A method includes placing a cutter module in an engaging position; moving a positioner associated with the cutter module away from a homing position to contact and drag the cutter module until it is detected that the cutter module hits a first obstacle; and aligning the cutter module with the positioner; wherein, in the engaging position, the cutter module is in the movement path of the positioner.

A self-propelled module for oversize loads includes two ground movement assemblies with oil-pressure controlled actuation; a transverse rocker arranged between the movement assemblies, which are coupled thereto independently; oil-pressure controlled suspension elements, arranged on corresponding oscillating supports coupled to the transverse rocker; and a load-bearing frame, supported by the oil-pressure controlled suspension elements. The load-bearing frame includes an oil-pressure controlled circuit adapted to serve the ground movement assemblies and the suspension means elements. The module further includes a rotary distribution unit, having a vertical axis, mounted on the load-bearing frame for supplying the ground movement assemblies and the oil-pressure controlled suspension elements, a first part of the rotary distribution unit being fixed to the load-bearing frame, and a second part being free to rotate about the vertical of the resting surface with respect to the load-bearing frame.

Disclosed are a round knife, a cutting assembly, and a method for cutting tire components wherein the round knife includes a carrier that is rotatable about a rotation axis (X) and a plurality of first edge segments which are arranged to be mounted side-by-side in a circumferential direction (G) about the rotation axis (X) to the carrier to form a circular cutting edge (E) extending concentrically about the rotation axis (X), wherein the segment body is arranged to be spaced apart from the carrier in the radial direction (R) at the center between the first lateral side and the second lateral side.

There is provided a printing apparatus. A printing unit prints an image on a printing medium and is able to move. A cutter unit is able to connect with or separate from the printing unit, and, by following a movement of the printing unit, cuts the printing medium. A setting unit sets, in accordance with a size of the printing medium, a standby position of the cutter unit.

There is provided with printing apparatus. A printing unit prints an image on a printing medium and is able to move. A cutter unit is able to connect with or separate from the printing unit, and, by following a movement of the printing unit, cuts the printing medium. A control unit, in a case where a predetermined condition is satisfied after the printing medium is cut by the cutter unit, causes the printing unit to perform printing on a succeeding printing medium, while moving the printing unit in a state in which the cutter unit is connected with the printing unit.

This disclosure describes a micro-cutting machine for forming cuts in catheters, guidewires, and similar products. The micro-cutting machine can directly control the dimensions of the resultant beams being cut into these types of products, and can also capture images of each cut for feedback control and accuracy verification. The micro-cutting machine has two cutting blades each with cutting edges aligned with a vertical axis. Motors operate to move the cutting blades in a direction perpendicular to the longitudinal axis of the stock material being cut to form a pair of opposing grooves in the stock material with each cut.

This disclosure describes a micro-cutting machine for forming cuts in catheters, guidewires, and similar products. The micro-cutting machine can directly control the dimensions of the resultant beams being cut into these types of products, and can also capture images of each cut for feedback control and accuracy verification. The micro-cutting machine has two cutting blades each with cutting edges aligned with a vertical axis. Motors operate to move the cutting blades in a direction perpendicular to the longitudinal axis of the stock material being cut to form a pair of opposing grooves in the stock material with each cut.

The bidirectional sheet metal cutting tool (100) is a cutting tool that performs cuts on webbed material in which a length of cut exceeds a physical dimension of the cutting tool (100), while limiting flexing of the webbed material during a cutting operation. The cutter assembly (140) is configured to ride on a guide track (145), and has upper and lower sections. The upper and lower sections have an offset attachment to each other at an interface, so that the webbed material passes the offset after cutting in an extended bypass cutting operation. An interface between the upper and lower sections has a curved profile, allowing deflection of the webbed material on at least one side of a cutting direction. The cutting tool (100) can be mounted to a sheet metal forming tool as a slitter (500), permitting sequential operations of the metal forming tool.

A slitting machine for removing a strip from a sheet of material. The slitting machine has a blade assembly with first and second cutting blades, and a perforating blade arranged between the first and second cutting blades. The first and second cutting blades are arranged to cut the sheet of material to define the strip and the perforating blade is arranged to perforate the sheet of material to define an end of the strip.

A system for forming composite flake. An apparatus includes a first shearing assembly that meshes with a second shearing assembly to shear a length of composite material into a plurality of strips wherein reinforcing fibers of the composite material extend along the length of the composite strips. A chopping station receives the plurality of strips from the first and second shearing assemblies and shears the plurality strips across the axis of the reinforcing fibers to chop each strip into a plurality of pieces.