The present application discloses an axial diode junction box and a method for manufacturing the same, comprising an axial diode and a junction box body, wherein the axial diode is mounted inside the junction box body; the axial diode comprises a diode body, a first pin, and a second pin, one end of the diode body is connected to the first pin, the other end of the diode body is connected to the second pin, and a direction where the diode body is close to the junction box body is defined as a front direction; the first pin comprises a first connection portion and a first flat portion, one end of the first connection portion is connected to one end of the diode body, and the other end of the first connection portion is connected to the first flat portion; the second pin comprises a second connection portion and a second flat portion, one end of the second connection portion is connected to the other end of the diode body, and the other end of the second connection portion is connected to the second flat portion; and the diode body is clamped to the junction box body. The present application can simplify a production process, reduce a product cost, improve the product reliability, and improve the production efficiency of a production line.

Connector assembly for electrically connecting an inverter busbar to an electrical connector of a drive unit comprising: a carrier, an intermediate busbar comprising a first terminal with a hole, and a first fastening element extending through the hole of the first terminal, wherein the intermediate busbar is mounted to the carrier and the intermediate busbar is connectable to the inverter busbar by the first fastening element, wherein the carrier comprises a positioning pin defining a longitudinal axis, said positioning pin being adapted to be accommodated in a receptacle of a housing of the drive unit such that the carrier is axially slidable in the direction of the longitudinal axis; and that the first fastening element is arranged within the hole of the first terminal with a radial clearance relative to the longitudinal axis of the positioning pin.

An input/output device includes a terminal base to be mounted to a structure. A terminal block is connected to the terminal base and includes wiring terminals to be connected to I/O field wiring. A latch body is connected to the terminal block. The latch body is manually movable between an unlatched position and a latched position. An input/output module is connected to the terminal base adjacent the terminal block and includes a locking tab. The latch body, when in the latched position, engages the locking tab and captures the input/output module to the terminal block. The terminal block includes first and second module retaining rails or projections that engage respective slots of the input/output module to restrain the module relative to the terminal base. The terminal base includes first and second notches that receive inner ends of the first and second module retaining projections to rigidify the terminal base.

Provided is a socket capable of efficiently and easily connecting an external wiring connection terminal and an electrical device terminal connection terminal and reducing manufacturing cost and the number of steps. The socket includes an external wiring connection terminal which is connected to an external wiring and an electrical device terminal connection terminal which is connected to an electrical device terminal. The external wiring connection terminal and the electrical device terminal connection terminal are electrically connected by a bar-shaped wire of which a shape is fixed to a predetermined shape.

A terminal block for coupling with at least one conductive wire includes an insulation base (100) and a circuit board (200). A docking chamber (101) is defined in the insulation base (100), multiple connecting holes (102) for inserting the respective conductive wires and multiple through holes (103) corresponding to the respective connecting holes (102) are defined on a lateral surface of the insulation base (100). The respective through holes (103) are communicated with the docking chamber (101) and adjacent to the respective corresponding connecting holes (102). The circuit board (200) is arranged in the docking chamber (101), and multiple LEDs (210) are arranged on the circuit board (200) corresponding to the respective through holes (103). The LEDs (210) are accommodated in the docking chamber (101), and the respective LEDs (210) are able to illuminate through the respective corresponding through holes (103).

An easy assembly control panel and method is disclosed. In one example, an enclosure is provided having a pilot device coupled to the enclosure. A pre-assembled control panel is inserted into the enclosure, quick coupling the control panel to the pilot device and providing control communication between the pilot device and the control panel. No additional manual wiring or manual mechanical coupling is needed to couple the user interface device to the control panel. The control panel can be used as part of a system, such as a submersible pump system.

A power panel and modules for use in a power panel are disclosed. One disclosed chassis includes a top, a bottom, a front, a rear, and left and right sides, and an input power bus having a plurality of connection apertures therethrough. A plurality of circuit modules are mounted within the chassis. Each circuit module includes a circuit protection element including first and second bullet-nosed connectors, and a body element having first and second holes positioned to receive the first and second bullet-nosed connectors. The body element includes a bullet-nosed input connector sized to be received by one of the plurality of connection apertures. Each circuit element also includes an output terminal extending rearwardly from the body element.

An electrical connection terminal between two conductive elements includes at least one tightening screw, including a head and a thread, a stirrup, mounted around each screw, between the head and the thread of the screw, and a connector for each screw. Each connector includes a first stage, delimiting a tapping for receiving the tightening screw, and a second stage, arranged between the first stage and the stirrup and including a hole for passage of the screw, aligned with the tapping, the first stage being mobile relative to the second stage parallel to an axis of the screw. The terminal also includes a recess for receiving a first conductive element between the two stages of the connector, and a recess for receiving a second conductive element between the stirrup and the connector.

The invention concerns a function component upper part (500) for placing on a function component lower part (401) of a function component (400), having a first interface for electrically connecting the function component lower part (401) of the function component (400), and a second interface for electrically 409 connecting a housing upper part (403) of the function component (400).

The terminal block includes a movable operation feeling generating member (60) which generates an operation feeling according insertion of a conductor portion into an accommodating portion (12) from a first opening portion (111), and a first protruding portion (63) disposed in the accommodating portion to be capable of coming into contact with the movable operation feeling generating member being rotated by the insertion of the conductor portion into the accommodating portion from the first opening portion after the conductor portion and a terminal electrode portion (20) are changed from the non-connected state to the connected state. The movable operation feeling generating member includes a first contact portion (61) capable of coming into contact with the conductor portion inserted into the accommodating portion, and a second contact portion (62) which has a second protruding portion (70) generating the operation feeling by coming into contact with the first protruding portion (63).