In a terminal connection method of inserting a wire tip of an insulated wire, which is formed by stripping a front end of an insulating cover to expose an aluminum core wire, into a pressure-bonding section of a female crimp terminal to pressure bond the insulated wire to the female crimp terminal via the pressure-bonding section, signs are formed on the outer circumferential face of an insulated tip of the insulating cover at a distance of an internal length of the pressure-bonding section from a conductor tip face of the conductor tip, and the wire tip is inserted up to the signs in the pressure-bonding section to pressure-bond the wire tip to the pressure-bonding section.

An arc-resistant electrical terminal includes a mount portion and a wire receiving portion formed of an electrically conductive material. The wire receiving portion is configured to be crimped onto a wire. The mount portion includes a solid tongue having opposing face surfaces. An aperture is formed between the opposing face surfaces for connecting the terminal to a connection point. A layer of insulation material is formed on at least a portion of the tongue for preventing arcing at a connection point. A raised boss is formed to surround the aperture on at least one of the opposing face surfaces of the tongue, the raised boss providing an electrically conductive surface of the terminal free from the layer of insulation material for connection to a connection point.

A method for manufacturing a crimp terminal having a crimp portion that allows crimp connection to a conductor part of a coated wire includes forming a tubular body by bringing together side edges of a plate material made of metal composed of a copper alloy having a copper content ratio of greater than or equal to 70%, irradiating a periphery of the sides edges, which are brought together, with laser light from a laser irradiation unit to weld the side edges which are brought together, and setting a power density of the laser light and a sweep rate of the laser light in such a manner that a weld bead formed at the side edge portion after the welding has a width of 80 m to 390 m.

A telecommunications connector (100) includes a connector body (104) and a shield (102) attached to the connector body, the shield including a main body portion configured for attachment to the connector body and a barrel portion (110) for crimping against a cable to be terminated to the connector. The barrel portion of the shield includes a corrugated side wall made up of a series of bends extending along a direction from the rear end of the barrel toward the front end of the barrel along at least a portion of a length of the barrel, wherein the bends defining the corrugated side wall are provided on the shield at a pre-crimped stage.

A connection terminal has a connector body having a mating end and an opposite cable receiving end; a pair of contact arms extending from the mating end; and a cable receiving member having an approximate cylindrical shape with a variable diameter, and extending from the cable receiving end.

An inner-conductor contact element for an angled connector has a crimp region which is designed to be connectable to an inner conductor of a cable, and an interface region which is designed to be connectable to an inner-conductor contact element of a counterpart connector corresponding to the angled connector. The inner-conductor contact element also has a connection region which connects the crimp region to the interface region. The inner-conductor contact element is formed in one piece. The connection region has a first transverse extent and a second transverse extent which is smaller, preferably many times smaller, than the first transverse extent. The connection region has an angular shape in a plane formed by the first transverse extent and a longitudinal extent of the connection region.