A socket contact (1) has a hollow cylindrical contact wire region (AB) for receiving a stripped end portion of an electrical conductor to be connected, and a hollow cylindrical contact region (KB) with a pin insertion opening (2) for receiving a contact pin. The contact region (KB) has a cylinder wall with at least one radially inwardly folded contact blade (4), the free end of which points towards the pin insertion opening (2). The cylinder wall has an at least partially circumferential groove (5) for the contact blade in the region of the fold.

An electrical contact element (1) for transmitting high currents has a connection region (A) and a contact region (K). The connection region (A) has a cylindrical opening (2) and the contact region (K) has a cylindrical passage opening (3). The opening (2) and the passage opening (3) are oriented orthogonally relative to each other and a peripheral contact strip (4) is arranged within the cylindrical passage opening (3).

The present invention relates to a cable arrangement comprising a cable that has an outer conductor, and an outer-conductor contact element that is electrically connected to the outer conductor and has a diameter change. In a region of the diameter change, the cable arrangement also has a filling element, which is electrically conductive. The filling element is configured to reduce an air inclusion in the region of the diameter change.

A method of manufacturing a terminal-equipped electrical wire includes: inserting a core-wire exposed part of a core wire of an electrical wire at a terminal between inner wall surfaces of a pair of piece parts of a terminal fitting including a core-wire connection body formed of a bottom part and the piece parts protruding from both ends of the bottom part, and placing the core-wire exposed part on an inner wall surface of the bottom part; melting the core-wire exposed part and the core-wire connection body by emitting a laser beam to the core-wire exposed part and the core-wire connection body from a free end side of each piece part; and fixing the core-wire exposed part and the core-wire connection body melted by the laser beam, with the emission of the laser beam stopped.

A terminal-equipped electric wire includes a terminal and a coated conductive wire, which are electrically connected to each other. A crimp part of the terminal is crimped to the coated conductive wire, and has a conductive wire crimp part, which is crimped to a conductive wire that is exposed from a coating on the front-end side of the coated conductive wire, and a coating crimp part, which is crimped to the coating of the coated conductive wire. On the front-end side (terminal body side) of the conductive wire crimp part, an electric wire holding part, which applies a relatively strong holding force on the conductive wire, is provided, On the rear-end side (coating crimp part side) of the conductive wire crimp part, a conductive part for achieving conduction with the conductive wire is formed.

An electrical device having a stranded wire contact. The device includes a stranded wire with individual wires and a contact piece for electrical contacting of the stranded wire. The stranded wire contact is produced by thermal diffusion bonding.

The present invention prevents a cover from being incorrectly installed with respect to an external conductor. This shielded terminal is provided with: an external conductor (20) that has a connection space (28) which is between a pair of side walls (26), and which is open to the outside via a first opening (31) and a second opening (32); a shielded electric cable (70) that is connected to the external conductor (20); an internal conductor (11) that is housed in the external conductor (20) and that is connected to a core wire (71) of the shielded electric cable (70) in the connection space (28); and a cover (50) that is installed inside the connection space (28) from the first opening (31) and that surrounds the part at which the core wire (71) and the internal conductor (11) are connected, wherein an interference part (34) that interferes with the cover (50) is formed on the opening edge part of the second opening (32).

A glass plate module according to the present invention is a glass plate module to which a wire for supplying electric power is capable of being joined and includes a glass plate, a heating wire disposed on the glass plate, and an electricity supply portion that is disposed on the glass plate and supplies electric power to the heating wire. The electricity supply portion is formed using conductive print that contains, as a main component, metal microparticles whose thermal expansion coefficient is larger than that of the glass plate, and the electricity supply portion is thinner than the heating wire.

A connector includes a housing, a terminal, and an electric wire line. The housing is fittable to a mating housing that houses a mating terminal. The terminal is housed in the housing, and includes a tubular electric connection portion into which the mating terminal is inserted. The electric wire line includes at least a terminal end portion housed in the housing, and is electrically connected to the terminal. In the connector, the electric connection portion houses a multi-contact coil spring that is formed to have an elastically-deformable annular shape, is electrically connected to the electric connection portion, and is brought into contact at a plurality positions with the mating terminal inserted thereinto, and the terminal and at least the terminal end portion of the electric wire line are insert-molded in the housing.

An electrical terminal for coupling to a conductive structure includes a body having a wire receiving portion for receiving a conductor. A cup portion is electrically coupled with the wire receiving portion and a boss portion extends from the cup portion. An overmold structure of insulation material is formed on the cup portion and covers the cup portion sides. An aperture is formed in the body and extends through the cup portion and the boss portion for receiving a post of the conductive structure for securing the terminal to the conductive structure. A fastener is configured for engaging a post and securing the boss portion against the conductive structure. The boss portion is configured to surround the aperture for providing an electrically conductive surface free from insulation material for interfacing with the conductive structure. The fastener and post are contained in the cup portion and an insulative cap is configured for engaging the overmold structure and sealing the cup structure around the fastener and post of a conductive structure.