surface. Rotation of the handle member to rotate the cage the second amount. The cam member to control a rate of rotation of the handle member and the cage.

A cable backplane system includes a backplane having connector openings receiving corresponding cable connectors therein and a cable tray coupled to the backplane. The cable tray has side walls surrounding a cavity defining a raceway for cables interconnecting corresponding cable connectors. A cable connector grid frame supports the cable connectors and the cable connector grid frame is loaded into the cable tray to position the cable connectors and corresponding cables in the cable tray as a unit. The cable connector grid frame includes side rails and center rails held between the side rails and forming a grid of cable connector openings between the side rails and center rails. The cable connector openings receive corresponding headers of the cable connectors and hold the positions of the headers relative to one another.