An insulation displacement arms. The insulation displacement arms define a conductor or wire receiving slot. The insulation displacement arms have insulation stripping sections, weakened sections and base sections. The weakened sections have weakened section widths which are less than insulation stripping section widths of the insulation stripping sections and less than base section widths of the base section. The weakened sections are resiliently deformed upon one or more insulated conductors engaging the insulation stripping sections of the insulation displacement arms as the one or more insulated conductors are inserted into the insulation stripping zone of the wire receiving slot, allowing the insulation displacement contact to accommodate the one or more insulated conductors of the same type and gauge chosen from a broad range of gauges.

A coaxial cable clamping member includes a clamping main body that is capable of clamping a coaxial cable and a pressure contact blade that is fixed to the clamping main body and is capable of being connected to an outer conductor of the coaxial cable. Further, the coaxial cable clamping member includes a grounding portion that is fixed to the clamping main body under a state in which grounding portion is electrically coupled to the pressure contact blade and is capable of grounding the outer conductor of the coaxial cable to a grounded portion. The clamping main body is configured to clamp a plurality of coaxial cables. Under a state in which the clamping main body clamps the plurality of coaxial cables, the outer conductors of all the plurality of coaxial cables clamped by the clamping main body are electrically connected to the grounding portion via the pressure contact blade.

A coaxial cable clamping member includes a clamping main body that is capable of clamping a coaxial cable and a pressure contact blade that is fixed to the clamping main body and is capable of being connected to an outer conductor of the coaxial cable. Further, the coaxial cable clamping member includes a grounding portion that is fixed to the clamping main body under a state in which grounding portion is electrically coupled to the pressure contact blade and is capable of grounding the outer conductor of the coaxial cable to a grounded portion. The clamping main body is configured to clamp a plurality of coaxial cables. Under a state in which the clamping main body clamps the plurality of coaxial cables, the outer conductors of all the plurality of coaxial cables clamped by the clamping main body are electrically connected to the grounding portion via the pressure contact blade.

Disclosed herein is a motor including a power connector capable of preventing current leakage to the outer case and structural interference with the outer case. The motor includes a stator provided with an insulator, a rotor configured to be rotated against the stator, a power connection portion provided in the insulator, and configured to support an end of a coil wound around the stator and configured to accommodate a mag-mate terminal, and a power connector coupled to the power connection portion to connect an external power source to the coil, wherein the power connector includes a lead wire, a fork terminal coupled to an end of the lead wire to electrically connect the lead wire to the coil and a housing configured to accommodate the end of the lead wire and the fork terminal and coupled to the power connection portion.

A terminal holder unit of a wire connecting device includes a terminal accommodation space and a holder-side groove penetrating a wall of a holder base portion of the terminal holder unit in a wire extending direction. A covered electric wire is inserted into the holder-side groove. A press-insert terminal is inserted into the holder-side groove in a terminal insertion direction. A part of an insulating coating portion of the wire is removed, when cutting portions of the press-insert terminal are press-contacted to the wire. A part of a conductive wire portion of the wire is exposed to an outside of the wire, so that the press-insert terminal is electrically connected to the wire. A pair of wire stopper portions is formed in the holder base portion at both sides of the holder-side groove for limiting a movement of the wire in a direction from a wire assembled position to an open end of the holder-side groove.

A terminal holder unit of a wire connecting device includes a terminal accommodation space and a holder-side groove penetrating a wall of a holder base portion of the terminal holder unit in a wire extending direction. A covered electric wire is inserted into the holder-side groove. A press-insert terminal is inserted into the holder-side groove in a terminal insertion direction. A part of an insulating coating portion of the wire is removed, when cutting portions of the press-insert terminal are press-contacted to the wire. A part of a conductive wire portion of the wire is exposed to an outside of the wire, so that the press-insert terminal is electrically connected to the wire. A pair of wire stopper portions is formed in the holder base portion at both sides of the holder-side groove for limiting a movement of the wire in a direction from a wire assembled position to an open end of the holder-side groove.

A wire harness assembly including a first connector, a second connector, and conductors extending between the first connector and the second connector. Contacts are provided on the second connector. The contacts have termination sections which are mounted on the second connector, compliant sections which extend from the termination sections, and substrate engagement sections which extend from the compliant sections. The substrate engagement sections have curved contact sections which are configured to be positioned in mechanical and electrical engagement with circuit pads of a mating printed circuit board. Embossments are provided on the curved contact sections to provide additional strength and stability to the curved contact sections.

A wire harness assembly including a first connector, a second connector, and conductors extending between the first connector and the second connector. Contacts are provided on the second connector. The contacts have termination sections which are mounted on the second connector, compliant sections which extend from the termination sections, and substrate engagement sections which extend from the compliant sections. The substrate engagement sections have curved contact sections which are configured to be positioned in mechanical and electrical engagement with circuit pads of a mating printed circuit board. Embossments are provided on the curved contact sections to provide additional strength and stability to the curved contact sections.

A terminal (1) for connection of an electrical conductor (2) without stripping, having at least one conductor insertion area (13) for inserting an electrical conductor (2), insulated with an insulating material, into the terminal (1) in a conductor insertion direction. The terminal (1) has, for each conductor insertion area (13), an actuating part (50) and an insulation-piercing contact (30) having a cutting edge (33) for cutting through the insulating material and establishing electrical contact with the electrical conductor (2). The cutting edge (33) extends about an axis of rotation along an arc. By rotating the actuating part (50) about the axis the insulation-piercing contact (30) moves between a contacting position, in which the cutting edge (33) intersects the conductor insertion area (13) for establishing electrical contact with an inserted electrical conductor (2), and a release position, in which the cutting edge (33) clears the conductor insertion area.

A terminal (1) for connection of an electrical conductor (2) without stripping, having at least one conductor insertion area (13) for inserting an electrical conductor (2), insulated with an insulating material, into the terminal (1) in a conductor insertion direction. The terminal (1) has, for each conductor insertion area (13), an actuating part (50) and an insulation-piercing contact (30) having a cutting edge (33) for cutting through the insulating material and establishing electrical contact with the electrical conductor (2). The cutting edge (33) extends about an axis of rotation along an arc. By rotating the actuating part (50) about the axis the insulation-piercing contact (30) moves between a contacting position, in which the cutting edge (33) intersects the conductor insertion area (13) for establishing electrical contact with an inserted electrical conductor (2), and a release position, in which the cutting edge (33) clears the conductor insertion area.