A front end conveyor includes a frame having a first side and a second side, a lower deck having a plurality of sheet supports and an upper deck having a plurality of sheet guides. Upper portions of the sheet supports lie in a first plane. The plurality of sheet supports and the plurality of sheet guides define therebetween a sheet transport path for moving sheets in a sheet transport direction toward the downstream end of the front end conveyor, and the front end system includes at least one blower directed at the sheet transport path and configured to dislodge scrap material from the sheets.

Embodiments are directed to an automated cutting tool that is configured to cut open nonuniform enclosures, such as cases containing electronic components. An example system comprises a multi-speed motor that is coupled to a cradle. The multi-speed motor rotates the cradle at a selected speed, and the cradle adapted to hold a case. A cutting head is positioned adjacent to the cradle and is configured to maintain contact with the case during rotation of the multi-speed motor. The multi-speed motor is configured to operate at a first speed when first segments of the case are in contact with the cutting head and to operate at a second speed when second segments of the case are in contact with the cutting head.

The present invention relates to a device (1) for automatically cutting a material web (2) with a longitudinal cutting device (60) using a material web (2) in a longitudinal direction (L) separable in at least a partial web (3) and/or at least a remaining web (4), a discharging device (10) for automatically discharging the produced remaining web (4), a transverse cutting device (70) downstream of a longitudinal cutting device (60) for cutting the remaining web (4) transversely to the longitudinal direction (L).

An apparatus includes channel assemblies in a rotatable section, a cutting assembly, a discharge assembly, and a cleanout assembly. The channel assembly holds a bulk instance of compressible material extending through upper and lower channels of a continuous channel. The cutting assembly moves in relation to the channel assembly to isolate the upper and lower channels, severing upper and lower material portions of the bulk instance. The discharge assembly directs gas into the lower channel of a channel assembly to discharge the lower material portion from the lower channel, based on radial alignment of a conduit assembly of the channel assembly with a conduit assembly of the discharge assembly. The cleanout assembly supplies a fluid through the conduit assembly of the channel assembly, based on radially alignment of the conduit assembly of the channel assembly with a conduit assembly of the cleanout assembly.

A cutting apparatus includes a blade configured to cut a sheet that is conveyed along a sheet conveyance path, a scrap path through which scrap generated when the sheet is cut by the blade passes, a guide member configured to guide the sheet conveyed, and a blowing unit configured to blow air such that the air crosses the sheet conveyance path from a side opposite the scrap path with the sheet conveyance path therebetween, wherein the blowing unit blows air such that the air flows along the guide member positioned at a second position at which the scrap is allowed to enter the scrap path.

The invention relates to a paper making machine (1) comprising a forming section (2) in which a fibrous web (W) can be formed, a drying section (5) in which a formed fibrous web (W) can be dried; and a reel-up (11) on which a dried fibrous web (W) can be wound into a roll (12). The paper making machine (1) is arranged to carry a fibrous web (W) in the machine direction (MD) along a predetermined path (P) and the paper making machine (1) has at least one water jet cutting device (17, 18, 19) arranged to cut the fibrous web (W) that is moving in the machine direction (MD) such that the fibrous web (W) is divided into at least one waste part (23a, 23b, 30) and a remaining part (24, 29). The paper making machine (1) is arranged to direct the at least one waste part (23a, 23b, 30) away from the predetermined path (P) and to convey the remaining part (24, 29) further in the machine direction (MD) along the predetermined path (P). The paper making machine (1) further comprises a blowing device (20, 21, 22) arranged to blow gas or air against the water jet cutting device (17, 18, 19) in a direction toward the remaining part of the fibrous web (24, 29) such that fiber particles that have been released by the cutting action of the water jet cutting device (17, 18, 19) are blown onto the surface (25) of the remaining part (24, 29) of the fibrous web (W) and follow the remaining part (24, 29) of the fibrous web along the predetermined path (P). The invention also relates to a method in which gas or air is blown in a direction toward the remaining part of the web such that fiber particles that have been released by the cutting action of the water jet cutting device (17, 18, 19) are blown onto the surface (25) of the remaining part (24, 29) of the fibrous web (W). The stream of air or gas is given a shape which is circular cylindrical or conical and expanding in the direction in which the stream moves.

Slabbing machine for removing material M wound around a reel R, comprising a frame; a structure for holding the material M wound around the reel R; a beam connected to the frame and displaceable along the frame in a radial direction y; a blade holder connected to the beam and displaceable along the beam in a longitudinal direction x perpendicular to the radial direction y; a blade mounted on the blade holder for cutting the material M down to a cutting plane p perpendicular to the radial direction y and located at the farthest end of the blade in radial direction y; wherein one or several air outlets are mounted on the blade holder 1 and directed towards the cutting plane p for blowing air towards the cutting plane p.

A separator (10) for separating waste (820) from product (810; 2302) in a pre-cut substrate (2600) having one or more cut lines. An inlet feeder feeds the substrate (2600) into the separator (10) along a material path. A separation edge (2500) is disposed in a location downstream of the inlet feeder and defines a line below the plane of the material path. A plurality of punch tools (30; 1800; 1900; 2000) above the plane of the material path, upstream of the separation edge (2500), each has an actuator configured to position the tool in an extended configuration with a contact end of the punch tool (30; 1800; 1900; 2000) disposed below the separation edge (2500), and a retracted configuration with the contact end disposed above the plane of the material path. A controller commands each actuator to position the corresponding punch tool (30; 1800; 1900; 2000) contact end synchronized with the position of the pre-cut substrate (2600) to cause the separation edge (2500) to separate the waste (820) from the product (810; 2302) along the cut lines.

A label processing apparatus including a head configured to cause a wire pin to move toward and away from a label medium for performing processing on the label medium, a first wall member located at a position in a first direction from the transport path surface including a first communication hole communicating with outside, and a fan configured to blow air onto a ventilation region including a region located at the head side of the first surface in the transport direction, and to then cause the air to be discharged to the outside through the first communication hole.

A paper-feeding cutting machine is provided. The paper-feeding cutting machine includes a frame and a machine head. The frame is provided with a paper-loading platform, a cutting table, a receiving hopper and a crossbeam, wherein a linear guide rail is disposed on both sides of the frame, and the cross beam is connected to the linear guide rail. The machine head is disposed on the crossbeam. The machine head includes a fixing plate, a cutter holder, a cutting component, a machine head lifting mechanism and a machine head rotating mechanism. A cutter holder guide rode is disposed on the fixing plate; the cutter holder is connected to the cutter holder guide rode; the machine head lifting mechanism is connected to the cutter holder; the cutting component comprises at least two cutter head assemblies mounted on the cutter holder; the machine head rotating mechanism is connected to the cutter head assemblies.