The present invention relates to a sensor device for determining alignment/misalignment of a laser beam relative to a gas nozzle of a laser machining head which comprises a sensor housing provided with mounting means adapted to mount the housing to a laser machining head, a camera device comprising a camera, the camera device is provided in the sensor housing, so that the camera faces the tip of the gas nozzle when the sensor housing is mounted to the laser machining head for visualizing an orifice of the gas nozzle and a pilot laser simultaneously, and output means for outputting image signals obtained by the camera.

A system (40) for processing a workpiece includes a support surface (88) for supporting a workpiece (44). The system (40) includes a processing tool (92) movable with respect to a processing path. The system (40) includes a sensor carriage (408) movable along a scan axis and having a light source (476, 515, 550, 586) located to emit a light beam at an angle to the scan axis onto a target surface of a workpiece (44), and a camera (484, 522, 558, 594) configured to record location data of the light beam on a target surface of a workpiece (44) as the sensor carriage (408) moves along the scan axis. The system (40) includes a control system for generating a three-dimensional point representation of a workpiece surface from the light beam location data, to control movement of the processing tool (92) based on the three-dimensional point representation of a workpiece (44).

An adjustment collar for a laser machine tool includes a first actuator between an outer housing and an inner collar, the first actuator operable to move the inner collar with respect to the outer housing in the X-axis and a second actuator between the outer housing and the inner collar, the second actuator operable to move the inner collar with respect to the outer housing in the Y-axis.

A laser welding device includes: a laser scanner body configured to emit a laser beam to a workpiece; a jet nozzle configured to jet gas so as to cause the gas to cross an optical path of the laser beam emitted from the laser scanner body; and a guide plate disposed on the downstream side in the flow direction of the gas, from the optical path of the laser beam emitted from the laser scanner body. The guide plate is configured to change the flow direction of the gas that has crossed the optical path of the laser beam into a direction away from a laser irradiation position on the workpiece toward the downstream side in the flow direction of the gas.

The present invention relates to a sensor device for determining alignment/misalignment of a laser beam relative to a gas nozzle of a laser machining head which comprises a sensor housing provided with mounting means adapted to mount the housing to a laser machining head, a camera device comprising a camera, the camera device is provided in the sensor housing, so that the camera faces the tip of the gas nozzle when the sensor housing is mounted to the laser machining head for visualizing an orifice of the gas nozzle and a pilot laser simultaneously, and output means for outputting image signals obtained by the camera.

Laser processing machines, such as laser cutting machine, including a work table receiving workpiece, and work arm with a laser cutting head. Laser cutting head includes nozzle receiving device and nozzle. Via nozzle laser beam may be directed onto work piece. Machine includes main drives moving work arm and/or the laser cutting head on X-Y-Z axes to process work piece, as well as an alignment unit to adjust laser beam. An adjusting station includes receiving unit fixing nozzle and/or the nozzle receiving device during centering of nozzle. The alignment unit has head element in laser cutting head. Head element receives nozzle and/or the nozzle receiving device and is slidable in X-Y directions, via the main drives. Head element may be fixed in a selected position, within the laser cutting head, via clamping device releasable during nozzle centering at adjusting station.

A method of monitoring an operation status of a confined laser cutting tool includes emitting light in the form of laser beams from a laser source. The method includes using a nozzle to form a confining column composed of a liquid. The method further includes forming a confined laser beam, the confined laser beam defined by the confluence of the laser beams and the confining column. The method also includes sensing a characteristic of the confined laser beam with a sensor. The method further includes determining the operation status of the confined laser cutting tool based on the sensed characteristic of the confined laser beam. The method also includes deactivating the laser source when the sensed characteristic of the confined laser beam reaches a predetermined threshold. The method may also include providing an operator notification after deactivating the laser source.

A workpiece positioning system for holding and manipulating a workpiece. The system includes a rail, a headstock assembly, and a tailstock assembly. The tailstock assembly is mountable to the rail in spaced relation to the headstock assembly to enable the workpiece to be supported between the headstock assembly and the tailstock assembly. The tailstock assembly includes a locking mechanism operable between a locking position in which the tailstock assembly is lockable against the rail in a desired position relative to the headstock, and an unlocked position in which the tailstock assembly is adapted to traverse the rail. The invention also provides a powder injection nozzle having a body and aa tube releasably connected to the body. The tube defines a through passage having at least one inlet for receiving a cladding material and an outlet for delivering the cladding material from the tube.

Laser processing machines, such as laser cutting machine, including a work table receiving workpiece, and work arm with a laser cutting head. Laser cutting head includes nozzle receiving device and nozzle. Via nozzle laser beam may be directed onto work piece. Machine includes main drives moving work arm and/or the laser cutting head on X-Y-Z axes to process work piece, as well as an alignment unit to adjust laser beam. An adjusting station includes receiving unit fixing nozzle and/or the nozzle receiving device during centering of nozzle. The alignment unit has head element in laser cutting head. Head element receives nozzle and/or the nozzle receiving device and is slidable in X-Y directions, via the main drives. Head element may be fixed in a selected position, within the laser cutting head, via clamping device releasable during nozzle centering at adjusting station.

A method of monitoring an operation status of a confined laser cutting tool includes emitting light in the form of laser beams from a laser source. The method includes using a nozzle to form a confining column composed of a liquid. The method further includes forming a confined laser beam, the confined laser beam defined by the confluence of the laser beams and the confining column. The method also includes sensing a characteristic of the confined laser beam with a sensor. The method further includes determining the operation status of the confined laser cutting tool based on the sensed characteristic of the confined laser beam. The method also includes deactivating the laser source when the sensed characteristic of the confined laser beam reaches a predetermined threshold. The method may also include providing an operator notification after deactivating the laser source.