A method for manufacturing a belt-shaped cord member by cutting a rubber topped fabric produced by covering a topping rubber on an interdigitated fabric formed by interweaving many warp textile cords and few wefts to a predetermined width, comprising; an interdigitated fabric forming step of arranging a cord having conductivity for every predetermined number of the many warp textile cords which is then interwoven with the weft yarn, a rubber topped fabric producing step of topping rubber on the front and back surfaces of the interdigitated fabric, and a cutting step of cutting the produced rubber topped fabric by every predetermined number of the textile cords, wherein, in the cutting step, the rubber topped fabric is cut along the textile cord in which a cord having conductivity is arranged, after the position of the textile cords is specified by energizing the rubber topped fabric.

A food cutter assembly can include a spindle body defining an interior passage for receiving a food product. A cutting tool can be connected to an end of the spindle body for cutting the food product. The food cutter assembly can also include a housing for rotationally mounting the spindle body. Rotation of the spindle body can be controlled by one or more magnets mounted to the spindle body and by a stator and/or pulley magnetically or electromagnetically coupled with the magnet to drive the one or more magnets about a rotational axis, which in turn spins the spindle body about the rotational axis, driving the rotational cutting motion of the cutting tool.

A food cutter assembly can include a spindle body defining an interior passage for receiving a food product. A cutting tool can be connected to an end of the spindle body for cutting the food product. The food cutter assembly can also include a housing for rotationally mounting the spindle body. Rotation of the spindle body can be controlled by one or more magnets mounted to the spindle body and by a stator and/or pulley magnetically or electromagnetically coupled with the magnet to drive the one or more magnets about a rotational axis, which in turn spins the spindle body about the rotational axis, driving the rotational cutting motion of the cutting tool.

A lift mechanism of a die set apparatus includes a guide pin, a linear motion guide member, a first washer, a second washer, a first coil spring, and a second coil spring. A first positioning portion and a second positioning portion control a first end turn portion and a second end turn portion from moving in a radial direction of the guide pin in a state where a first gap is formed between the first coil spring and the guide pin. A third positioning portion and a fourth positioning portion control a third end turn portion and a fourth end turn portion from moving in the radial direction of the guide pin in a state where a second gap is formed between the second coil spring and the guide pin.

A mechanism is described herein to drive slitter and cutter waste in a direction that allows for a more advantageous use of the waste collection bin's volume. The waste drive mechanism allows for at least one armature that drives the waste in a desired direction. The armature is made from a material that is flexible, with a curved shape to allow a pre-loaded force against a contact surface of the waste collection bin. The pre-loaded flexible armature against a contact surface of the collection bin provides sufficient force to drive the waste it in a desired direction, allowing for a more consistent use of the waste collection bin spatial volume.

A mechanism is described herein to drive slitter and cutter waste in a direction that allows for a more advantageous use of the waste collection bin's volume. The waste drive mechanism allows for at least one armature that drives the waste in a desired direction. The armature is made from a material that is flexible, with a curved shape to allow a pre-loaded force against a contact surface of the waste collection bin. The pre-loaded flexible armature against a contact surface of the collection bin provides sufficient force to drive the waste it in a desired direction, allowing for a more consistent use of the waste collection bin spatial volume.

A hand-held knockout punch driver includes a housing, a motor, a drive assembly with an output member movable relative to the housing, and a head unit removably coupled to the housing. The head unit includes a body, an input member movable relative to the body, and a draw rod to which a punch or a die is attachable. The draw rod is configured to move axially relative to the body in response to movement of the input member relative to the body. The knockout punch driver also includes a quick-release mechanism to removably couple the body to the housing. The output member is configured to engage the input member such that the input member moves relative to the body in response to movement of the output member relative to the housing, and the body engages the quick release mechanism separately from engagement between the output member and the input member.

A stand-alone apparatus for cutting a web of media or tag stock into individual units for use downstream of a printer. The apparatus may cut vinyl, plastic, or RFID stock material in both back and forth directions. The apparatus comprises a housing, a carriage assembly and a movable cutter assembly. The cutter assembly is easily interchangeable and comprises a cutting element such as a wheel blade, and a pressure adjusting element for adjusting the amount of pressure applied by the cutting element to the stock material. Alternatively, the cutter assembly may be manufactured with a predetermined pressure load, but still permit an operator to adjust the depth of cut. The apparatus may be powered by and or in hardline or wireless communication with a printer, or may further comprise a computer microprocessor, memory and user interface to function wholly independent from a printer.

A stand-alone apparatus for cutting a web of media or tag stock into individual units for use downstream of a printer. The apparatus may cut vinyl, plastic, or RFID stock material in both back and forth directions. The apparatus comprises a housing, a carriage assembly and a movable cutter assembly. The cutter assembly is easily interchangeable and comprises a cutting element such as a wheel blade, and a pressure adjusting element for adjusting the amount of pressure applied by the cutting element to the stock material. Alternatively, the cutter assembly may be manufactured with a predetermined pressure load, but still permit an operator to adjust the depth of cut. The apparatus may be powered by and or in hardline or wireless communication with a printer, or may further comprise a computer microprocessor, memory and user interface to function wholly independent from a printer.

A system and method relating to a slicer system, the slicer system includes a slicer that includes a slider blade, a first motor configured to rotate the slicer blade, an in-feed table configured to hold the product and move, while the product is sliced by the slicer blade; an out-feed table configured to receive a sliced portion of a product, in response to the slicer blade slicing the product, at least one second motor, each of the at least one second motor configured to move the out-feed table in at least one direction; and at least one processor configured to cause the sliced portion of the product to be received on the out-feed table in a predetermined shape by controlling the at least one second motor to move the out-feed table while the slicer is slicing the product.