An apparatus for clamping a robotically controlled tool to a workpiece comprises a tool support mountable on a robotic arm and configured to support the tool, a plurality of clamping modules, each of which includes at least one vacuum cup arranged to clamp the tool support to the workpiece, and an adjustment mechanism configured to adjust the position of the tool support relative to the workpiece.

A robot system provided with: a conveying apparatus; a robot that performs processing on an article being conveyed; a camera that captures images of the article being conveyed; a conveying-velocity calculating portion that calculates at least one of a position of the article on the conveying apparatus and a velocity at which the article is conveyed by the conveying apparatus on the basis of the plurality of images captured by the camera; and a control unit that controls the robot on the basis of at least one of the position and the conveying velocity. The control unit determines whether or not the article is present in the images, and, in the case in which the article is absent, controls the robot on the basis of at least one of the position and the conveying velocity calculated by the conveying-velocity calculating portion immediately therebefore.

A method for detaching or installing a rotor blade from or to a hub of a wind turbine includes positioning the rotor blade toward a ground location between a three o'clock position and a nine o'clock position. The method also includes mounting a mechanical arm to an uptower location of the wind turbine. Further, the mechanical arm includes a torqueing tool at a distal end thereof. Thus, the method also includes removing or installing, via the torqueing tool, each of the plurality of hub fasteners so as to detach or attach the rotor blade from or to the hub.

The invention relates to a method and an arrangement for introducing boreholes into a surface of a workpiece (W) mounted in a stationary manner using a boring tool which is attached to the end face of an articulated-arm robot (KR) and which can be spatially positioned by said robot. The method has the following method steps: positioning the articulated-arm robot-guided boring tool at a spatial position which lies opposite a specified machining location on the workpiece surface at a specified distance therefrom, producing a rigid mechanical connection which supports the end face of the articulated-arm robot (KR) on the workpiece and which can be released from the workpiece surface, and machining the surface by moving the boring tool towards the machining location and subsequently engaging the boring tool with the workpiece (W) at the machining location on the workpiece surface while the end face of the articulated-arm robot (KR) is connected to the workpiece. The invention is characterized by the combination of the following method steps: the boring tool is moved towards the workpiece (W) by means of an NC advancing unit attached to the end face of the articulated-arm robot (KR), the boring process is monitored on the basis of information obtained using a sensor system which detects the position of the boring tool relative to the workpiece surface and which is attached to the end face of the articulated-arm robot (KR), and the boring process is terminated upon reaching a specified boring depth.

Embodiments of the present disclosure are directed to methods, computer program products, and computer systems of a robotic apparatus with robotic instructions replicating a food preparation recipe. In one embodiment, a robotic control platform, comprises one or more sensors; a mechanical robotic structure including one or more end effectors, and one or more robotic arms; an electronic library database of minimanipulations; a robotic planning module configured for real-time planning and adjustment based at least in part on the sensor data received from the one or more sensors in an electronic multi-stage process file, the electronic multi-stage process recipe file including a sequence of minimanipulations and associated timing data; a robotic interpreter module configured for reading the minimanipulation steps from the minimanipulation library and converting to a machine code; and a robotic execution module configured for executing the minimanipulation steps by the robotic platform to accomplish a functional result.

Embodiments of the present disclosure are directed to methods, computer program products, and computer systems of a robotic apparatus with robotic instructions replicating a food preparation recipe. In one embodiment, a robotic control platform, comprises one or more sensors; a mechanical robotic structure including one or more end effectors, and one or more robotic arms; an electronic library database of minimanipulations; a robotic planning module configured for real-time planning and adjustment based at least in part on the sensor data received from the one or more sensors in an electronic multi-stage process file, the electronic multi-stage process recipe file including a sequence of minimanipulations and associated timing data; a robotic interpreter module configured for reading the minimanipulation steps from the minimanipulation library and converting to a machine code; and a robotic execution module configured for executing the minimanipulation steps by the robotic platform to accomplish a functional result.

The disclosed system includes a robot system with a robot having a modular platform and a controller operably coupled to the robot. The modular platform includes a plurality of mount connectors and a plurality of receiving port connectors. Each of the mount connectors is configured to attach to the robot and each of the receiving ports is configured to connect to an end effector such as a gripper, sensor or other tool. The modular platform is configured to mount to the robot in a plurality of orientations and to connect with a plurality of different end effectors.

A workpiece inverting device includes a gripping part configured to rotatably grip a workpiece, a rotary body rotatable about a rotating shaft and connected to the gripping part, a strip member extending in a direction orthogonal to the rotating shaft, and an arm configured to move in one of a state in which a tip of the arm is provided with the gripping part and the rotary body and a state in which the tip of the arm is provided with the strip member. While the workpiece is gripped by the gripping member, the rotary body moves relative to the strip member in contact with the rotary body in the direction in which the strip member extends.

A gripping mechanism (3) includes a gripping roller (32) and a holder (31) that houses the gripping roller (32). A gripped portion (42) of a first component (4) is gripped between an outer surface of the gripping roller (32) and an inner surface of the holder (31) through action of gravity acting on the gripping roller (32). Preferably, the gripping roller (32) includes a core (321) that is cylindrical or columnar in shape and a covering section (322) that is an elastic body covering a circumferential surface of the core (321). Preferably, the covering section (322) has a circumferential surface with a friction coefficient greater than a friction coefficient of the circumferential surface of the core (321).

A method of operating a manipulation system of the type having a movable arm with a proximal end connected to a base and a distal end that is movable relative to the base and is coupled to an end-effector. The method comprises moving the distal end of the movable arm towards a target object and into contact with a stabilization object proximate to the target object, maintaining contact between the distal end of the movable arm and the stabilization object while operating the end-effector to perform a desired operation at the target object, and upon completing the desired operation at the target object, disengaging the distal end of the movable arm from contact with the stabilization object.