A spring clamp for plugging onto an electrical conductor of an electric machine, having a first spring leg and a second spring leg adjoining the first spring leg. The spring legs are arranged and/or formed with respect to one another in such a way that a receiving opening for receiving the electrical conductor is formed between a free first end portion of the first spring leg and a free second end portion of the second spring leg, and the conductor is clamped between the first end portion and the second end portion. The second spring leg has a sensor holder and a spring arm with a press-on tab, a spring force is exerted by way of the spring arm such that a sensor arranged in the sensor holder is fixed in the sensor holder by way of the press-on tab, and the sensor holder is pressed onto the electrical conductor.

A cable retainer insert for a multi-strand cable includes a cable contact portion and a plurality of cable receptacles in the cable contact portion circumferentially spaced from each other. Each of the cable receptacles receives a strand of the multi-strand cable. Each of the cable receptacles has a cable strand insertion opening at a radially outward end and a bottom at an opposite radially inward end. A circle inscribed in each of the cable receptacles and touching the bottom of the cable receptacle extends radially outward beyond the cable strand insertion opening.

An electrical feedthrough (1) is provided for improving the thermal properties and the electromagnetic compatibility (EMC) and also for simplified production of a medical instrument (7), in which electrical feedthrough individual contact pins (4), which are guided through a glass body (2) in a housing (20) of the instrument (7), are electrically connected to one another by a pluggable plug element (5), preferably in the form of a sheet metal part. Here, the plug element (5) firstly provides high thermal and electrical conductivity and secondly provides a shielding area that effectively prevents the input coupling of electromagnetic radiation. Preferably, the plug element (5) is formed in such a way that it independently develops a holding force for securing itself to the contact pins (4).

An electrical element holder includes a printed circuit board having a receiver. A resilient holder is electrically engaged with the receiver. The resilient holder includes a holding portion that is defined within an outward surface of the resilient holder and between opposing resilient arms. An electrical element is secured within the holding portion between the opposing resilient arms.

An earth wire holder for a cable tray having two spaced-apart side bars, wherein the earth wire holder is in the form of a spring clamp having a side bar receptacle enclosed by two mounting arms for connecting the spring clamp to the upper edge of a side bar and having an undercut earth wire receptacle enclosed by two holding arms, wherein, when the spring clamp is mounted on the upper edge of the side bar, the mounting arms bear against the side bar under prestress, and the spacing between the holding arms in the section thereof enclosing the earth wire receptacle is smaller than the diameter of the earth wire to be introduced therein.

A battery module connector for electrically conductive connecting of two battery modules includes a first contact element for electrically conductive contacting of a first battery module, a second contact element for electrically conductive contacting of a second battery module, a band-shaped wire braid that is electrically conductively connected at a first end to the first contact element and at a second end to the second contact element, and at least one spring element that is inserted into a section of the wire braid between the first end and the second end, and is configured to impinge the section with a spring force such that the section is widened radially with respect to a longitudinal axis of the wire braid.

A light cap electrical connection structure includes a driving board, a light cap body and a first electrode pin. The light cap body is a shell structure. One end of the first electrode pin is fixed on the light cap body and further including a socket. The socket is set on the driving board and includes a connection base and a first electrode. The first electrode is set on the connecting base and has a fixed end and a connecting end. The connecting end of the first electrode is an elastic structure. The other end of the first electrode pin is inserted into the light cap body and becomes an electrical connection in elastic contact with the connecting end of the first electrode. The light cap electrical connection structure has advantages of a simple structure and being easy to automate.

A socket has a housing, which is composed of an electrically insulating material and an elongate plug-receiving region. A contact spring is arranged in the plug-receiving region. A lever loads the contact spring in the open position of the lever such that a dimension of the contact spring transverse to the longitudinal direction of the plug-receiving region is reduced and relaxes the contact spring in the closed position of the lever. A plug is provided for such a socket.

A shielded in-line connector includes conductive first and second body portions, each with a securement feature, as well as conductive first and second clips. The first and second body portions are secured to one another to define an unshielded connector-receiving cavity as well as first and second shielded cable openings; each of the first and second shielded cable openings being proximate the respective clip securement feature. Each of the clip securement features includes a channel supportive of a respective shielded cable extending from each of the first and second shielded cable openings; each of the shielded cables having an exposed shield. The first and second clips are adjustably secured to a respective one of the first and second securement features to position the respective clip in direct contact with the exposed shield of the respective shielded cable.

The present disclosure provides descriptions of configurations for wire connectors used to splice low voltage electrical conductors or to splice high voltage electrical conductors. The wire connectors may be coupled to form a wire connector assembly. Each wire connector includes a base, a cover, a first cover coupling assembly and a second first cover coupling assembly. The base has an upper wall and a lower wall and can be divided into a first end portion, a second end portion and a central portion between the first end portion and the second end portion. The cover has a main cover member, a first movable cover member movably connected to a first side of the main cover member and a second movable cover member movably connected to a second side of the main cover member. The main cover member includes a plurality of contact chambers, where each contact chamber includes at least one electrical contact positioned within a cavity of the contact chamber. The first cover coupling assembly is associated with the first end portion of the base and the first movable cover member of the cover. The second cover coupling assembly is associated with the second end portion of the base and the second movable cover member of the cover. The cover assemblies are used to releasably couple the movable cover members to the base.