A method for automatically adapting an adaptable process parameter of a tooling machine, the tooling machine being part of a first or second manufacturing process for physically processing input work pieces into output work pieces. According to the method, at least one geometric feature of an output work piece is measured by a coordinate measuring machine, the geometric feature being a direct or indirect result of the processing with the tool. The measurement result is together with nominal measurement data of the geometric feature fed into a deterministic digital simulation of at least a part of the manufacturing process with a digital model such as a digital twin of the tooling machine and modelled process parameters, therein the adaptable process parameter of the tooling machine, simulating at least a deterministic behavior of the tooling machine relevant for an operation of its tool.

The invention relates to a manipulator having a manipulator arm (5) at the one free end (6) of which a manipulator flange (8) is provided on which an end effector (46) having an application device (9) for machining a workpiece (37) is held. The manipulator flange (8) is rotatable about hand axes (20, 21, 22). A first hand axis (20) extends in the direction of the longitudinal axis (18) of the manipulator arm (5), a second hand axis (21) extends transversely to the first hand axis (20) and a third hand axis (22) extends transversely to the second hand axis (21), wherein the hand axes (20, 21, 22) intersect one another in a common intersection point (26). A machining force (33) acting on the application device (9) is diverted into the manipulator arm (5) by way of the end effector (46). So that process forces occurring during a mechanical operation do not lead to an impairment of the machining pose of the manipulator arm (5), provision is made to fix the application device (9) to the manipulator flange (8) at an attachment angle (30) to the first hand axis (20) in such a way that a machining force (33) occurring at the application device (9) is diverted in a direction (31) towards the manipulator arm (5), which direction extends through the intersection region (25) of the hand axes (20, 21, 22).

The present invention provides for a wall mountable system for automated drawing of an image upon a wall which includes a horizontal mounting track for mounting on a wall, a robot having a y-track rigidly mounted it where the robot and the mounted y-track travel along the horizontal track. An end effector, which includes a pen holding mechanism holding a pen, is in electrical communication with the robot and travels along the y-track of the robot. The present invention provides a system and device that can attach to a wall or vertical surface in a damage-free manner and draw fast any complexity or style image of custom size in both the horizontal (X) and vertical (Y) directions, that is easy to remove and transport and require small floor space to operate.

The invention relates to a system and method for changing liners of a mill, the configuration of which allows the automated robotic manipulation of liners of mills for ore grinding in comminution processes. The configuration and operation of the system allows the task of manipulation to be improved, having a greater degree of freedom and/or flexibility in its movements, thereby providing a greater degree of certainty and efficiency to the method and thus optimising the time that the mill is halted for maintenance, and also preventing the risks to which maintenance staff may be exposed. The system comprises at least one support structure, at least one system for supplying and moving liners, at least one robotic manipulator system for manipulating the liners, at least one liner manipulation tool, at least one artificial vision system, and at least one control system.

A manipulator has a manipulator arm with a manipulator flange at one free end. The flange holds an end effector having an application device for machining a workpiece. The manipulator flange is rotatable about hand axes. A first hand axis extends in the direction of the longitudinal axis of the manipulator arm, a second hand axis extends transversely to the first hand axis and a third hand axis extends transversely to the second hand axis. The hand axes intersect at a common intersection point. A machining force acting on the application device is diverted into the manipulator arm by way of the end effector. So that process forces during a mechanical operation do not lead to impairment of the machining pose of the manipulator arm, provision is made to fix the application device to the manipulator flange at an attachment angle to the first hand.

The present invention provides for a wall mountable system for automated drawing of an image upon a wall which includes a horizontal mounting track for mounting on a wall, a robot having a y-track rigidly mounted it where the robot and the mounted y-track travel along the horizontal track. An end effector, which includes a pen holding mechanism holding a pen, is in electrical communication with the robot and travels along the y-track of the robot. The present invention provides a system and device that can attach to a wall or vertical surface in a damage-free manner and draw fast any complexity or style image of custom size in both the horizontal (X) and vertical (Y) directions, that is easy to remove and transport and require small floor space to operate.

A dummy tool is used to teach a robot the path the robot will follow to perform work on a workpiece to eliminate the possibility of damaging an actual tool during the training. The dummy tool provides the robot programmer an indication of potential collisions between the tool and the workpiece and other objects in the work cell when path is being taught. The dummy tool can have a detachable input/output device with a graphic user interface (GUI) that can communicate wirelessly with the robot controller. The dummy tool can also have a moveable camera attached thereto to track the relationship of the tool to objects in the work area.

A dummy tool is used to teach a robot the path the robot will follow to perform work on a workpiece to eliminate the possibility of damaging an actual tool during the training. The dummy tool provides the robot programmer an indication of potential collisions between the tool and the workpiece and other objects in the work cell when path is being taught. The dummy tool can have a detachable input/output device with a graphic user interface (GUI) that can communicate wirelessly with the robot controller. The dummy tool can also have a moveable camera attached thereto to track the relationship of the tool to objects in the work area.

The present invention relates to a method and a system for manufacturing a board body (10), such as a skateboard, from a blank (20) having an indefinite shape. The blank (20) with the indefinite shape is collected by a handling robot (50). The shape of the blank (20) is scanned in three dimensions by means of a vision system (47) and a virtual image of said blank (20) is stored in a memory and used to calculate a three dimensional cutting path for milling the blank (20) into said board body (10).

The invention relates to a system and method for changing liners of a mill, the configuration of which allows the automated robotic manipulation of liners of mills for ore grinding in comminution processes. The configuration and operation of the system allows the task of manipulation to be improved, having a greater degree of freedom and/or flexibility in its movements, thereby providing a greater degree of certainty and efficiency to the method and thus optimising the time that the mill is halted for maintenance, and also preventing the risks to which maintenance staff may be exposed. The system comprises at least one support structure, at least one system for supplying and moving liners, at least one robotic manipulator system for manipulating the liners, at least one liner manipulation tool, at least one artificial vision system, and at least one control system.