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.

A wire stripper part or assembly uses two or more elements for a blade roller, with one element being a cutter, and the other element or elements being a guide element that keeps the wire aligned with the cutter. A tri-blade self-centering wire stripper knife is also described. A wire stripper has: a structural frame; parallel rollers mounted on the structural frame to rotate relative to one another, one of the parallel rollers being a feed roller and the other being a blade roller; and in which the blade roller has a wire cutter comprising a cutting blade and one or more circumferential guide shoulders, with the wire cutter aligned with a wire-gripping portion of the feed roller to define a wire-cutting zone. Methods of use are described.

There is provided a coating moving method for a cable that removes a coating at a terminal portion of a cable, including a step of applying a pressing force having such a magnitude that a cutting edge stops at a position before reaching the core wire to the cutting blade to make an incision on the coating by the cutting blade, a step of twist-cutting an uncut portion of the coating between the cutting edge of the cutting blade and the outer periphery of the core wire by rotating the coating on a distal end side from an incision position with respect to the coating on a base end side, and a step of removing the coating on the distal end side from the incision position by gripping and pulling out the coating on the distal end side from the incision position to expose the core wire.

A strip stop mechanism for a fiber stripping machine including a channel for receiving an optical fiber. The strip stop mechanism can include a lever operably mounted to the fiber stripping machine, the lever extending between a first end and a second end and being rotatable between a first position and a second position. When the lever is in the first position, the first end of the lever resides within the channel to provide an end stop for the optical fiber. When the lever is in the second position, the first end of the lever is at least partially withdrawn from the channel and the fiber stripping machine is activated. A second end of the lever can be configured to depress an activation button of the fiber stripping machine once the first end of the lever is at least partially removed from the channel.

A stripping system that includes a securement device including a receiver platform and an engagement platform sized to receive at least a portion of a large diameter cable having an outer jacket defining a thickness of at least 0.5 mm. The engagement platform translates relative to the receiver platform to secure the cable to the securement device. The system includes a cutting device including a receiver platform that includes a first cutting apparatus and an engagement platform that includes a second cutting apparatus. The receiver platform is sized to receive at least a portion of the cable. The engagement platform translates relative to the receiver platform to move the second cutting apparatus toward the first cutting apparatus to define a cutting interface that is sized to partially sever the outer jacket such that at least a portion of the 0.5 mm thickness of the outer jacket remains partially intact.

An integrated cable processing device for performing processing operations on a cable includes a frame defining a workbench, and a plurality of cable processing mechanisms provided on the workbench for performing different processing operations on the cable. A cable clamping assembly of the device is adapted to clamp the cable, and is movable relative to the plurality of cable processing mechanisms to successively move a sub segment to be processed of the clamped cable to each of the plurality of cable processing mechanisms, and each cable processing mechanism performs the corresponding processing operation on the sub segment.

A wire processing system includes a tray having at least one tray surface configured to sequentially receive a first wire and a second wire from a wire feed system of a wire processing machine. The tray surface has a surface feature configured to provide a wire-to-surface coefficient of friction between the tray surface and the first wire higher than a wire-to-wire coefficient of friction between the first wire and the second wire laying on top of the first wire. The wire-to-surface coefficient of friction reduces movement of at least a portion of the first wire relative to the tray surface during movement of the second wire relative to the first wire.

The present disclosure relates to the technical field of cable processing, and discloses a method for processing a reaction force cone of a cable main insulating layer. The method includes: two ends of a cable are clamped through a clamping device, and the cable is enabled to pass through a cutting device; a cutting depth of the cutting device in a radial direction and a cutting position of the cutting device in an axial direction are adjusted; the cutting device is started, and the cable is cut by the cutting device to form the reaction force cone.

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-processing device includes a first advancing device, a cutter head, and a second advancing device. The first advancing device pulls the wire out of a wire store and advances according to the desired length of wire to be cut. After the wire is cut through by the cutter head, the wire-ends of the wire-length are processed. The wire-processing device is provided with a device to determine the diameter of the conductor of the wire including an input coupler that generates in the wire a wire signal, and wherein the wire signal can be sensed by an output coupler which generates an input signal which is interpreted by a signal processor, wherein the cutters of the cutter head touch the conductor and change the input signal when cutting into the wire.