An electronic device including a plurality of ports for electrically connecting the device to another device. The electronic device may include a housing including a front, a back and at least a first side and an opposing second side extending between the front and the back, a printed circuit board housed by the housing, and an electrical connector electrically connected to the printed circuit board. The electrical connector may include a first spring contact, a second spring contact, and an electrically conductive bridge mechanically and electrically connecting the first spring contact and the second spring contact. The electrically conductive bridge may be housed by the housing. The first and second spring contacts may extend outside of the housing and may be accessible from the first and second sides of the housing, respectively.

A device includes a housing including a rail mount and a stopper to lock an engagement flange (RAb) on a DIN rail (RA) with the rail mount receiving the DIN rail (RA), a locking member to be at a locking position to lock an engagement flange (RAb) on the DIN rail (RA) and at a release position to unlock the engagement flange (RAb) with the rail mount receiving the DIN rail (RA), a release button including a pressing portion to be pressed by a user and located in the housing with the pressing portion exposed outside the housing, and an arm to move the locking member from the locking position to the release position in response to movement of the release button from a standby position to a pressed position deeper in the housing than the standby position.

A mounting enclosure assembly is configured to mount electronic components onto a DIN rail. The mounting enclosure assembly includes a mounting bracket including a body having at least one elongate slot configured to receive an edge of the electronic component therein. The mounting enclosure assembly further includes a heat sink secured to the mounting bracket. The heat sink includes a mounting configuration configured to secure the heat sink and the mounting bracket to the DIN rail. The mounting enclosure assembly further includes a thermal bonding material disposed within the slot to secure the electronic component to the body of the mounting bracket within the slot. Other embodiments of the mounting enclosure assembly are further disclosed.

A mounting enclosure assembly is configured to mount electronic components onto a DIN rail. The mounting enclosure assembly includes a mounting bracket including a body having at least one elongate slot configured to receive an edge of the electronic component therein. The mounting enclosure assembly further includes a heat sink secured to the mounting bracket. The heat sink includes a mounting configuration configured to secure the heat sink and the mounting bracket to the DIN rail. The mounting enclosure assembly further includes a thermal bonding material disposed within the slot to secure the electronic component to the body of the mounting bracket within the slot. Other embodiments of the mounting enclosure assembly are further disclosed.

The present disclosure provides a chassis and an electronic device applying the chassis. The chassis includes: a chassis body; the chassis body is a 2U chassis body or a 4U chassis body; a hard disk module, installed in a front end area of the chassis body; a power supply module, installed at one side of a rear end area of the chassis body; a controller module, installed in a remaining rear end area of the chassis body except the power supply module, parallel with the power supply module, and including a plurality of pluggable functional modules; a middle board, connected with the power supply module, the hard disk module, and the control module, respectively, to realize the electrical connection between the power supply module, the hard disk module, and the control module. The present disclosure can improve the versatility of the chassis modules.

An electronic device including a plurality of ports for electrically connecting the device to another device. The electronic device may include a housing including a front, a back and at least a first side and an opposing second side extending between the front and the back, a printed circuit board housed by the housing, and an electrical connector electrically connected to the printed circuit board. The electrical connector may include a first spring contact, a second spring contact, and an electrically conductive bridge mechanically and electrically connecting the first spring contact and the second spring contact. The electrically conductive bridge may be housed by the housing. The first and second spring contacts may extend outside of the housing and may be accessible from the first and second sides of the housing, respectively.

A retention mechanism for attaching equipment to a mounting rail comprises a slider including a first retention section and a pivoting lever mechanical coupled to the slider. The slider is movable in a translational manner along a sliding direction with respect to a remaining portion of the retention mechanism. The lever includes a second retention section aligned with the first retention section in the sliding direction. A reception area for receiving the mounting rail is defined between the first retention section and the second retention section.

An I/O system including an I/O base having a first connector component, an I/O module selectively attachable to the I/O base and having a second connector component adapted to mate with the first connector component, and a locking actuator assembly for securing the I/O module to the I/O base. The locking actuator assembly includes an actuator supported for axial and rotational movement by the I/O module, the actuator movable from an unlocked position having a first end of the actuator extending from a housing of the I/O module to a locked position wherein a second end of the actuator extends from the housing. The second end of the actuator includes a flange adapted to pass through a corresponding slot in a surface of the I/O base such that when the actuator is rotated the at least one flange restricts withdrawal of the actuator from the slot in the I/O base.

A bus device of a terminal block includes a case and a latch assembly. The case has a connecting side and is formed with a sliding trough. The latch assembly includes an actuator and a locking peg. The actuator is disposed in the sliding trough and movable along the sliding trough between a release position and a locking position. The actuator has an actuating ramp set. The locking peg is axial-rotatably disposed in the case and arranged corresponding to an end of the sliding trough. An end of the locking peg projects from the connecting side and has an inverted hook. The locking peg has a protrusive key abutting against the actuating ramp set. When the actuator moves between the release position and the locking position, the actuating ramp set is configured to push the protrusive key to axially rotate the locking peg.

A carrier-rail bus assembly including a number of n mechanically contiguous bus-circuit-plate sections electrically connected via bus-circuit paths and installed in a carrier rail, an electronic control unit being configured such that it detects whether an apparatus is inserted in an installation position i, respective installation position i being allotted a bus address, which is assigned to the apparatus inserted on the carrier rail on the respective bus-circuit-plate section in respective installation position i. A related method for assigning a bus address is also disclosed.