A connector comprises a housing including an upper casing defining an aperture through which a wire is adapted to extend, and a lower casing defining a chamber receiving the upper casing. The chamber defines an opening that opens toward the upper casing. The upper casing is movable relative to the lower casing upon the exerting of a force on the upper casing such that the aperture and the opening at least partially overlap. A conductive terminal is disposed in the chamber of the lower casing and is adapted to tear an outer insulation of the wire arranged within the chamber to electrically connect to a conductor of the wire as the upper casing is moved toward the lower casing.

The invention relates to a contact for a direct plug-in connector having two strips made of sheet-metal material that are arranged next to one another in an insertion portion and in a contact portion, wherein the insertion portion is provided for insertion into a through-opening, which is electrically conductive at its inner wall, in a printed circuit board and the contact portion is provided to make electrical contact with the inner wall of the through-opening, wherein the two strips are connected together in a connection portion that is provided for connecting to a cable strand, and wherein a connecting portion is located between the connection portion and the contact portion, wherein the two strips are located in a common plane and formed in an L-shaped manner in the connecting portion, wherein the legs of the connecting portion that proceed from the connection portion extend parallel to one another and the legs of the connecting portion that are connected to the contact portion extend towards one another.

The invention relates to a contact for a direct plug-in connector having two strips made of sheet-metal material that are arranged next to one another in an insertion portion and in a contact portion, wherein the insertion portion is provided for insertion into a through-opening, which is electrically conductive at its inner wall, in a printed circuit board and the contact portion is provided to make electrical contact with the inner wall of the through-opening, wherein the two strips are connected together in a connection portion that is provided for connecting to a cable strand, and wherein a connecting portion is located between the connection portion and the contact portion, wherein the two strips are located in a common plane and formed in an L-shaped manner in the connecting portion, wherein the legs of the connecting portion that proceed from the connection portion extend parallel to one another and the legs of the connecting portion that are connected to the contact portion extend towards one another.

An insulation displacement contact (IDC) cluster includes a plurality of IDC cluster modular units each having a plurality of receptacles adjacent to one another in a row. Each of the receptacles receives an IDC terminal. A first IDC cluster modular unit of the IDC cluster modular units is coupled to a second IDC cluster modular unit of the IDC cluster modular units to form a modular structure by stacking and fastening together, arranging the receptacles of the IDC cluster modular units in parallel rows.

A strain relief system for a cable inserted within has a main housing with an opening and a series of ramp features and a series of serrations on an interior surface. The system also has a rotating collar with an opening in line with the opening of the main housing. The rotating collar having a series of follower features configured to be inserted into the opening of the main housing such that when the rotating collar is rotated relative to the main housing, the follower features engage the ramp features to compress the cable inserted with the strain relief system. The rotating collar also having at least one ratcheting tab configured to engage the series of serrations of the main housing such has to provide a ratcheting function between the rotating collar and the outer housing.

A terminal-equipped electric wire includes an electric wire in which a core wire including a plurality of strands is covered with a covering, and a terminal fitting attached to the electric wire. The terminal fitting includes a core wire connection body physically and electrically connected to the core wire. The core wire connection body has a bottom, a pair of cantilever side walls erected from the bottom and arranged facing each other with a space therebetween, and at least one set of paired pressure contact bodies arranged facing each other with a space therebetween between the pair of side walls so as to come into pressure contact with the strands in an outermost layer of the core wire.

A strain relief system for a cable inserted within has a main housing with an opening and a series of ramp features and a series of serrations on an interior surface. The system also has a rotating collar with an opening in line with the opening of the main housing. The rotating collar having a series of follower features configured to be inserted into the opening of the main housing such that when the roating collar is rotated relative to the main housing, the follower features engage the ramp features to compress the cable inserted with the strain relief system. The rotating collar also having at least one ratcheting tab configured to engage the series of serrations of the main housing such has to provide a ratcheting function between the rotating collar and the outer housing.

A terminal-equipped electric wire includes an electric wire in which a core wire including a plurality of strands is covered with a covering, and a terminal fitting attached to the electric wire. The terminal fitting includes a core wire connection body physically and electrically connected to the core wire. The core wire connection body has a bottom, a pair of cantilever side walls erected from the bottom and arranged facing each other with a space therebetween, and at least one set of paired pressure contact bodies arranged facing each other with a space therebetween between the pair of side walls so as to come into pressure contact with the strands in an outermost layer of the core wire.

A contact includes a base portion, a cold-weld portion extending upward from the base portion and having a cold-weld slot into which an electric wire is configured to be cold-welded, a trailing portion extending downward by being folded back downward from an upper end of the cold-weld portion, and a contact portion extending from a lower end of the trailing portion. The trailing portion has a press-fitted portion below the cold-weld slot that is press-fitted into the housing. The contact portion makes contact with a mating contact by receiving the mating contact in a space between the contact portion and the base portion.

A contact includes a base portion, a cold-weld portion extending upward from the base portion and having a cold-weld slot into which an electric wire is configured to be cold-welded, a trailing portion extending downward by being folded back downward from an upper end of the cold-weld portion, and a contact portion extending from a lower end of the trailing portion. The trailing portion has a press-fitted portion below the cold-weld slot that is press-fitted into the housing. The contact portion makes contact with a mating contact by receiving the mating contact in a space between the contact portion and the base portion.