A method of machining an elongate workpiece extending along a longitudinal axis and shaped to be supported rotationally instably about the longitudinal axis includes sensing a rotation of the workpiece about the longitudinal axis, thereby yielding a sensing result; and machining the workpiece at the machining station at least partly in dependence of the sensing result.

A method for controlling a cutting tool in a CNC machine and a device using the method receives contours of workpieces generated by a first measuring machine, inputs the first contour parameters into a calculation model to output first compensation values of the cutting tool, the calculation model being a time sequences model established according to contour sets of the workpieces, and the contour sets include at least one historical contour of the workpieces. The device further determines whether the first compensation values of the cutting tool are greater than, equal to or smaller than a preset value, and sends the first compensation values of the cutting tool to a machine.

A method and apparatus for machining a part for an assembly. First sensor data is acquired for a surface of a first part from a first sensor system. Second sensor data is acquired for a set of existing holes in a second part from a second sensor system. A surface model of the surface of the first part is generated using the first sensor data. First offset data is computed based on a nominal model of a third part that is nominally positioned relative to the surface model within a three-dimensional virtual environment. Second offset data is computed for the set of existing holes using the second sensor data. Overall offset data is generated using the first and second offset data, wherein the overall offset data is used to drill a set of holes in the third part for use in fastening the third part to the second part.

A method for controlling a cutting tool in a CNC machine and a device using the method receives contours of workpieces generated by a first measuring machine, inputs the first contour parameters into a calculation model to output first compensation values of the cutting tool, the calculation model being a time sequences model established according to contour sets of the workpieces, and the contour sets include at least one historical contour of the workpieces. The device further determines whether the first compensation values of the cutting tool are greater than, equal to or smaller than a preset value, and sends the first compensation values of the cutting tool to a machine.

The present invention relates to a checking tool and a method for checking whether a laser cutting machine is provided with a correct workpiece from a set of workpieces, comprising the method steps of: Detecting actual workpiece properties of a workpiece which is provided or is prepared to be provided to the laser cutting machine for cutting; Providing a set of cutting plans, wherein one cutting plan of the set of cutting plans is forwarded to a control unit of the laser cutting machine, wherein each cutting plan is associated to target workpiece properties; Comparing the detected actual workpiece properties with the target workpiece properties, and providing a comparison result, indicating whether the correct workpiece is provided according to the cutting plan; Depending on the comparison result: Issuing a stop signal to stop the cutting process or issuing an adaption signal to change the sequence in the set of cutting plans.

The invention relates to a grinding and/or erosion machine (10), as well as to a method for gauging and referencing the axis arrangement (11) comprising several machine axes (12), wherein each can be configured as a rotational or translational machine axis. To do so, a measuring disk (28) is inserted in a tool spindle (13) and a test mandrel (27) is inserted in a workpiece holding device (14). The test mandrel (27) is electrically connected to a reference potential, preferably ground (M). The measuring disk (28) is electrically connected to a supply voltage potential (UV). By forming a contact between the measuring disk (28) and the test mandrel (27), a measuring current (IM) flows between the supply voltage potential (UV) and the reference potential and, in accordance with the example, from the supply voltage potential (UV) to ground (M). The flow of this measuring current (IM) may be detected in a monitoring device (31), and the actual position of the machine axes (12) at the time of the start of the current flow of the measuring current (IM) can be determined. Via the axis arrangement (11), one or more contact locations (K) between the measuring disk (28) and the test mandrel (27) can be approached, and, as a result of this, referencing or gauging of the axis arrangement (11) and the machine, respectively, can take place.

A system and method for calibrating a manufacturing machine that includes a leveling device including a machine base interface to a manufacturing machine, a support system that comprises of a set of linearly actuating supports, a workpiece interface, and wherein actuation of supports collectively adjusts the orientation of the workpiece interface with two degrees of angular freedom; and a calibration system with sensors configured to measure the orientation of the workpiece interface.

A method of removing features from a cast workpiece includes generating a nominal toolpath for machining the cast workpiece. The cast workpiece is mounted onto a platform of a computer numeric control machine. The cast workpiece is inspected with a probe to generate probe data. Features to be removed are identified based upon the probe data generated during the inspection. Any expected features of the cast workpiece that are missing from the cast workpiece are identified. A transformation matrix is applied to the nominal toolpath with a controller of the computer numeric control machine, wherein the transformation matrix is based upon the probe data. Alignment of the cast workpiece is adjusted relative to the computer numeric control machine based on the transformation matrix with the computer numeric control machine. Features are removed from the cast workpiece that were identified during inspection.

A method of removing features from a cast workpiece includes generating a nominal toolpath for machining the cast workpiece. The cast workpiece is mounted onto a platform of a computer numeric control machine. The cast workpiece is inspected with a probe to generate probe data. Features to be removed are identified based upon the probe data generated during the inspection. Any expected features of the cast workpiece that are missing from the cast workpiece are identified. A transformation matrix is applied to the nominal toolpath with a controller of the computer numeric control machine, wherein the transformation matrix is based upon the probe data. Alignment of the cast workpiece is adjusted relative to the computer numeric control machine based on the transformation matrix with the computer numeric control machine. Features are removed from the cast workpiece that were identified during inspection.

The invention relates to a method for correcting a predetermined cutting path for cutting a metal blank from a metal strip continuously transported in a transport direction x with the following steps: Simultaneously determining a first x coordinate x1 and a first y coordinate y1 of a point on a surface of the metal strip with respect to an x and a y reference; Determining a second coordinate y2 of the point with respect to the y reference at precisely the time when the metal strip has been moved in the transport direction x by a predetermined first distance dx1 with respect to the first x coordinate x1; Determining a first y correction value K.sub.y1 by taking the difference between the first y coordinate y1 and the second y coordinate y2; and Using the first y correction value K.sub.y1 to correct the cutting path coordinates describing the predetermined cutting path.