A cutting device (1), in particular for rapidly cutting webs, including: a support structure (2) including a fixed blade (3), a carriage (4) movable along a movement direction (X), a mobile blade (5) mounted on the carriage (4), a guide (7), associated to the support structure (2), on which the carriage (4) is slidable along the movement direction (X); a sliding sleeve (11), interposed between the carriage (4) and the guide (7) concentrically to the guide (7); seals (8, 10) interposed between the guide (7) and the carriage (4) so as to define a chamber (9), concentric to the guide (7) and containing the sleeve (11); motor (6) configured to move the carriage (4) according to an alternating movement along the movement direction (X) between a non-operating position and an operating position, in which the mobile blade (5) partially superposes the fixed blade (3) so as to carry out the cutting of a web; supply (15) for supplying air to the chamber (9) so as to maintain it at a greater pressure with respect to the surrounding environment.

In An example cutting module comprises a housing to engage the cutting module with a drive shaft, a cutter engaged with the housing, and a drive system engaged with the housing. The cutting module movable along the drive shaft laterally to a media path, the cutter cuts media along the media path, and the drive system may lock when the drive shaft rotates in a second drive direction such that the cutting module moves with the drive shaft.

In a cutting device, a cutting blade is reciprocally movable within a movable range including a first retracted position away from a target to be cut and a cut complete position at which cutting of the target is to be completed. A memory is configured to store cutting data indicating the first retracted position. A controller is configured to perform controlling, in response to determining that the cutting blade has stopped at an intervening position between a cut start position at which cutting of the target is started and the cut complete position, a drive portion to move the cutting blade from the intervening position to a second retracted position positioned within the movable range and away from the target. The controller is configured to further perform updating the cutting data stored in the memory so as to indicate the second retracted position in place of the first retracted position.

The invention relates to tube perforating machine for perforating a hollow tube. The powered machine includes a mechanical timing system comprising a Geneva mechanism so that perforations are punched when the tube is held stationary and perforations cannot be punched when the tube is rotating or moving longitudinally within the machine.

Method and device for guiding a tool in a recurring application of a product moved along an X-axis, wherein the tool is mounted on the Z-carriage of a cross guide and is moved therewith along the Z-axis standing perpendicular on the X-axis, wherein the Z-carriage is mounted on the X-carriage of the cross guide, the guide of which is mounted along the X-axis in a base plane, wherein the X-carriage is driven with an X-drive, wherein the Z-carriage is driven by a Z-drive, which is held stationary in the base plane and has a traction means driven by a first servo motor provided for the drive of the Z-carriage, which is driven from the base plane on the movable Z-carriage.

Method and device for guiding a tool in a recurring application of a product moved along an X-axis, wherein the tool is mounted on the Z-carriage of a cross guide and is moved therewith along the Z-axis standing perpendicular on the X-axis, wherein the Z-carriage is mounted on the X-carriage of the cross guide, the guide of which is mounted along the X-axis in a base plane, wherein the X-carriage is driven with an X-drive, wherein the Z-carriage is driven by a Z-drive, which is held stationary in the base plane and has a traction means driven by a first servo motor provided for the drive of the Z-carriage, which is driven from the base plane on the movable Z-carriage.

The invention relates to a punch press for punching out punch products, such as automotive components, especially instrument panels, door interior panels or similar, with a frame, with a punching tool with a lower tool and an upper tool, with a machine table for holding the lower tool, and with a traversing device for moving the upper tool in relation to the lower tool, wherein the punch press, especially the punching tool, the machine table and the traversing device are set up for replacing the punching tool for a punch product change to retool the punch press to new punch products to be punched.

The present invention relates to a thermoform packaging machine, comprising a controller and a film punch, which includes a lever mechanism, a tool, upper part and a tool lower part. At least one of the tool upper part and the tool lower part are movable by means of the lever mechanism such that the tool upper part and the tool lower part approach each other.

Disclosed is an electric puncher. The electric puncher includes at least one punching device, a rotating shaft and a drive unit. The punching device further includes a support frame arranged on the base and a punching assembly that moves up and down along the support frame. The rotating shaft can be connected with the support frame through rotation. The rotating shaft is furnished with eccentric cams that drive the punching assembly to move up and down. The staggered arrangement of eccentric cams enables the punching assemblies to asynchronously move up and down during the rotation of rotating shaft. The drive unit drives the rotating shaft to rotate. The asynchronous vertical motion of various punching assemblies helps to save labor, thereby alleviating the requirements for motor output power and gear strength.

A blade assembly includes a support frame, a cutting blade, a motor to drive the cutting blade, a support shaft operatively coupled to the support frame to permit pivotal movement of the support frame, and an actuator operatively coupled to the support frame to reciprocally move the slicing assembly between an extended position and a retracted position. When the slicing assembly is in the extended position, a plane of the cutting blade is substantially co-planar with a cutting plane of the food product, and the cutting blade slices the food product. Conversely, when the slicing assembly is in the retracted position, the plane of the cutting blade is disposed at a predetermined angle away from the cutting plane of the food product, and the cutting blade does not contact the food product.