A core-wire exposed portion in an electric wire and at least one pair of pressure-welding pieces made of an electroconductive material are included. The core-wire exposed portion is a portion is which a core wire composed of a plurality of element wires is exposed. The pair of pressure-welding pieces are provided with a core wire pressure-welding section in which pressure-welding end surfaces are disposed facing each other at a distance and Kate the core-wire exposed portion press-fitted between the pressure-welding end surfaces. The core wire pressure-welding section is formed as a section that brings all of the element wires in the core-wire exposed portion, between the pressure-welding end surfaces, into contact with either of the pressure-welding end surfaces while being in an aligned state.

An electrical connector and associated terminal are disclosed for making an electrical connection to a wire. The terminal includes a plurality of metal plates adjoining each other to form a stack that defines a passage for receiving the wire. The plates include a plurality of cutter plates disposed between a pair of outer holding plates. Each of the cutter plates has a pair of cutting edges for disrupting any insulation on the wire to permit a conductor of the wire to directly contact the cutter plate. One or more of the cutter plates may have a contact projection for making an electrical connection. The connector includes the terminal and may further include a housing. The holding plates of the terminal have outer edges with abutment features for engaging interior surfaces of the housing.

Provided is a connector capable of enhancing contact reliability between a cable and a contact by improving press-contact accuracy of the cable by the contact. The connector (10) configured to clamp a core wire of a cable by a press-contact portion includes: a pair of fitting objects fitted to each other; a contact (50) provided in the fitting objects and having a pair of press-contact portions; a first partition wall (18b1) formed in one of the fitting objects; and a second partition wall (33) formed in another one of the fitting objects, in which a pair of press-contact portions of the contact (50) are spaced apart from each other and are separated by the first partition wall (18b1) and the second partition wall (33) in a pair of fitting objects fitted to each other.

Provided is a connector capable of enhancing contact reliability between a cable and a contact by improving press-contact accuracy of the cable by the contact. The connector (10) configured to clamp a core wire of a cable by a press-contact portion includes: a pair of fitting objects fitted to each other; a contact (50) provided in the fitting objects and having a pair of press-contact portions; a first partition wall (18b1) formed in one of the fitting objects; and a second partition wall (33) formed in another one of the fitting objects, in which a pair of press-contact portions of the contact (50) are spaced apart from each other and are separated by the first partition wall (18b1) and the second partition wall (33) in a pair of fitting objects fitted to each other.

A dual contact Insulation Displacement Contact (IDC) header pin comprised of an upper section, a lead-in section, and a retention section. The upper section of the pin has at a plurality of pin barbs to allow it to be retained into a housing. The side walls and back of the upper portion create a C-shape to the upper portion. Each IDC header pin has two blades to contact a wire and displace the insulation thereof. The lead-in section serves to lead the IDC header pin into a housing and prevent stubbing of the pin during insertion. The retention section of the pin has a plurality of rib-like projections allowing the pin to be retained into respective holes in a PCB by applying normal force and an interference fit. An embodiment is open, with front protrusions on the upper section, and another embodiment is closed, having two front walls on the upper section.

A dual contact Insulation Displacement Contact (IDC) header pin comprised of an upper section, a lead-in section, and a retention section. The upper section of the pin has at a plurality of pin barbs to allow it to be retained into a housing. The side walls and back of the upper portion create a C-shape to the upper portion. Each IDC header pin has two blades to contact a wire and displace the insulation thereof. The lead-in section serves to lead the IDC header pin into a housing and prevent stubbing of the pin during insertion. The retention section of the pin has a plurality of rib-like projections allowing the pin to be retained into respective holes in a PCB by applying normal force and an interference fit. An embodiment is open, with front protrusions on the upper section, and another embodiment is closed, having two front walls on the upper section.

Provided is an electrical connection box according to which it is possible to suppress the occurrence of mistakes in a manufacturing process, and it is possible to reliably prevent the occurrence of faulty products. The electrical connection box to be used in a vehicle includes a terminal having an inner-fitting plate portion that is fit into and held in a slit of a holding member; and multiple substrate connection portions that protrude along a surface of the inner-fitting plate portion from one side edge of the inner-fitting plate portion. The terminal has a shape that is asymmetrical in a direction in which the multiple substrate connection portions are arranged side by side.

Each IDCC header pin is comprised of an upper section, a pin barb section, and a lower section. Each IDCC header pin has at least a first pin barb on its pin barb section, to allow it to be anchored and retained into a housing. The upper section of each IDCC header pin also has a blade to contact a wire and displace the insulation thereof. The lower section of the pins has an associated compliant retention feature which allows the IDCC header pin to be retained into respective holes in a PCB. A dual contact bent IDCC header pin can include two upper sections which each have a blade and create a dual contact with a wire, and another embodiment can have a two-thickness upper section.

Each IDCC header pin is comprised of an upper section, a pin barb section, and a lower section. Each IDCC header pin has at least a first pin barb on its pin barb section, to allow it to be anchored and retained into a housing. The upper section of each IDCC header pin also has a blade to contact a wire and displace the insulation thereof. The lower section of the pins has an associated compliant retention feature which allows the IDCC header pin to be retained into respective holes in a PCB. A dual contact bent IDCC header pin can include two upper sections which each have a blade and create a dual contact with a wire, and another embodiment can have a two-thickness upper section.

A snap fastener system includes a conductive first snap fastener portion in electrical and physical contact with a first electronic component, a second snap fastener portion, and a snap ring including tines mated to one of the first and/or second snap fastener portions and including one or more conductive insulation displacement tines which cut through the insulation covering a wire to be electrically coupled to the first electronic component.