An electrical connector comprises an interface element attachable to a circuit board and a plurality of peripheral connectors. The interface element has an inner contact electrically contacting the circuit board and a connecting interface. The peripheral connectors are each individually matable with the connecting interface. The peripheral connectors include a peripheral plug connector having a plurality of plug connector pins and a peripheral lead connector having a plurality of wires.

An inductive sensor includes a core body, a coil wound on the core body, a cavity having a fixed volume within the core body, and an epoxy mixture filling a controlled portion of the fixed volume. The controlled portion of the fixed volume filled with the epoxy mixture controls an inductance of the sensor.

A distributed induction-controlled solar lighting system comprises a first light, second lights and an inductive switch. Each light comprises a first sensor and a sub-controller used for controlling the brightness of the light. The inductive switch is spaced apart from the first light and can trigger the brightness of the first light within its preset range to increase when sensing that a pedestrian or an animal passes by. The first sensor can trigger the brightness of the first light and/or the second light within its range to increase when sensing that a pedestrian or an animal passes by. The solar lighting system can sense a signal in advance when a pedestrian or an animal passes by, such that the situation where the lights will not be turned on or brightness will not be increased until a pedestrian or an animal passes by is avoided; each light has a brightness adjustment function and can adjust the brightness of its own according to a sensing signal of the adjacent lights, a special master controller is not needed, unnecessary lighting power is avoided, and the endurance and reliability of the lights are improved.

A target magnet mechanism for a proximity switch. The target magnet mechanism includes a plurality of magnets disposed in an alternating magnetic pole configuration forming a narrowed, polarity reversing magnetic field. A center magnet has a magnetic polarity opposite the magnetic polarity of a sensing magnet of the proximity switch. A flanking magnet includes a magnetic polarity opposite the magnetic polarity of the center magnet and the same as the sensing magnet. So configured, the plurality of magnets trigger the proximity switch to an activated state by pulling on a magnetic field of the proximity switch via the opposed polarity of the center magnet and the sensing magnet. In addition, the plurality of magnets release the proximity switch back to an unactivated state by pushing on the magnetic field of the proximity switch via the same polarity of the flanking magnet and the sensing magnet.

An inhibitor switch is provided. The inhibitor switch includes a housing having a rotor accommodation space and a Hall element accommodation space, a rotor disposed in the rotor accommodation space, and a magnet disposed on an outer circumferential surface of the rotor. A Hall element is disposed in the Hall element accommodation space and spaced apart horizontally from the magnet with a sensing surface facing an outer circumferential surface of the magnet. Further, the inhibitor switch include a cover configured to block an opening of the rotor accommodation space to prevent the rotor from being released.

A device that will increase an inductive proximity sensor's detection distance and detection position is disclosed. The device uses a housing in combination with a sensor and axially magnetized magnet and a target magnet to achieve the increased detection distance and position. The device can be defined as universal because it allows different manufacturers and sizes of sensors to be used and calibrated. An optional threaded end section of the device allows connection of standard conduit fittings.

A magnetic induction switch has a base; a mounting cavity is arranged in the base; an induction circuit board is arranged in the mounting cavity and a Hall induction element is provided; a rotating cover is rotated on the base and is provided with at least two positioning points on the rotating path; the magnet is provided in the rotating cover, and the position of the magnet relative to the Hall induction element changes during the rotation of the rotating cover so that the induction circuit board generates control signals; the magnetic induction switch of the invention is waterproof, avoids hidden trouble existing in the ignition of the mechanical switch, and has the advantages of simple structure and convenient manufacture.

A switch adapter can include a base having one or more openings, a support coupled to the base, and one or more retainers for coupling a switch to the adapter. The support can have one or more openings between its interior and exterior. The retainer can be adapted to couple to at least one of the base, the support, and a combination thereof. The switch adapter can include one or more switches, such as a replacement switch, and can be adapted for replacing a limit switch with a proximity switch. A proximity switch can be coupled to a switch adapter in one or more positions, and a switch adapter can be adapted to couple with a plurality of different switch mounts. A switch adapter can include a mass compensator for adjusting its center of gravity.

A front end for an inductive proximity sensor includes a coil for detecting an approaching metal object and a circuit board, wherein the coil is designed as a circuit board coil disposed in the circuit board, wherein a metal influencing element which is disposed in or on the circuit board has an opening to receive at least one electrical connecting element, wherein a through connection of the circuit board to an electrical connection plane, which serves for electrical connection of the circuit board to a control electronics of the proximity sensor, is made by the at least one electrical connecting element.

The present disclosure relates to a proximity sensor for detecting the proximity of an object, the sensor including a sensing element (11), a detection circuitry (65), and a housing (5), the sensing element (11) being arranged in a front portion (21) of the housing (5) such that it is adapted to interact with the object through the front portion (21) and the detection circuitry being interconnected with the sensing element (11) in order to receive a detection signal from the sensing element (11), wherein the detection circuitry (65) is provided on a circuit board (15, 15A, 15B, 15C) extending at least through a middle portion (22) of the housing (5). To allow a better flexibility of the sensor along its length expansion, it is proposed that the housing (5) includes multiple segments (41, 42, 43, 44) that are consecutively arranged in a longitudinal direction (27) from a rear end (56) toward a front end (55) of the housing (5), wherein neighboring segments of said segments (41, 42, 43, 44) are linked to each other via a respective pivot axis (35, 39, 40) extending transversely with respect to said longitudinal direction (27), such that the housing (5) is bendable around each of said pivot axes (35, 39, 40), wherein both of said front portion (21) and said middle portion (22) each includes at least one of said segments (41, 42, 43, 44), and wherein the circuit board (15, 15A, 15B, 15C) includes at least one bendable section (61, 75, 76, 77, 85, 86) extending transversely with respect to said longitudinal direction (27), said bendable section (61, 75, 76, 77, 85, 86) being provided inside said neighboring segments (41, 42, 43, 44).