The invention relates to a screwing device, including a storage container for screws having a screw head, a screw head drive, and a threaded pin, a robot manipulator having an effector, which is adapted to the screw head and the screw head drive, and is embodied and configured to pick up and handle such a screw, an isolating unit connected to the storage container, which provides screws from the storage container isolated at an interface at a known position in such a way that a respective screw head is accessible to the effector, a control unit for controlling/regulating the robot manipulator, wherein the control unit is embodied and configured to execute the following first control program: the effector is guided by the robot manipulator along a predetermined trajectory T1 having a target orientation O.sub.target,T1(R.sub.T1) to the screw head of a screw provided at the interface, wherein along the trajectory T1 for locations R.sub.T1 of the trajectory T1, the target orientation O.sub.target,T1(R.sub.T1) of the effector is defined, wherein to pick up the screw head in the effector, force-regulated and/or impedance-regulated and/or admittance-regulated rotational movements and/or tilting movements and/or translational movement patterns of the effector in relation to its target orientation are executed by the robot manipulator until a predetermined limiting value condition G1 for a torque acting on the effector and/or a predetermined limiting value condition G2 of a force acting on the effector and/or a limiting value condition G3 for a time for carrying out the rotational and/or tilting movements and/or translational movement patterns is reached or exceeded and/or a provided force/torque signature and/or a position/speed/acceleration signature at the effector is reached or exceeded, which indicates/indicate that the picking up of the screw by the effector has been successfully completed within predefined tolerances.

An electric motor-driven screwdriver includes a control circuit having a memory stored with setting data and a computing unit controlling the electric motor-driven screwdriver based on the setting data. The computing unit sets an execution order of work processes based on a pre-designated piece of order setting data, and sets, based on a next operation setting value, a next operation to be performed after completion of the final work process. The next operation setting value is selectable from among a setting value for stopping the operation of the electric motor-driven screwdriver, a setting value for repeating a series of work processes, and a setting value for shifting to a series of work processes in an execution order determined based on another piece of order setting data.

A tool is equipped with a torque sensor, suited for a tightening task of a fastening component of a device such as a fluid control system that requires a large number of fastening components for assembly and has a narrow space for access to the fastening components, and capable of automatically detecting a tightening torque. The tool includes a torque sensor capable of detecting a tightening torque for tightening a fastening component acting on a bit. The torque sensor initiates measurement of the tightening torque when the tightening torque detected exceeds a set threshold value, completes measurement when the tightening torque detected falls below the set threshold value and a set time elapses, and outputs torque-related data formed on the basis of measurement data from measurement initiation to measurement completion and including a measurement time. The torque-related data includes a peak value of the measurement data.

A machine learning device includes a state observation unit for observing state variables that include at least one of the state of an assembly constituted of first and second components, an assembly time and information on a force, the result of a continuity test on the assembly, and at least one of position and posture command values for at least one of the first and second components and direction, speed and force command values for an assembly operation; and a learning unit for learning, in a related manner, at least one of the state of the assembly, the assembly time and the information on the force, the result of the continuity test on the assembly, and at least one of the position and posture command values for at least one of the first and second components and the direction, speed and force command values for the assembly operation.

A method is provided for managing optional functions in a screw driving system using a fleet of at least two control hubs, each controlling at least one piece of production equipment and being capable of being used with at least one optional function. Each control hub stores non-differentiated tokens. The optional function is assigned a pre-defined weight, corresponding to a number of tokens. The optional function is pre-installed and deactivated in the control hub. The optional function can be selectively activated on the control hub if the control hub has available a number of tokens greater than the weight of the function, a quantity of tokens corresponding to the weight being debited from the number of tokens available to the control hub, and the function can be selectively deactivated. The quantity of tokens are then made freely usable. Two control hubs can transfer non-differentiated tokens to each other.

Provided is a technique capable of suitably determining screw fastening failure. A screw fastening failure determination device (10) includes: a speed acquisition unit (13) which acquires an axial speed of a screw driver or a speed feature value relating to the speed; and a failure determination unit (14) which determines, in a temporary seating process, that a screw fastening has failed on the basis of the axial speed or the speed feature value at a prescribed timing.

A system for locating the center line of a bolt which extends through an aircraft part, including a robot which carries a nut or collar placement device and a stereo camera. A control system operates the camera to produce two images of the fastener at a specified angle. A processor then transforms the image information to control information for the robot to align the nut or collar placement device with the centerline of the fastener and then to place the nut or collar on the end of the fastener.

A system for locating the center line of a bolt which extends through an aircraft part, including a robot which carries a nut or collar placement device and a stereo camera. A control system operates the camera to produce two images of the fastener at a specified angle. A processor then transforms the image information to control information for the robot to align the nut or collar placement device with the centerline of the fastener and then to place the nut or collar on the end of the fastener.

A machine learning device includes a state observation unit for observing state variables that include at least one of the state of an assembly constituted of first and second components, an assembly time and information on a force, the result of a continuity test on the assembly, and at least one of position and posture command values for at least one of the first and second components and direction, speed and force command values for an assembly operation; and a learning unit for learning, in a related manner, at least one of the state of the assembly, the assembly time and the information on the force, the result of the continuity test on the assembly, and at least one of the position and posture command values for at least one of the first and second components and the direction, speed and force command values for the assembly operation.

A method is provided for managing optional functions in a screw driving system using a fleet of at least two control hubs, each controlling at least one piece of production equipment and being capable of being used with at least one optional function. Each control hub stores non-differentiated tokens. The optional function is assigned a pre-defined weight, corresponding to a number of tokens. The optional function is pre-installed and deactivated in the control hub. The optional function can be selectively activated on the control hub if the control hub has available a number of tokens greater than the weight of the function, a quantity of tokens corresponding to the weight being debited from the number of tokens available to the control hub, and the function can be selectively deactivated. The quantity of tokens are then made freely usable. Two control hubs can transfer non-differentiated tokens to each other.