A connection structure of a cable and a terminal, the connection structure includes a cable including a core wire exposed from an insulating sheath, and a terminal including a base plate and at least a pair of elastic connection pieces formed to be capable of being cut-raised in the base plate, the at least a pair of elastic connection pieces each having a cable insertion hole formed therein. At least the core wire of the cable is pressed against and electrically connected to the base plate by elastic restoring force of each of the at least a pair of elastic connection pieces in a state in which at least the core wire of the cable is inserted in the cable insertion hole formed in each of the at least a pair of elastic connection pieces.

A tool device is disclosed for generating a curved terminal from an insulation stripped end of an electrical wire. The tool device includes a first member having a first and a second end the first member having a longitudinal axis. A second member is disposed adjacent to the first member, the second member having a first and a second extremity. The second member defines a further longitudinal axis which is disposed substantially parallel to and spaced from the longitudinal axis of the first member. The arrangement is such that a space is defined between the first member and the second member for the reception therein of the insulation stripped end of the electrical wire. The curved terminal is generated during relative movement of the axes around the insulation stripped end of the electrical wire.

A method of transporting grounding plates is provided, having a step of providing a plurality of grounding plates made from an electrically conductive material. Each grounding plate has a plate body with first and second faces that are planar, opposed, and parallel to each other, and a grounding connector formed from the same material and having a first end connected to the plate body. The grounding connector is bendable about the first end from a planar configuration to a functional configuration. In the planar configuration, the grounding connector is aligned with and parallel to the first and second faces of the plate body, and in the functional configuration, the grounding connector is at an angle relative to the first face of the plate body. The method has the further steps of stacking the plurality of grounding plates in the planar configuration and transporting the stack to a destination.

A method of transporting grounding plates is provided, having a step of providing a plurality of grounding plates made from an electrically conductive material. Each grounding plate has a plate body with first and second faces that are planar, opposed, and parallel to each other, and a grounding connector formed from the same material and having a first end connected to the plate body. The grounding connector is bendable about the first end from a planar configuration to a functional configuration. In the planar configuration, the grounding connector is aligned with and parallel to the first and second faces of the plate body, and in the functional configuration, the grounding connector is at an angle relative to the first face of the plate body. The method has the further steps of stacking the plurality of grounding plates in the planar configuration and transporting the stack to a destination.

A connection structure of an electric wire and a terminal includes a terminal formed by folding back a base plate to form a body part and an elastic connection piece, and an electric wire having a core wire exposed from an insulation sheath. The elastic connection piece includes a first elastic connection part adjacent to a folded-back portion of the base plate and a second elastic connection part continuing to the first elastic connection part in the longitudinal direction of the base plate. An electric wire insertion hole is formed on each of the elastic connection parts. The core wire is sandwiched and connected by the elastic connection piece and the body part at a position between the first elastic connection part and the second elastic connection part at a state where the core wire is inserted through the wire insertion holes in the longitudinal direction of the base plate.

A connection structure of an electric wire and a terminal includes a terminal formed by folding back a base plate to form a body part and an elastic connection piece, and an electric wire having a core wire exposed from an insulation sheath. The elastic connection piece includes a first elastic connection part adjacent to a folded-back portion of the base plate and a second elastic connection part continuing to the first elastic connection part in the longitudinal direction of the base plate. An electric wire insertion hole is formed on each of the elastic connection parts. The core wire is sandwiched and connected by the elastic connection piece and the body part at a position between the first elastic connection part and the second elastic connection part at a state where the core wire is inserted through the wire insertion holes in the longitudinal direction of the base plate.

An electromagnetic terminal shield includes a shield body formed of sheet metal having a connector opening configured to receive a corresponding mating terminal shield and a cable opening configured to receive a wire cable. The terminal shield also includes a plurality of cantilevered spring arms integrally formed with the shield body having fixed ends attached to the connector opening and free ends disposed within a shield cavity defined by the shield body. A process for manufacturing the electromagnetic terminal shield is also presented.

An electromagnetic terminal shield includes a shield body formed of sheet metal having a connector opening configured to receive a corresponding mating terminal shield and a cable opening configured to receive a wire cable. The terminal shield also includes a plurality of cantilevered spring arms integrally formed with the shield body having fixed ends attached to the connector opening and free ends disposed within a shield cavity defined by the shield body. A process for manufacturing the electromagnetic terminal shield is also presented.

A connection structure of an electric wire and a terminal includes a terminal formed by folding back a base plate to form a body part and an elastic connection piece, and an electric wire having a core wire exposed from an insulation sheath. The elastic connection piece includes a first elastic connection part adjacent to a folded-back portion of the base plate and a second elastic connection part continuing to the first elastic connection part in the longitudinal direction of the base plate. An electric wire insertion hole is formed on each of the elastic connection parts. The core wire is sandwiched and connected by the elastic connection piece and the body part at a position between the first elastic connection part and the second elastic connection part at a state where the core wire is inserted through the wire insertion holes in the longitudinal direction of the base plate.

A connection structure of an electric wire and a terminal includes a terminal formed by folding back a base plate to form a body part and an elastic connection piece, and an electric wire having a core wire exposed from an insulation sheath. The elastic connection piece includes a first elastic connection part adjacent to a folded-back portion of the base plate and a second elastic connection part continuing to the first elastic connection part in the longitudinal direction of the base plate. An electric wire insertion hole is formed on each of the elastic connection parts. The core wire is sandwiched and connected by the elastic connection piece and the body part at a position between the first elastic connection part and the second elastic connection part at a state where the core wire is inserted through the wire insertion holes in the longitudinal direction of the base plate.