A method for producing workpiece parts from a plate-shaped workpiece in a processing machine or laser processing machine includes positioning and holding the workpiece on a workpiece support by clamping devices. A plurality of workpiece parts are cut out of the workpiece with a process beam. The process beam is moved relative to the workpiece support by a processing head and/or the workpiece is moved relative to the workpiece support by the clamping devices. A cutting process for processing the workpiece to produce the workpiece parts is interrupted at least once by a relaxation step for the workpiece. During the relaxation step at least one clamping device is released to relax the workpiece. The at least one clamping device is closed following the relaxation and before continuing the cutting process. A data processing program and a processing machine for producing the workpiece parts are also provided.

A method and machine for cutting and removing a workpiece part from a plate-shaped material includes cutting the workpiece part with a beam or jet directed onto the material and separating the workpiece part and material. The workpiece part is removed as a scrap skeleton removal part. The cut-free workpiece part is lifted out of a workpiece supporting plane by a lifting device and removed by a gripping device, or the cut-free workpiece part is removed downwards from the plane through a gap between workpiece supporting surfaces by an ejection device, or gravity removes the cut-free workpiece part downwards through the gap. Before cutting the workpiece part free, a sacrificial part adjoining the workpiece part and partially having a common cutting line with the workpiece part is cut free from the material before cutting the workpiece part free in the material or scrap skeleton.

Automated systems and methods for making cuts in large materials, particularly to trim and reduce the sizes of steel plates and slabs and produce therefrom one or more reduced-size pieces, optionally with the ability to reduce or avoid the need to perform a separate deburring operation on the materials after undergoing such cuts. Such a system includes multiple support units aligned in a longitudinal direction of a foundation and longitudinal and cross cutting units translatable in the longitudinal direction for performing, respectively, longitudinal and lateral cuts in a material. The support units are independently translatable in the longitudinal direction and each support unit has a crossmember that extends in the lateral direction, is adapted to at least partially support the material, and is operable to be raised and lowered in the vertical direction while the material is supported by the crossmembers.

Automated systems and methods for making cuts in large masses of materials, including lateral cuts to reduce the lengths of steel slabs and produce therefrom slabs of desired sizes for producing steel plates. Such a system includes an apparatus having a support that supports the material, and a torch arm translatable in a Y-direction of the material and supporting a torch that emits a torch flame to make a cut in a Z-direction of the material while supported by the support. The apparatus has a deburring device associated with the torch arm and translatable in the Y-direction to perform a deburring operation by emitting an oxidizing gas stream that simultaneously removes burrs along the lateral cut produced by the torch in synchrony with translation of the torch in the Y-direction as the lateral cut is produced by the torch to oxidize the burrs before the burrs solidify.

Provided is a cutting machine that cuts a high-temperature moving object to be cut while moving in synchronization with the movement of the object to be cut, and that is capable of effectively protecting itself from the heat of the object to be cut and effectively utilizing the heat. A cutting machine for cutting a high-temperature moving object to be cut while moving in synchronization with the movement of the object to be cut, comprising: a cutter configured to cut the object to be cut; a movement device configured to move the cutting machine in synchronization with the object to be cut; a water-cooling plate configured to cool the cutting machine; and a thermoelectric power generation device including a thermoelectric element for converting the heat of the object to be cut into electric energy, wherein the water-cooling plate also serves to cool a low-temperature side of the thermoelectric element.

A method and an apparatus efficiently and reliably cut a steel frame. The cutting method includes locating a cutting torch apart from the steel frame held by a holding device in a direction along a cutting surface, moving the cutting torch from a cutting start position to a first cutting end position in a first feed direction perpendicular to a supply direction along the cutting surface, while applying a flame from a fire port of the cutting torch in the supply direction and supplying cutting oxygen to thereby cut a part of the cutting surface, stopping the cutting torch at the first cutting end position and thereafter cutting an uncut part by moving the cutting torch from the first cutting end position in a second feed direction opposite to the first feed direction.

Automated systems and methods for making cuts in large masses of materials, including lateral cuts to reduce the lengths of steel slabs and produce therefrom slabs of desired sizes for producing steel plates. Such a system includes an apparatus having a support that supports the material, and a torch arm translatable in a Y-direction of the material and supporting a torch that emits a torch flame to make a cut in a Z-direction of the material while supported by the support. The apparatus has a deburring device associated with the torch arm and translatable in the Y-direction to perform a deburring operation by emitting an oxidizing gas stream that simultaneously removes burrs along the lateral cut produced by the torch in synchrony with translation of the torch in the Y-direction as the lateral cut is produced by the torch to oxidize the burrs before the burrs solidify.

Automated systems and methods for making cuts in large materials, particularly to trim and reduce the sizes of steel plates and slabs and produce therefrom one or more reduced-size pieces, optionally with the ability to reduce or avoid the need to perform a separate deburring operation on the materials after undergoing such cuts. Such a system includes multiple support units aligned in a longitudinal direction of a foundation and longitudinal and cross cutting units translatable in the longitudinal direction for performing, respectively, longitudinal and lateral cuts in a material. The support units are independently translatable in the longitudinal direction and each support unit has a crossmember that extends in the lateral direction, is adapted to at least partially support the material, and is operable to be raised and lowered in the vertical direction while the material is supported by the crossmembers.

Provided is a cutting machine that cuts a high-temperature moving object to be cut while moving in synchronization with the movement of the object to be cut, and that is capable of effectively protecting itself from the heat of the object to be cut and effectively utilizing the heat. A cutting machine for cutting a high-temperature moving object to be cut while moving in synchronization with the movement of the object to be cut, comprising: a cutter configured to cut the object to be cut; a movement device configured to move the cutting machine in synchronization with the object to be cut; a water-cooling plate configured to cool the cutting machine; and a thermoelectric power generation device including a thermoelectric element for converting the heat of the object to be cut into electric energy, wherein the water-cooling plate also serves to cool a low-temperature side of the thermoelectric element.

A torch cutting machine comprising a longitudinal travel way, a main carriage that travels along the travel way, and a boom assembly extending from the main carriage perpendicular to the travel way, the boom assembly comprising at least one cutting torch extending from a main boom. The boom assembly is rotatable with respect to the main carriage. Also, a method of cutting metal material where a boom of a torch cutting machine having a cutting torch extending therefrom, is placed over metal material in a first cutting bed, which is cut by moving the cutting torch. The boom is rotated 180 and positioned over material in a second cutting bed, which is cut in the same manner. Cut material is removed from the first cutting bed and new material is placed in the first cutting bed while the cutting of the material in the second cutting bed is being performed.