A front end feeding device 23 between a cutter 10 and a fixed-length feeding hand 30 that feeds a strip member 5 on an upstream side of the cutter 10 feeds a front end of the strip member 5 a short distance to a downstream side of the cutter 10, a front end grasping hand 60 on the downstream of the cutter 10 holds the front end of the strip member 5 fed the short distance, the fixed-length feeding hand 30 holds a part of the strip member 5 fed the short distance on the upstream side of the cutter 10, the front end grasping hand 60 and the fixed-length feeding hand 30 synchronously feed the strip member 5 a long distance to the downstream side, and the cutter 10 cuts the strip member 5 having been fed the long distance.

A sheet processing apparatus includes a sheet conveyance portion, a punching member, a punching member moving portion, a position detection portion, and a controller. In a case of performing a punching process on a preceding sheet and a succeeding sheet successively conveyed to a predetermined position, the controller is configured to execute preliminary movement after the punching process on the preceding sheet is finished and before an end portion position of the succeeding sheet in a sheet width direction that coincides with a first punching position of the succeeding sheet in a conveyance direction reaches the position detection portion. The first punching position is a position where the punching process is first performed on the succeeding sheet.

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.

A sheet perforating apparatus includes a punch unit configured to punch holes in a sheet from an image processing apparatus. A dust box is below the punch unit and detachably attached to a case. A lid member is attached to the dust box and is displaceable between a closed state, in which the lid member closes an opening of the dust box, and an open state, in which the lid member does not close the opening of the dust box. When in the open state, the lid member is electrically grounded to weaken static electricity of punch chips dropped from the punch unit to the lid member and directs the punch chips towards the opening.

A sheet perforating apparatus includes a punch unit configured to punch holes in a sheet from an image processing apparatus. A dust box is below the punch unit and detachably attached to a case. A lid member is attached to the dust box and is displaceable between a closed state, in which the lid member closes an opening of the dust box, and an open state, in which the lid member does not close the opening of the dust box. When in the open state, the lid member is electrically grounded to weaken static electricity of punch chips dropped from the punch unit to the lid member and directs the punch chips towards the opening.

The cutting machine includes at least one feed path for elongated products, wherein the elongated products move forward along a direction substantially parallel to the longitudinal extension thereof. The cutting machine includes a rotating unit adapted to rotate around a rotation axis, carrying at least one first disc-shaped cutting blade and one second disc-shaped cutting blade. The rotation of the rotating unit causes an orbital movement of the first disc-shaped cutting blade and of the second disc-shaped cutting blade along trajectories intersecting the product feed path. The first disc-shaped cutting blade and the second disc-shaped cutting blade are offset from each other in a direction parallel to the product feed path. The first disc-shaped cutting blade and the second disc-shaped cutting blade are also angularly offset from each other with respect to the rotation axis of the rotating unit.

The cutting machine includes at least one feed path for elongated products, wherein the elongated products move forward along a direction substantially parallel to the longitudinal extension thereof. The cutting machine includes a rotating unit adapted to rotate around a rotation axis, carrying at least one first disc-shaped cutting blade and one second disc-shaped cutting blade. The rotation of the rotating unit causes an orbital movement of the first disc-shaped cutting blade and of the second disc-shaped cutting blade along trajectories intersecting the product feed path. The first disc-shaped cutting blade and the second disc-shaped cutting blade are offset from each other in a direction parallel to the product feed path. The first disc-shaped cutting blade and the second disc-shaped cutting blade are also angularly offset from each other with respect to the rotation axis of the rotating unit.

An automated food cutting machine is disclosed, having a cutting element defining a cutting point; a rotary shaft; a body joined to the rotary shaft; at least one housing joined to the body radially spaced with respect to the rotary shaft; a cavity in each of the housings for housing the products, the cavity defined with an end opening for passage of the foods and a longitudinal opening for depositing and removing the foods; an element for moving through the cavity and dragging the foods towards the end opening; device for arranging the foods in the housing; a control unit for actuating the device with the element at the starting point and moving the element between the starting and end points.

An automated food cutting machine is disclosed, having a cutting element defining a cutting point; a rotary shaft; a body joined to the rotary shaft; at least one housing joined to the body radially spaced with respect to the rotary shaft; a cavity in each of the housings for housing the products, the cavity defined with an end opening for passage of the foods and a longitudinal opening for depositing and removing the foods; an element for moving through the cavity and dragging the foods towards the end opening; device for arranging the foods in the housing; a control unit for actuating the device with the element at the starting point and moving the element between the starting and end points.