A twisted pair cable processing system includes a frame and a core wire untwisting device installed on the frame for untwisting a pair of exposed core wires of a twisted pair cable. The core wire untwisting device includes an installation plate fixed to the frame, a rotating wheel rotatably mounted on the installation plate and formed with an axial through installation hole, a positioning body and a driver. The positioning body is embedded into the installation hole and is formed with a pair of core wire insertion holes. The driver drives the rotating wheel and the positioning body to rotate together. When the ends of the pair of exposed core wires of the twisted pair cable are inserted into the pair of core wire insertion holes, the driver drives the rotating wheel and the positioning body to rotate to unwind the pair of exposed core wires.

An apparatus for cutting a previously flared shield conductor of a shielded electrical cable includes a two-piece clamping die having an aperture in which the shielded electrical cable is secured and a cutting surface. The clamping die is opened and closed around the shielded electrical cable. The apparatus further includes a cutting tube configured to be pressed against the cutting surface while the flared shield conductor is between the cutting tube and the cutting surface, thereby cutting a portion of a free end of the flared shield conductor. Alternatively, the apparatus may include a die comprising a cutting surface and an aperture in which the end of the shielded electrical cable is received. The cutting tube has two parts that are closed about the shielded electrical cable and pressed against the cutting surface while the flared shield conductor is disposed between the cutting tube and the cutting surface.

A wire stripping machine includes a supporting frame; the supporting frame is provided with a first driving shaft and a second driving shaft; the distance between the first driving shaft and the second driving shaft enables a cable to pass through; the first driving shaft is provided with a number of straightening rings; a spacing between the straightening rings is not consistent; a wire inlet groove with a width and a non-uniform depth is arranged between the straightening rings; the second driving shaft sleeve is provided with a number of cutter and is arranged in the wire inlet groove and keeps the spacing of the cutting cable insulating layers from the wire inlet groove; a limiting ring is arranged between the cutter; and a lead plate is arranged on the supporting frame.

A method of processing a cable with a cable preparation device comprises the steps of: 1) flaring an exposed free end of at least one layer of the cable; and 2) folding the flared exposed free end of the at least one layer of the cable over a portion of the cable by engaging the exposed free end with a curved folding surface defined on a cutting blade of the cable preparation device.

A processing apparatus 200 for a multicore cable 1 processes the multicore cable 1 including a sheath 2 and cores 3 and 4 inserted in the sheath 2, and includes: a slitter 21 that makes a slit along a circumferential direction; a puller 22 that moves at least one of a distal portion of the sheath 2 and a proximal portion of the sheath 2 in a longitudinal direction of the multicore cable 1 to thereby expose the core wires 3 and 4, the distal portion being closer to a distal end of the multicore cable 1 than the slit, the proximal portion being closer to a proximal end of the multicore cable 1 than the slit; a detector 31 that detects a position of a specific core 3 of the cores 3 and 4 in a circumferential direction of the multicore cable 1; and a rotator 32a that rotates the multicore cable 1 based on the detected position of the specific core 3 in the circumferential direction to thereby move the specific core 3 to a predetermined position in the circumferential direction.

A method for connecting a conductor wire to an electrode that is formed on a substrate includes placing the conductor wire on the electrode while tension is applied to the conductor wire, and soldering the conductor wire to the electrode while the conductor wire is pressed toward the substrate by a heating element.

Disclosed is a medium to large-sized cable peeling device, including a main component having a base, a cable support positioned on top of the base and a positioning frame positioned in the middle of the cable support; and a cutting assembly positioned below the positioning frame and in the middle of the cable support, the cutting assembly has an adjustment component positioned below the positioning frame, a cutting blade positioned at the bottom of the adjustment component, a locking component positioned inside the cutting blade and a rotating component positioned below the adjustment component and in the middle of the cable support. The invention achieves adjustment of cable peeling based on the thickness of the cable insulation by setting up a main component and a cutting assembly, which prevents damage to cable core during the cutting process and enables the blade to cut at an angle, thereby improving cutting efficiency.

A method for easy, safe and fast removal of a section of a cable film. An end section of a cable has a cable axis, wherein the cable includes a cable jacket and at least one electrically conductive conductor structure and which includes a cable film made from a plastic and applied into one of the conductor structures. A defined damaged region is generated by inductively heating at least that conductor structure on which the cable film is applied such that the cable film applied onto the heated conductor structure is at least partially thermally damaged in the damaged region. The cable film is moved relative to one of the conductor structures, wherein a crack is formed by the relative movement in the damaged region that separates the section of the cable film to be removed from a section of the cable film remaining on the cable.