A metal foil flaring apparatus includes a frame, a flaring mechanism mounted on the frame and having a flaring mouth adapted to open and close, and a first driver mounted on the frame and adapted to drive the flaring mouth to open and close. The flaring mouth has a cone shape gradually contracted toward a front end of the flaring mouth. The front end of the flaring mouth is adapted to be forwardly inserted in a first direction between an inner insulation layer of a cable and a metal foil wrapped around the inner insulation layer when the flaring mouth is closed, flaring the metal foil outwardly into the cone shape.

A cable processing apparatus including a first housing member having a first interface surface, a second housing member having a second interface surface, the second interface surface opposes the first interface surface. At least one abrasive member unit coupled to at least one of the first and second housing members so as to be disposed between the first and second interface surfaces. A controller coupled to the first and second housing members and the at least one abrasive member unit for moving the first and second housing members to clamp a cable extending through the first and second housing members, actuating the at least one abrasive member unit, and moving the second housing member relative to the first housing member to radially expand shielding of the cable where the radially expanded cable shielding is ground off of the cable by the at least one abrasive member unit.

A stripping apparatus and a stripping station capable of reducing cycle time for steps of stripping an insulation coating from a conducting wire material are provided. A stripping apparatus configured to strip an insulation coating WL from a conducting wire material W, including the insulation coating WL and cross-section of which orthogonal to a longitudinal direction has a rectangular shape, the stripping apparatus includes: an upper mold 150 provided with a stripping blade configured to strip the insulation coating WL; a lower mold 110 configured to support the conducting wire material W from a lower side thereof; a pressing member 130 configured to prevent displacement of the conducting wire material W; and a rotation mechanism configured to rotate the conducting wire material W around a rotational axis C1 that is parallel to a axial center of the conducting wire material W.

A system for servicing cable includes a field-end assembly and a live-end assembly, each mounted on a support structure having at least one drive mechanism operable to cause relative linear movement between the field-end assembly and the live-end assembly. A drilling-and-shorting assembly can create a short circuit in a field-end of the cable, and a continuity tester can test the integrity of the short-circuit. The field end of the cable can then be ejected from the system, and an end-cap-cradle assembly can position an end cap on a live end of an electrical cable and test its installation.

A system for the automated production of a cable set, which has a branched structure of a plurality of individual line elements. In a modular set-up in the first part, a plurality of first processing stations, and in the second part, a plurality of second processing stations are arranged. In the first part, there is an automatic preparation of the individual line elements, which are then collected in a buffer station at the end of the first part. In the second part, the prepared individual line elements are assembled into the cable set. The line elements are plugged into connector casings in a connector station and transferred to second transporters, and via which the branched structure of the cable set is then formed by moving along second tracks. In this spread-out branched structure, a fixing of the line elements to one another takes place in a fixing station.

An automated system for processing an end of a cable. The system includes: a cable delivery system; a cable processing module; a pallet supported by the cable delivery system; a drive wheel rotatably coupled to the pallet; a motor operatively coupled for driving rotation of the drive wheel; and an idler wheel rotatably coupled to the pallet and forming a nip with the drive wheel. The cable processing module includes cable processing equipment configured to perform an operation on an end of a cable and a computer system. The computer system is configured to: (a) cause the drive wheel to rotate in a cable pushing direction to cause a specified length of cable to be inserted into the cable processing equipment; (b) activate the cable processing equipment to perform an operation on the inserted end of the cable; and (c) cause the drive wheel to rotate in a cable pulling direction to cause the specified length of cable to be removed from the cable processing equipment.

A cable processing device includes at least one processing unit for assembling a cable and a sorting unit that can be actuated with a selection signal to output a cable received from the processing unit at least on a first side or on a second side according to the selection signal.

Provided is an insulating coating device for an electric wire, including a pressing pipe. The pressing pipe includes two first pressing parts which are configured to divide the pressing pipe into two parts along a longitudinal cross section of the pressing pipe, an inner wall of the pressing pipe is provided with an air bag, and the air bag is provided with an air pipe joint which penetrates to an outside of the pressing pipe. In the insulating coating device for the electric wire, a self-curing insulating material is coated on joints of the electric wires, the air bag is used to squeeze the self-curing insulating material such that the self-curing insulating material is shaped and compacted, so that cavities generated in a coating process is reduced, and the self-curing insulating material is uniformly attached to the joints of the electric wires.

A method for processing a cable on a cable processing machine which includes a cable processing station with a cable processing tool. An interface receives at least one physical parameter value, from a sensor, indicating a capability of the cable processing machine for executing a processing step. A capability determination component determines, based on the physical parameter, that the capability is insufficient. A voice instruction generator component generates voice instructions for an operator, relating to an action to be performed for restoring the capability of the cable processing machine to enable execution of the processing step. Voice instructions are output generated and sent to wearable audio device associated with operator. A confirm component receives confirmation that action for restoring the capability of the cable processing machine is complete, and the capability determination component validates restoration of the capability. Once capability is restored, the cable processing tool executes the processing step.

A robot is a robot configured to convey an elongated object, and includes a first holding part and a second holding part configured to hold the elongated object extending in an up-and-down direction, at least one arm configured to move the first holding part and the second holding part, and a control device. The control device operates the arm so that the first holding part holds the elongated object at a position above a center-of-gravity position of the elongated object, the second holding part holds the elongated object at position below the center-of-gravity position, and the first holding part and the second holding part move while maintaining a state where the first holding part and the second holding part hold the elongated object.