A robot system includes: a first robot; a second robot; and circuitry configured to: control the first and second robots to execute a collaborative operation on a work piece; and control, in response to a detection of an irregular state of the first robot during the collaborative operation, the first and second robots to execute a collaborative counteractive operation to eliminate the irregular state.

The disclosure concerns a coating method and a corresponding coating device for coating components with a nozzle applicator with several nozzles, in particular for painting motor vehicle body components. The disclosure provides that the nozzle applicator is flexibly controlled during the coating method.

The disclosure concerns a coating method and a corresponding coating device for coating components with a nozzle applicator with several nozzles, in particular for painting motor vehicle body components. The disclosure provides that the nozzle applicator is flexibly controlled during the coating method.

Techniques relate to aligning one or more robotic arms of a robotic system to one or more alignment positions. For example, resistance for manual movement of a robotic arm can be set based on a direction of movement of a distal end of the robotic arm with respect to one or more alignment positions. The robotic arm can provide a first amount of resistance for manual movement in a direction closer to the one or more alignment positions and to provide a second amount of resistance for manual movement in a direction away from the one or more alignment positions. In some instances, the robotic arm can be automatically moved to the one or more alignment positions when the robotic arm is within a distance to the one or more alignment positions.

An end effector (400) for a robotic arm, the end effector (400) comprising: two pipe engaging jaws (404), each jaw comprising an inner contour configured for engaging a pipe section, wherein at least one jaw (404) is a fixed jaw; wherein the end effector (400) is configured to restrict radial movement of the pipe section while permitting axial movement.

Systems and methods are provided for robot control. One embodiment is a method for coordinating operations of robots performing work on a part. The method includes assigning a group of robots to a part, initiating work on the part via the group of robots, determining that a robot within the group is unable to continue performing work at a first location of the part, removing the robot from the group while other robots of the group continue performing the work, adding a functioning robot to the group at a second location that the robot is scheduled to occupy, and continuing work on the part via the group of robots.

Systems and methods for clearing a top drive from an operational area of the mast such that operations may be performed along the rail without interference from the top drive. Systems and methods of the present disclosure provide for arranging the top drive in a parked configuration outside of, or generally behind, the mast. A guide rail may be arranged within an operational area of a mast and may have a pair of interchangeable rail sections, each of which may be configured for arrangement in either an operating configuration, where the rail section may be positioned within the operational area of the mast to form part of the rail, or a parked configuration, where the rail section may be positioned outside of the operational area. Each interchangeable rail section may be pivotable about an axis and may be arranged on a pivotable gate of the mast.

A robot system includes: a first robot; a second robot; and circuitry configured to: control the first and second robots to execute a collaborative operation on a work piece; and control, in response to a detection of an irregular state of the first robot during the collaborative operation, the first and second robots to execute a collaborative counteractive operation to eliminate the irregular state.

A robotic mount is configured to move an entertainment element such as a video display, a video projector, a video projector screen or a camera. The robotic mount is moveable in multiple degrees of freedom, whereby the associated entertainment element is moveable in three-dimensional space. In one embodiment, a system of entertainment elements are made to move and operate in synchronicity with each other, such as to move a single camera via multiple robotic mounts to one or more positions or along one or more paths.

The robot includes a first arm having a first hand part provided to a tip end thereof, and at least one joint shaft provided between a pedestal and the first hand part, a first acting part configured to contact a given table-like body on which a plurality of workpieces are able to be placed, while the first acting part is provided to the first hand part, a controller, an imaging unit configured to two-dimensionally image a placement surface of the workpieces in the table-like body in a perpendicular direction to the placement surface, and a recognition part configured to recognize a position of the workpiece by performing a two-dimensional pattern matching based on an image two-dimensionally captured by the imaging unit. The controller vibrates the table-like body by controlling the first arm so that the first acting part acts on the table-like body.