Methods and systems for assembling customizable solderless cables for direct current (DC) transmission of electricity to an electronic device. The systems and methods utilize shielded co-axial cable defining first and second opposed ends which may be cut to a desired length as selected by the user. Connectors, which may have a conventional 2.1 mm×5.5 mm DC plug design, include a barrel portion defining a threaded axial passageway. In use, the threaded passageway of the plug is twisted upon a respective end of the cable such that the end of the cable becomes threadedly seated thereinto and in electrical contact with the plug to form two dedicated electrical connections. A respective other plug is mounted on the other respective end of the cable in the same manner to thus define the customizable cable. A single length of cable or a plurality of wire segments and plugs may be sold as a pre-packaged unit for use in making a plurality of customizable DC cables.

An assembly comprising a cable terminator comprising a wire guide, a cube shaped securing cap comprising an open end for installation over the wire guide, and pairs of piercing contacts for piercing respective conductors of the cable. When assembled, an outer end of each of the piercing contacts is exposed on an outer surface of a respective securing cap sidewall. The assembly also comprises a coupler connector comprising one of a modular (for example RJ-45 compatible) socket or a modular (for example RJ-45 compatible) plug, a rearward surface comprising a cable terminator receiving socket, wherein pairs of contacts are exposed along at least one side wall of the socket, and further wherein each of a plurality of the tines in the modular socket or the terminal contacts of the plug is interconnected with a respective one of the contacts. When the cable terminator is inserted into the cable terminator receiving socket, each of the piercing contacts comes into contact with a respective one of the contacts, thereby interconnecting each of the tines (or each of the terminal contacts) with a respective one of the conductors. A back-to-back connector is also disclosed.

The invention concerns a production line consisting of an automated system for the realization of the industrial wiring of IDC connectors.

An intraoperative multichannel brain probe is presented. The brain probe has a cylindrical upper stainless steel section attached to a lower cylindrical section. In the lower section, an outer cylindrical tube surrounds a second insulating tube. Electrically recording/stimulating wires are placed between the outer tube and the second tube. Each wire has one end protruding out a hole in the outer tube. The other end of each wire is threaded through the entire probe and electrically connected to a recording or stimulating device through a connector system. A number of insulating tubes and electrodes located inside the second tube may also be part of the brain probe. Each inner electrode, typically two, is insulated from each other and from the second insulating tube by other insulating tubes. The combination of one or more wires and electrodes provides a multi-functional device. The brain probe is capable of providing multichannel stimulation and/or recording of brain functions and up to 128 individual electrode conducting sites.

An intraoperative multichannel brain probe is presented. The brain probe has a cylindrical upper stainless steel section attached to a lower cylindrical section. In the lower section, an outer cylindrical tube surrounds a second insulating tube. Electrically recording/stimulating wires are placed between the outer tube and the second tube. Each wire has one end protruding out a hole in the outer tube. The other end of each wire is threaded through the entire probe and electrically connected to a recording or stimulating device through a connector system. A number of insulating tubes and electrodes located inside the second tube may also be part of the brain probe. Each inner electrode, typically two, is insulated from each other and from the second insulating tube by other insulating tubes. The combination of one or more wires and electrodes provides a multi-functional device. The brain probe is capable of providing multichannel stimulation and/or recording of brain functions and up to 128 individual electrode conducting sites.

The pressure welding contact is provided with an electric wire connecting portion and a contact connecting portion. The electric wire connecting portion comprises a first fixing plate and a pressure welding piece. The pressure welding piece comprises a notched groove into which the core wire of the electric wire can be introduced. The contact connecting portion comprises a second fixing plate and an elastic piece. The second fixing plate contacts the first fixing plate. The elastic piece turns back from the base end portion of the second fixing plate. Further, the elastic piece is disposed in a state inclined upwards, towards the tip portion of the second fixing plate. The elastic piece comprises at its tip portion a contact point portion. The mating side connector can be inserted from between the second fixing plate and the elastic piece.

A connector (10) configured to bring an object (70) into conduction comprises: a pair of fitting bodies fittable to each other; and a filler (60) with which at least one fitting body of the pair of fitting bodies is loaded, wherein a fitting body of the pair of fitting bodies includes an accommodating portion (35a) configured to accommodate an end of the object (70), and the filler (60) is configured to cover the end of the object (70) in the accommodating portion (35a).

A connector (10) configured to bring an object (70) into conduction comprises: a pair of fitting bodies fittable to each other; and a filler (60) with which at least one fitting body of the pair of fitting bodies is loaded, wherein a fitting body of the pair of fitting bodies includes an accommodating portion (35a) configured to accommodate an end of the object (70), and the filler (60) is configured to cover the end of the object (70) in the accommodating portion (35a).

A connector for receiving a ribbon cable is provided. The connector includes a housing including an open top, a cable organizer, and a cover. The cable organizer is configured to be positioned within an interior of the housing and configured to receive the ribbon cable upon an upper surface thereof. The cover is configured to selectively cover the open top of the housing to enclose the cable organizer within the interior of the housing. The cover is coupled to the housing and includes a latch configured to engage the housing and the cable organizer and move in a both vertical direction relative to the housing and rotate relative to the housing.

A connector for receiving a ribbon cable is provided. The connector includes a housing including an open top, a cable organizer, and a cover. The cable organizer is configured to be positioned within an interior of the housing and configured to receive the ribbon cable upon an upper surface thereof. The cover is configured to selectively cover the open top of the housing to enclose the cable organizer within the interior of the housing. The cover is coupled to the housing and includes a latch configured to engage the housing and the cable organizer and move in a both vertical direction relative to the housing and rotate relative to the housing.