The invention discloses an automatic tool aligning system based on a spectral confocal displacement sensor. The system comprises three-dimensional mobile platform, tool aligning component based on the spectral confocal displacement sensor, clamping device, machine tool and the control module. The three-dimensional mobile platform is fixed on the outer side of the machine tool, the tool aligning component is connected with the three-dimensional mobile platform, the clamping device used to clamp the workpiece is fixed on the center of the machine tool through mechanical connection, and the spectral confocal displacement sensor is connected with the control module. After judging the collected working condition data, the control module outputs a control instruction to the three-dimensional mobile platform.

The invention discloses an automatic tool aligning system based on a spectral confocal displacement sensor. The system comprises three-dimensional mobile platform, tool aligning component based on the spectral confocal displacement sensor, clamping device, machine tool and the control module. The three-dimensional mobile platform is fixed on the outer side of the machine tool, the tool aligning component is connected with the three-dimensional mobile platform, the clamping device used to clamp the workpiece is fixed on the center of the machine tool through mechanical connection, and the spectral confocal displacement sensor is connected with the control module. After judging the collected working condition data, the control module outputs a control instruction to the three-dimensional mobile platform.

In a self-detecting apparatus for workpiece-origin, a mobile machine tool having the self-detecting apparatus, a method for self-detecting the workpiece-origin, the self-detecting apparatus is equipped to the mobile machine tool and includes a vision sensor and a transmitting unit. The vision sensor obtains a point image marked to the workpiece, and detects a position of a workpiece-origin based on coincidence of focuses of the points. The transmitting unit provides an information obtained by the vision sensor to the mobile machine tool. The mobile machine tool is moved to the workpiece-origin, so as to coincide the focuses of the points, based on the provided point image obtained by the vision sensor.

In a self-detecting apparatus for workpiece-origin, a mobile machine tool having the self-detecting apparatus, a method for self-detecting the workpiece-origin, the self-detecting apparatus is equipped to the mobile machine tool and includes a vision sensor and a transmitting unit. The vision sensor obtains a point image marked to the workpiece, and detects a position of a workpiece-origin based on coincidence of focuses of the points. The transmitting unit provides an information obtained by the vision sensor to the mobile machine tool. The mobile machine tool is moved to the workpiece-origin, so as to coincide the focuses of the points, based on the provided point image obtained by the vision sensor.

A method of correcting a track of a cutting edge is provided. With movement of the cutting edge, a point on the cutting edge in contact with the rotation symmetry plane is moved along the cutting edge from a first end portion of the cutting edge to a second end portion of the cutting edge opposite to the first end portion. The correction method includes measuring, by a measurement unit, a shape of the cut and machined rotation symmetry plane, calculating, by an operation unit, an error of the measured shape of the rotation symmetry plane from a target shape of the rotation symmetry plane in a direction of the axial line of rotation, and correcting, by the operation unit, a component in the direction of the axial line of rotation of a track of a point of cutting based on the error.

Systems and methods for lathe and tooling calibration are disclosed. A sensor is utilized to measure dimensions and operational parameters of one or more components of a lathe, such as a turret, tool stations, and/or a spindle. Tool measurements are received and analyzed along with the measurements from the sensor. The dimensions and operational parameters may be utilized to calibrate movement parameters of one or more components of the lathe. Once calibrated, the lathe may be utilized to tool one or more objects.

A numerical control device for a machine tool controls a machine tool having a main spindle for attaching a tool, a table holding a workpiece and a jig, three translational axes, and one or more rotation axis. The numerical control device includes an axis-dependent deformation error estimation unit, an input unit, a gravitational deformation estimation unit, a correction value calculation unit, and an addition unit. The correction value calculation unit calculates a correction value of the translational axes and/or the rotation axis with respect to an error of a position and/or a posture of the tool with respect to the workpiece, based on an estimated value of an axis-dependent deformation error, an estimated value of a gravitational deformation error, and command values. The addition unit adds the correction values to the command values.

A numerical control device for a machine tool controls a machine tool having a main spindle for attaching a tool, a table holding a workpiece and a jig, three translational axes, and one or more rotation axis. The numerical control device includes an axis-dependent deformation error estimation unit, an input unit, a gravitational deformation estimation unit, a correction value calculation unit, and an addition unit. The correction value calculation unit calculates a correction value of the translational axes and/or the rotation axis with respect to an error of a position and/or a posture of the tool with respect to the workpiece, based on an estimated value of an axis-dependent deformation error, an estimated value of a gravitational deformation error, and command values. The addition unit adds the correction values to the command values.

A control device, linear drive, production- or packaging machine, computer program product and method for controlling movement of at least one rotor in the linear drive, wherein a user or a machine station specifies the movement pattern to the control device to specify the movement, where the specified movement pattern is associated with virtual axes, particularly via the computer program product, the movement pattern is advantageously automatically associated with virtual axes subsequently associated with real axes, a control unit, i.e., a converter, controls movement of the rotor on the segment of the linear drive and the control unit supplies at least one segment with electrical voltage or current, where the segments as part of the linear drive therefore move the rotors in accordance with the specifications of the movement pattern, where such an association occurs automatically, and the user is relieved of this task during specification of the movement pattern.

A method for moving a rotor onto a segment, a linear drive, a production machine, a machine tool, and a packaging machine comprising such a linear drive, wherein the actual speed of the rotor is ascertained using a sensor paired with the segment when the rotor is moved onto the segment, where the actual speed is selected by a control unit as the first target speed for the rotor, and after the target speed has been determined for the rotor, the regulation of the actual speed is activated for the rotor, and where the actual speed of the rotor is then regulated in accordance with a conventional rule, wherein a rule variable is the ascertained actual speed and/or the position of the rotor such that jerking or an undesired acceleration is prevented during transition of the rotor onto the segment.