A method is for cutting a tubular structure in the petrochemical industry, using a cutting tool having a non-rotatable cutting element and a reaction member opposite the non-rotatable cutting element. The cutting tool is further configured for carrying out a translational cutting movement through the tubular structure. The method comprises: a) positioning the cutting tool in a first position exterior to the tubular structure; b) squeezing the tubular structure at the first position by activating a partial translational cutting movement of the non-rotatable cutting element to obtain a dented region in the tubular structure; c) positioning the cutting tool in a second position exterior to the tubular structure, wherein the second position is displaced over a predefined distance compared to the first position, and d) cutting the tubular structure at the second position (P2) by activating a full translational cutting movement of the non-rotatable cutting element through the tubular structure.

A service tool for cutting and plugging a fluid line includes a body having a receiving portion configured to receive the fluid line, a clamping mechanism movable relative to the body and configured to clamp around at least a portion of an outer circumference of the fluid line when the fluid line is received in the receiving portion, and a cutting blade configured to engage the fluid line and cut the fluid line into a first cut portion and a second cut portion. The service tool further includes a hub associated with the body, the hub including a plugging mechanism configured to dispense a plug or a valve into the second cut portion of the fluid line.

A method and device provides for alternately cutting off material by back-and-forth movement of multiple vehicles. Specifically, the device is a cut-off machine for alternately cutting off material by back-and-forth movement of multiple vehicles. The cut-off machine is at least provided with two cutter vehicles, wherein these vehicles are installed on tracks parallel to material. The tracks are arranged around the material side by side. Each vehicle moves back and forth in accordance with a set sequence. Cutters on the vehicles alternately cut off the material in accordance by a set length. The larger the number of vehicles, the longer the possible stroke of each vehicle can be, such that the cutters have more time to cut off the material. Accordingly, the cut-off machine can be adapted to higher material forming speeds in a production line.

A purpose of the present invention is to provide a technology that allows corrugated tubes of various diameter sizes to be easily and reliably cut at a convex portion. In order to achieve the purpose, a cutting device is provided with a feeder feeding a corrugated tube such that an axial direction of the corrugated tube lies along a feeding path; a cutter cutting along a circumferential direction of the corrugated tube being fed along the feeding path; and an imager capturing an image of a planned cutting position of the corrugated tube. A controller performs image analysis of the captured image of the planned cutting position to determine whether the planned cutting position is a convex portion of the corrugated tube and, when a positive determination result is obtained, causes the cutter to cut the corrugated tube at the planned cutting position.

A purpose of the present invention is to provide a technology that allows corrugated tubes of various diameter sizes to be easily and reliably cut at a convex portion. In order to achieve the purpose, a cutting device is provided with a feeder feeding a corrugated tube such that an axial direction of the corrugated tube lies along a feeding path; a cutter cutting along a circumferential direction of the corrugated tube being fed along the feeding path; and an imager capturing an image of a planned cutting position of the corrugated tube. A controller performs image analysis of the captured image of the planned cutting position to determine whether the planned cutting position is a convex portion of the corrugated tube and, when a positive determination result is obtained, causes the cutter to cut the corrugated tube at the planned cutting position.

A purpose of the present invention is to provide a technology that allows corrugated tubes of various diameter sizes to be easily and reliably cut at a convex portion. In order to achieve the purpose, a cutting device is provided with a feeder feeding a corrugated tube such that an axial direction of the corrugated tube lies along a feeding path; a cutter cutting along a circumferential direction of the corrugated tube being fed along the feeding path; and an imager capturing an image of a planned cutting position of the corrugated tube. A controller performs image analysis of the captured image of the planned cutting position to determine whether the planned cutting position is a convex portion of the corrugated tube and, when a positive determination result is obtained, causes the cutter to cut the corrugated tube at the planned cutting position.

A purpose of the present invention is to provide a technology that allows corrugated tubes of various diameter sizes to be easily and reliably cut at a convex portion. In order to achieve the purpose, a cutting device is provided with a feeder feeding a corrugated tube such that an axial direction of the corrugated tube lies along a feeding path; a cutter cutting along a circumferential direction of the corrugated tube being fed along the feeding path; and an imager capturing an image of a planned cutting position of the corrugated tube. A controller performs image analysis of the captured image of the planned cutting position to determine whether the planned cutting position is a convex portion of the corrugated tube and, when a positive determination result is obtained, causes the cutter to cut the corrugated tube at the planned cutting position.

An apparatus for the processing of wire and/or tubular components includes a base member and at least two wire/tube processing modules. The modules can be releasably engaged with each other and the base member in which engagement mechanically and electrically couples the modules and the base member. The base member includes an operator interface enabling operation to any linked module.

An apparatus for machining a tubular piece, wherein the apparatus includes a frame element, support rollers, which are associated with the frame element, support a workpiece and rotate the same around its longitudinal axis. In addition, the frame element is provided with a machining unit adapted to be movable towards and away from the workpiece. The machining unit includes a tool member, such as for example a cutting tool, as well as support wheels adapted to bear against a workpiece. The machining unit is arranged to link up with the frame element through the use of an auxiliary frame element adapted to clamp itself thereto at not less than two support points, for example through the use of a self wedging assembly implemented with an indentation.

An apparatus for machining a tubular piece, wherein the apparatus includes a frame element, support rollers, which are associated with the frame element, support a workpiece and rotate the same around its longitudinal axis. In addition, the frame element is provided with a machining unit adapted to be movable towards and away from the workpiece. The machining unit includes a tool member, such as for example a cutting tool, as well as support wheels adapted to bear against a workpiece. The machining unit is arranged to link up with the frame element through the use of an auxiliary frame element adapted to clamp itself thereto at not less than two support points, for example through the use of a self wedging assembly implemented with an indentation.