A control device includes a processor that is configured to execute computer-executable instructions so as to control a robot that includes a robot arm including a force detector, wherein the processor is configured to reset the force detector after moving the robot arm at a first speed, and subsequently moves the robot arm at a second speed faster than the first speed and performs force control based on an output from the force detection unit.

A nut runner, an attachment unit, and a sliding member are provided in a second arm that is a leading arm of the robot and has a leading end shaft movable along the direction of an elevation axis. The nut runner includes a screw fastening driver, a drive shaft rotationally driven by the screw fastening driver, and an extension bar that is so connected to rotate together with the drive shaft in the circumferential direction and to move in the axial direction. The attachment unit fixedly connects the screw fastening driver to the second arm so that a screw fastening axis parallel to the elevation axis serves as a rotation axis of the screw fastening driver. The sliding member is connected to the leading end shaft and supports the extension bar so as to move together in the axial direction and are rotatable relatively in the circumferential direction.

A robot control device includes a correction amount calculation unit that calculates a correction amount for collecting a deviation of a tip position of a tool attached to a tip of a robot due to an external force applied to the tool and a correction profile generation unit that generates a correction profile indicating a relationship between the correction amount calculated by the correction amount calculation unit and time.

A control device which controls a robot having a moving part includes: a processor which is configured to cause an end effector provided on the moving part to move an insertion object, bring the insertion object into contact with an insertion hole provided in an insertion target object in the state where the insertion object is tilted from a center axis of the insertion hole, and subsequently insert the insertion object into the insertion hole.

An automatic screw tightening module includes a plate assembly, an input module, a screwdriver module, a transmission module, a movable module, an elastic element and a position sensor. The screwdriver module includes a screwdriver and a screwdriver sleeve. The transmission module is connected with an input terminal of the input module and the screwdriver sleeve for allowing the input terminal, the transmission module and the screwdriver sleeve to be rotated synchronously. The movable module is movably disposed on a base plate of the plate assembly. The movable module includes a bearing, and portion of the screwdriver sleeve is accommodated in the bearing, so that the screwdriver module and the movable module are moved relative to the base plate. The elastic element is disposed on the base plate and connected with the movable module. The position sensor is disposed on the base plate for sensing a displacement of the movable module.

A robot includes a work tool that performs a work to a work point, and a moving unit that moves the work tool and changes the posture thereof. A console receives an operation to designate the coordinates of arbitrary two or three points on an inclined surface. Upon this operation, a processor calculates a direction of the work tool toward the work point from a work start point based on the coordinates of the arbitrary two or three points, next, a control unit moves the work tool to the work start point, directs the posture of the work tool toward the work point in accordance with the calculation by the processor, and causes the work tool to start a process to the work point.

A screw fastening device comprises a robot including a wrist part, a bit which turns a screw, a force sensor which detects force information associated with a force or a moment acting between the bit and the screw, and a controller which controls the robot. The wrist part includes a flange which rotates. The bit is supported by the flange so as to rotate coaxially with the rotation axis of the flange and rotates upon transmission of the rotational force of the flange.

A system and method for implementing a search and feel function on a robot for installing parts on a workpiece. An air switch feature is provided on a gripper of the robot to determine the presence and proper placement of a part in a desired receptor location on the workpiece. The air switch feature is used to detect whether or not a particular part, such as a bolt or other part being inserted by the robot, has been properly gripped by the gripper, and whether the part has been properly placed in the desired position.

A tool-support system for working on holes of a surface. The tool-support system includes two rails fixed to the surface and having imprints regularly distributed over their length, and a mobile tool-support including a mobile optical system capturing an image of the surface. For each rail, at least one wheel is adapted to be moved on the rail, and includes on its rolling strip counter-imprints complementary to the imprints. A mobile tool carries a working tip, and a control unit is configured to control the movement of the mobile tool-support, of the tool and of the optical system to analyze an image captured by the optical system and to detect the presence of a hole. A tool-support system of this kind can therefore move along the rails without slipping while detecting the holes to work on them.

An automatic jig replacement system includes a detection device, a robot, a bolt tightening/loosening device, and a control device. The detection device is configured to be capable of detecting a predetermined part of a jig. The robot is configured to be capable of conveying the jig. The bolt tightening/loosening device is configured to be capable of tightening/loosening a bolt for securing the jig. The control device determines a bolt tightening/loosening position, on the basis of a result of detecting the predetermined part by the detection device. The robot is caused to unload the jig from the mounting position, or to load the jig to the mounting position. The bolt tightening/loosening device is moved to the bolt tightening/loosening position, and is caused to tighten or loosen the bolt.