The invention describes an apparatus for separating a two-ply film web which can first be wound up at a winding point, wherein the two plies of the film web are first joined to one another via two side edges, wherein the apparatus comprises as features at least one and preferably two lengthwise slitting units, with which a lengthwise slit can be made into a first of the two plies of the two-ply film web, which are at a distance from side edges, so that the one ply is narrower than the two-ply film web, and at least one pressing element, which can be moved in the orthogonal direction of the plane defined by the two-ply film web, wherein the two plies of the two-ply film web can be spaced apart from one another, and which can be moved in the plane of the two-ply film web, but perpendicular to its longitudinal direction, so that the pressing element can be guided between the two plies of the two-ply film web.

Blade for a stripping and peeling tool for stripping and peeling a pre-insulated pipe.

The invention relates to a separating device (10) for separating a tubular flat material (1) having an actual tube width (1.1), comprising at least one longitudinal separating unit (20) for removing a first edge region (2) and a second edge region (3) of the flat material (1). The invention further relates to a separating method (100) for separating a tubular flat material and to a system (70) having a separating device (10).

A method is shown for installing a heat tube on a section of pre-insulated piping. A metal carrier pipe is covered with a first layer of foam insulation. Next, a routing device is used to cut a longitudinal slot along the length of the pipe so that the pipe exterior surface is exposed from the insulation. A heat tube is then installed within the longitudinal slot, whereby the heat tube contacts the exterior surface of the metal carrier pipe. A second layer of foam insulation is then sprayed onto the exterior of the metal carrier pipe, covering the previously formed longitudinal slot and installed heat tube. A polyolefin coating is then applied over the insulation to form a protective outer jacket for the insulated pipe.

A tube jacket slitting tool including first and second opposite tool portions, each tool portion including a common hinged portion at a first end for engaging the opposite tool portion. The first and second opposite tool portions are foldable about the hinged portion between an open position and a closed position. The tool includes at least one concave surface extending across the width of forming an opening, when the first and second opposite tool portions are in the closed position, through which a tube may be slid. The tool includes a blade extending inward into the opening for slitting a depth of the tube jacket as it is moved with respect to the tool. The tool includes a hinge pivot axis in the hinged portion extending in a direction substantially in the direction of the width and at an acute angle to either the plane or to the longitudinal axis of the tube or cable in the opening formed by the at least one concave surface. When the first and second opposite tool portions are folded to the closed position with the tube or cable in the opening, movement of the tube or cable with respect to the tool causes the first and second opposite tool portions to be urged toward each other.

A device for slitting a tubular workpiece into strips includes radially disposed cutting members. The device may include a tapered infeed mandrel for maintaining tension on the tubular workpiece being slit and optionally an exit mandrel. In embodiments, the position of the radially disposed cutting members may be adjustable.

A slitter for slitting a guide catheter has a handle and a blade assembly coupled to the handle. The blade assembly includes a shroud for receiving an elongated body of a medical device and a slitting blade having an exposed cutting edge to slit the guide catheter. The blade assembly includes a user-deflectable portion coupled to the shroud for causing the shroud to flex in response to deflection of the user-deflectable portion. The handle and the blade assembly may be assembled from piece parts in a manufacturing method.

An electrical wire processing device (1) includes a pair of cutting blades (40A, 40B) capable of cutting an electrical wire (5) and circumferentially notching a covering (5b), a slit blade (43A, 43B) disposed farther in one side in a longitudinal direction (CL) of the electrical wire (5) than the cutting blades (40A, 40B) and capable of slitting the covering (5b) in the longitudinal direction (CL) of the electrical wire (5), and a slit blade actuator (35A, 35B) that moves the slit blade (43A, 43B) between a slit position in which the slit blade (43A, 43B) comes closer to the electrical wire (5) than the cutting blades (40A, 40B) and a retraction position in which the slit blade (43A, 43B) goes farther from the electrical wire (5) than the cutting blades (40A, 40B).

A slitter for slitting a guide catheter has a handle and a blade assembly coupled to the handle. The blade assembly includes a shroud for receiving an elongated body of a medical device and a slitting blade having an exposed cutting edge to slit the guide catheter. The blade assembly includes a user-deflectable portion coupled to the shroud for causing the shroud to flex in response to deflection of the user-deflectable portion. The handle and the blade assembly may be assembled from piece parts in a manufacturing method.

Described herein is a cutting apparatus (100) for allowing visual inspection of a core sample in an inner tube at a drilling site after the inner tube has been removed from a coring tube and prior to it being transported to a laboratory. The cutting apparatus (100) comprises a support track (110, 112, 114, 116)) on which is mounted a tube support member (120), a cutter wagon (130, 132, 138) and a drive arrangement (140, 142, 144, 146). The apparatus (100) provides relative movement between an inner tube (150) and the cutter wagon (130, 132, 138) to allow a section of the inner tube (150) to be removed along its entire length for visual inspection. The drive arrangement (140, 142, 144, 146) provides the relative movement between the inner tube (150) and the cutter wagon (130, 132, 138).