Systems and methods for cutting and cooking a substance are disclosed. Exemplary implementations may: convey, via a primary conveying subsystem, a layer of food substance along a conveyance path along which the layer of food substance is conveyed; cut, via a cutter, the layer of food substance into food pieces; apply, via a primary pressurized fluid outlet, primary pressurized fluid such that the food pieces are released from the cutter; heat, via the heating mechanism, a chamber; apply, via a secondary pressurized fluid outlet, secondary pressurized fluid so that the food pieces are held flat to the primary conveying substrate, and hold, via a secondary conveying subsystem, the layer of food substance flat between the primary conveying substrate and a secondary conveying substrate for at least a portion of the chamber.

Devices, kits, and methods for manipulating crayons to make various crayon configurations are provided. Embodiments of the invention include a crayon slicer, a crayon shaver, a crayon holder, a crayon notcher, a crayon shaving kit, and a crayon rubbing kit. The multiple embodiments of the invention have various features that allow for a crayon to be easily and safely manipulated by a user in multiple ways. Further, additional embodiments provide additional features, which allow the user to make various crayon configurations.

Devices, kits, and methods for manipulating crayons to make various crayon configurations are provided. Embodiments of the invention include a crayon slicer, a crayon shaver, a crayon holder, a crayon notcher, a crayon shaving kit, and a crayon rubbing kit. The multiple embodiments of the invention have various features that allow for a crayon to be easily and safely manipulated by a user in multiple ways. Further, additional embodiments provide additional features, which allow the user to make various crayon configurations.

A machine and a method of manufacturing the machine are provided. The machine comprises a sensor, a plurality of tools and a processor. The sensor is configured to detect a sheet of a bundle of sheets. The bundle of sheets includes at least a first sheet having a first edge and a second sheet having a second edge, and the sheet is any one of the first sheet and the second sheet. The plurality of tools removably is disposed in a tool housing. Each tool of the plurality of tools corresponds to at least an operation of a plurality of operations, and each tool of the plurality of tools is arranged to perform the operation on the sheet. The processor configured to position the sheet and to selectively actuate at least one tool of the plurality of tools to cause performance of at least one operation at a first location on the first sheet and at a second location on the second sheet, and wherein the first location and second location are determined by the processor based on a first input to obliquely aligned the first edge and the second edge upon aligning the first location and second location.

A machine and a method of manufacturing the machine are provided. The machine comprises a sensor, a plurality of tools and a processor. The sensor is configured to detect a sheet of a bundle of sheets. The bundle of sheets includes at least a first sheet having a first edge and a second sheet having a second edge, and the sheet is any one of the first sheet and the second sheet. The plurality of tools removably is disposed in a tool housing. Each tool of the plurality of tools corresponds to at least an operation of a plurality of operations, and each tool of the plurality of tools is arranged to perform the operation on the sheet. The processor configured to position the sheet and to selectively actuate at least one tool of the plurality of tools to cause performance of at least one operation at a first location on the first sheet and at a second location on the second sheet, and wherein the first location and second location are determined by the processor based on a first input to obliquely aligned the first edge and the second edge upon aligning the first location and second location.

A cutting apparatus includes a chuck table for holding a workpiece, a cutting blade for cutting the workpiece which is held by the chuck table, and a blade cover disposed in covering relation to an outer circumference of the cutting blade. The workpiece is cut in a dry state by the cutting blade while cut dusts produced from the workpiece and rotating with the cutting blade are being discharged through a tubular member under suction by a cut dusts retrieving unit mounted on the blade cover.

A device for cutting a length of pipe includes a clamp portion for clamping around a length of pipe and a bow moveable with respect to the clamp portion that retains a loop of diamond embedded wire. The device further includes a feed for driving the bow with respect to the clamp portion and a detector for detecting bending of the wire and a control responsive to the detector for controlling feed rates. The device is made of modular parts and has synchronizing arms for clamping around a length of pipe. In one embodiment, the wheels are retained in enclosures with slots through which the cutting wire passes.

A workpiece processing device includes a workpiece supporting unit configured to support a workpiece so that the workpiece is rotatable around a first axis parallel to a central axis of the workpiece, a cutting unit having a blade configured to cut a surface of the workpiece, a detecting unit configured to calculate a position of a vertex of the surface in a direction along a second axis which is perpendicular to the first axis and parallel to the blade, and a control unit configured to control the workpiece supporting unit so that a cutting position on the surface is located at a vertex in the direction along the second axis, and relatively move the workpiece supporting unit and the cutting unit so that an incision direction of the blade is on a plane defined by the central axis and the cutting position, thereby forming a groove at the cutting position.

A workpiece processing device includes a workpiece supporting unit configured to support a workpiece so that the workpiece is rotatable around a first axis parallel to a central axis of the workpiece, a cutting unit having a blade configured to cut a surface of the workpiece, a detecting unit configured to calculate a position of a vertex of the surface in a direction along a second axis which is perpendicular to the first axis and parallel to the blade, and a control unit configured to control the workpiece supporting unit so that a cutting position on the surface is located at a vertex in the direction along the second axis, and relatively move the workpiece supporting unit and the cutting unit so that an incision direction of the blade is on a plane defined by the central axis and the cutting position, thereby forming a groove at the cutting position.

The invention relates to a holding device for fastening polymeric motor-vehicle bumpers during a machining operation, in particular a punching operation, comprising a main frame and a fastening device for fastening the bumper on the main frame. According to the invention, the fastening device has at least one fastening-arm group having at least two fastening arms movable independently of each other for different bumper models, wherein the fastening arms have different contact contours that lie against the corresponding bumper model (1) in the fastening position and the contact contour of each fixing arm is matched to the local shape of a specific bumper model.