Abstract: An automated instrument for identification and/or characterization of a microbial agent present in a sample. The instrument includes (a) a sample removal apparatus operative to remove a test sample from a specimen container and add the test sample to a disposable separation device; (b) a separation and concentration apparatus operative on the separation device to separate the microbial agent from other components which may be present in the test sample and concentrate the microbial agent within the separation device; and (c) a identification and/or characterization module interrogating the concentrated microbial agent to identify and/or characterize the microbial agent.

Abstract: A rotary coupling for a multi-axial robot hand (19) is provided with a rotatable hand housing (20) and an output element (21) that is rotatable on said housing. The rotary coupling (62) includes connections (65, 66, 68) for the output element (21), a tool (23) and an accessory unit (30). The tool (23) and the accessory unit (30) can be rotated relative to each other, and the accessory unit (30) can be coupled to the hand housing (20) or to the tool (23) or to the output element (21) via the rotary coupling (62). The rotary coupling (62) is provided for an application device (11) which is used to apply a sealant (8) on a lock seam (7) of an add-on piece (4) of a vehicle body (3).

Abstract: An ambidextrous robotic master controller includes a mounting base secured to a support, a shoulder member pivotally connected to the mounting base and, connected in series to the shoulder, an upper arm member, a forearm member, an inner wrist member, and an outer wrist member. An ambidextrous grip link is pivotally connected to the outer wrist member and is movable to a right hand position or a left hand position. An ambidextrous hand grip member is pivotally connected to the grip link member. The controller includes suitable encoders engaged between connected elements thereof to sense and signal relative movement therebetween. The controller is usable by either a right or left handed person to control a manipulator device having links and joints analogous to the links and joints of the controller.

Abstract: A substrate transfer robot includes a substrate gripping portion, an arm unit, and a controller. The substrate gripping portion is configured to hold a substrate. The arm unit includes a plurality of arms which are capable of turning in a horizontal plane. The arm unit has the substrate gripping portion at a leading end of the arm unit and is configured to transfer the substrate between a plurality of taught positions taught beforehand. When the taught positions are taught, the controller is configured to generate an access standby position corresponding to each of the plurality of taught positions and configured to generate and store a plurality of routes from the access standby position to a minimum turning posture of the substrate transfer robot.

Abstract: Methods include one or more of robotically positioning a cutting element on an earth-boring tool, using a power-driven device to move a cutting element on an earth-boring tool, and robotically applying a bonding material for attaching a cutting element to an earth-boring tool. Robotic systems are used to robotically position a cutting element on an earth-boring tool. Systems for orienting a cutting element relative to a tool body include a power-driven device for moving a cutting element on or adjacent the tool body. Systems for positioning and orienting a cutting element on an earth-boring tool include such a power-driven device and a robot for carrying a cutting element. Systems for attaching a cutting element to an earth-boring tool include a robot carrying a torch for heating at least one of a cutting element, a tool body, and a bonding material.

Abstract: A mixing vial is provided for an automated biological reaction apparatus typically used for staining tissue samples in Immuno-histological and in-situ hybridisation reactions. The mixing vial allows reagents placed on the apparatus to be mixed together to form additional or blended reagents. A reagent dispenser mounted on a robotic arm withdraws reagent from the reagent containers and deposits it into one of the mixing vials. Several reagents can be deposited into each vial. Mixing is undertaken by withdrawing the reagents in a vial and re-dispensing the reagent back into the vial. Mixing may take place between the operation of other tasks performed by the apparatus, and a scheduler is used to ensure blended reagent is provided before it is required in one of the processes undertaken on the apparatus. The apparatus is able to automatically identify which blended reagents are required and when they must be applied to provide an appropriate schedule that minimises time taken to stain samples.

Abstract: In a robot, a first determining unit determines whether there is an interference region in which a first occupation region and a second occupation region are at least partially overlapped with each other. A second determining determines whether a second movable part of another robot is at least partially located in the interference region based on an actual position of the second movable part. A stopping unit begins stopping, at a predetermined timing, movement of the first movable part if it is determined that there is the interference region, and that the second movable part is at least partially located in the interference region. The predetermined timing is determined based on a positional relationship between an actual position of the first movable part and the interference region.

Abstract: A method of controlling a redundant manipulator for assigning one or more redundant joints from a plurality of joints and obtaining the solution to an inverse kinematics problem at high-speed. The joints are arbitrarily classified into redundant joints and non-redundant joints, and an initial value is set for the joint angle of the classified redundant joint as a parameter. Then based on an evaluating function or a constraint condition defined by the joint angle of the redundant joint provided as a parameter and the joint angle of the non-redundant joint, which is determined by the inverse kinematics calculation according to the change of the parameter, an optimum solution of a set of joint angles is determined, and until the optimum solution covers the target range of the hand position, the procedure to determine the optimum solution is repeated with relaxing the constraint conditions.

Abstract: A laser processing robot control system is provided with a robot (1), a laser beam scanning device (3) and a robot controlling apparatus (7). The laser beam scanning device (3) is movable in a three-dimensional direction with respect to the robot (1) to scan a laser beam on a workpiece (W). This system selectively positions the robot and the laser beam scanning device to a prescribed position, and controls the laser beam scanning device (3) to scan the laser beam at a processing spot in a scan pattern based on a detected posture of the robot (1) and the scan pattern retrieved from the robot controlling apparatus (7). The teaching operations for positioning the robot (1) and the laser beam scanning device (3) to the prescribed position are performed independently of the teaching operations for controlling the scanning of the laser beam at the processing spot in the scan pattern.

Abstract: An alignment apparatus of this invention includes a holding stage that is larger in size than a semiconductor wafer, and an optical sensor that optically detects a position of a peripheral edge of the semiconductor wafer placed on and suction-held by the holding stage. The holding stage has a slits formed thereon vertically in a circumferential direction, and an outer periphery of the semiconductor wafer lies on the slits. The optical sensor is of a transparent type and includes a projector and a photodetector opposed vertically to each other with the slit interposed therebetween. The optical sensor measures the peripheral edge of the semiconductor wafer on the slits of the holding stage.

Abstract: There is provided a control device for a robot arm which includes an operation procedure information acquisition means for acquiring information on the procedure of a domestic operation, a progress management means for managing information on the progress of the operation, and a control parameter setting means for setting a control parameter for the robot arm based on the operation procedure information and the progress information, whereby the control device controls an operation of the robot arm based on the control parameter from the control parameter setting means.

Abstract: A “construction set” consisting of active and passive parts connected by joints that can be manipulated to form an movable articulated assembly representing things like animals and skeletons. Each active part includes a position sensor for acquiring and storing position data specifying a sequence of positions assumed by the active part as the assembly is reshaped, and a controllable drive motor for moving the active part relative to a connected part in accordance with the position data.

Abstract: A control device for a robot arm is designed such that, based on information on a transportation state database in which information on a transportation state of a person operating the arm is recorded, an impedance setting unit sets a mechanical impedance set value of the arm, and an impedance control unit controls a mechanical impedance value of the arm to the mechanical impedance set value thus set.

Abstract: A substrate transfer robot sets an interference region in advance in the range of motion of the substrate transfer robot; stores a plurality of patterns of a combination of a starting position, a target position, and the interference region, the starting position and the target position being among taught positions; determines which pattern among the plurality of patterns a movement of the substrate transfer robot from the starting position to the target position matches when the substrate transfer robot moves between the plurality of taught positions; and determines a movement path from the starting position to the target position so as to avoid the interference region in accordance with the determined pattern so that the substrate transfer robot avoids the interference region.

Abstract: A transfer apparatus includes a stationary base, a swivel supported by the stationary base to be rotatable about a vertical axis, a guide member mounted on the swivel, a linear movement mechanism supported by the swivel or the guide member, a hand supported by the linear movement mechanism and moved by the linear movement mechanism for carrying a work along a straight and horizontal travel stroke, a drive source disposed inside the stationary base, and a transmission shaft disposed along the vertical axis to transmit drive power from the drive source to the linear movement mechanism. The swivel includes an upper section and a lower section detachably connected with each other. The upper section has a connecting member supported by the upper section to be rotatable about the vertical axis. The connecting member has a detachable engagement member for engagement with the transmission shaft from the above.

Abstract: The invention relates to a device for displacing and positioning an object in a space, having at least three actuating arms that can pivot about a transmission axis. Each arm is connected to a motor unit/transmission unit. A carrier element is provided in order to arrange at least one gripping element for gripping the object. Each actuating arm, on the free ends thereof, has a first articulated axis that is parallel to the transmission axis with first articulated parts arranged at a distance from each other, of a first ball joint. The carrier element has a second articulated axis associated with each actuating arm with first articulated parts that are arranged at a distance in relation to each other, of a second ball joint. The first articulated axis is connected to the second articulated axis by a pair of connecting bars which include terminal second articulated parts.

Abstract: The position of a movable element such as the end of a robot arm (10) which has several degrees of freedom, being mounted on a base (11) and including a wrist mechanism, is determined by installing a multiplicity of base targets (32, 74) around the base of the robot, and a multiplicity of arm targets (42, 74) around the base (14) of the wrist mechanism (15), and an optical means (90) that moves with the movable element to determine the positions of at least some of the base targets and of at least some of the arm targets. The optical means may be a laser tracker or a camera system (90), and it may be mounted on the part (13) of the robot arm to which the base (14) of the wrist mechanism (15) is connected. This enables existing robots (10) to achieve absolute positional accuracy relative to a fixed external frame of reference.

Abstract: A remote controlled robot with a head that supports a monitor and is coupled to a mobile platform. The mobile robot also includes an auxiliary camera coupled to the mobile platform by a boom. The mobile robot is controlled by a remote control station. By way of example, the robot can be remotely moved about an operating room. The auxiliary camera extends from the boom so that it provides a relatively close view of a patient or other item in the room. An assistant in the operating room may move the boom and the camera. The boom may be connected to a robot head that can be remotely moved by the remote control station.

Abstract: A truss assembly station may include a jigging table for assembling a truss thereon and a truss assembler. The truss assembler is disposed at a mobile gantry suspended a predetermined distance from a surface of the jigging table. The mobile gantry is configured to move relative to the surface. The truss assembler is configured to enable assembly of a truss from truss members by providing an automatic sequential placement of the truss members based at least in part upon a planned location of pre-plated truss members within an assembled truss.

Abstract: The safety in robotic operations is enhanced and the floor space in a factory or the like is effectively utilized. A virtual safety barrier 50 including the trajectory of movement of a work or tool 7 mounted on a wrist 5 of a robot 1 in operation is defined in a memory. At least two three-dimensional spatial regions S (S1 to S3) including a part of the robot including the work or tool are defined. Predicted positions of the defined three-dimensional spatial regions obtained by trajectory calculations are matched with the virtual safety barrier 50, and if the predicted position of any one of the defined three-dimensional spatial regions based on trajectory calculations is included in the virtual safety barrier 50, a control is effected to stop the movement of the robot arms 3 and 4.

Abstract: A storage slot for multiple data storage cartridges, comprising a planar member having a first end, a second end, a side interconnecting the first end and the second end, and a gate moveably connected to the side at the first end of the planar member, wherein the gate can be moved between a closed position and an open position. The storage slot farther comprises a secondary catch moveably disposed between the first end and the second end. When the gate is disposed in a closed position, the secondary catch is disposed in a retracted orientation, and when the gate is disposed in an open position, the secondary catch is disposed in an extended orientation.

Abstract: A method for loading a semiconductor wafer into a process unit comprises opening the process unit, inserting a wafer into the process unit, adjusting the position of the wafer in the process unit so that it is in a certain position in relation to markers, and inserting a camera into the process unit facing the markers. The camera acquires an image of the markers and of a part of the wafer, and displays on a display screen the image acquired. The position of the wafer is adjusted according to the position of the wafer in relation to the markers on the image displayed.

Abstract: A system for testing with an automated test equipment (ATE) includes a tester having at least one test resource, a tandem handler, and a mux relay that switchably connects the test resource, via parallel connections, to either one of dual sockets at each instant of testing. The handler has first and second manipulator arms. Each arm operates as to a particular one of the respective sockets, to retrieve a next device to be tested and position the device in the socket (while testing is performed on a device in the other socket), to disposition the device from the socket once testing is completed as to the device in the socket, and thereafter repeat until all staged devices for testing have been tested (or an interruption of testing otherwise occurs). The mux relay switches between sockets in response to the tandem handler acting as a master and the tester as slave.

Abstract: A laser ultrasonic measurement system includes a first and a second laser source configured to generate a first and a second laser beam, respectively. A movable mechanical link is arranged to transmit the first laser beam. The movable mechanical link is formed by a plurality of rigid sections interconnected by rotating joints. A robot is configured to support and control the movement of at least a section of the mechanical link to transmit the first laser beam to an object. An optical scanner is positioned proximate to the mechanical link. The optical scanner is configured to direct the first and second laser beams onto the object. An interferometer is optically coupled to the optical scanner. The interferometer is configured to receive reflected light from the object and in response generate an electrical signal. The first laser source is kinematically mounted in a housing assembly.

Abstract: A robotic master controller having a series of linking members interconnected by pivots to each other and a hand grip with relative position sensors therein and sensing yaw and pitch of the hand grip due to movement of the user. The final linking member including an arched section that terminates in a pivot for the hand grip that is located within the user's hand during use and has an axis of rotation that generally aligns with a roll axis of rotation of the arm when the user's hand rotates between a palm up configuration to a palm down configuration. The final linking member also includes an arched section that extends over and cradles the outer palm of the hand when the hand is in the palm up configuration. The user reaches around the outside (to the right for a right arm controller) to grasp the hand grip.

Abstract: A robot, wherein the operating amounts of the first and second actuators are adjusted according to a torque necessary for maintaining a body member and an end member at specified angles in a mechanism in which the body member (361) and the end member (363) are rotatably connected to each other and first and second wires (366) connected to the end member are advanced and retreated by the first and second actuator (368).

Abstract: A system, method, and device may include software and hardware which simplify and quicken configuration of the system for testing a device, enhance testing procedures which may be performed, and provide data via which to easily discern a cause and nature of an error which may result during testing. A camera may capture still images of a display screen of a tested device and another camera may capture video images of the tested device and a partner device. A wizard may be used to generate a configuration file based on one previously generated for a similar device. A mount for a tested device may be structured so that: it is suitable for mounting thereon a plurality of differently structured devices; and adjustments in a vertical direction and a horizontal direction in a plane and adjustments of an angle of the device relative to the plane may be easily made.

Abstract: This method for measuring the diameter of a circular track on a component comprises: a) a step (162) of moving the component along a measurement path, b) as the component is moving along the measurement path, a measurement step (170), for measuring at least one parameter, without contact with the component, c) a step (186) of determining the diameter of the circular track from the parameters measured. During step a) a robot continuously moves the component at an instantaneous speed that is never zero along the measurement path and an instantaneous acceleration that never changes sign along the measurement path.

Abstract: An apparatus for measuring a surface of a workpiece is described. The apparatus comprises a support, attachable to the moveable arm of a machine, such as a coordinate positioning machine, and rotatable about first and second axes of rotation, the axes driven by first and second motors respectively. The apparatus additionally comprises a surface sensing device for sensing the surface of a workpiece, rotatable about a third axis of rotation. This third axis of rotation is alignable with the first axis of rotation, and when aligned, rotation of the support relative to the surface sensing device is actuatable by the first motor. A method for using an apparatus for measuring a surface of a workpiece is also described.

Abstract: The invention relates to a device and a method for checking and/or calibrating a passenger recognition device arranged in a vehicle seat, in the case of which device a child's seat can be pressed against a vehicle seat and in the case of which method a vehicle seat is loaded with a child's seat and a corresponding reaction from the passenger recognition device in the vehicle seat is evaluated.

Abstract: A collector device includes a collector connected to a positioner, such as a robot arm. The positioner can automatically move the collector in multiple dimensions to collect objects into the collector according to a specified collection pattern. By moving the collector in multiple dimensions, the positioner provides for objects to be arranged in the collector according to a specified pattern. The positioner can also move the collector so that the collected objects are transferred to a second collector for shipping, storage, and the like.

Abstract: One of reverse passing parts provided in a substrate passing part comprises a first holding mechanism and a second holding mechanism. The first holding mechanism and the second holding mechanism are arranged in vertically symmetry with respect to a rotary central axis and rotate 180 degrees about the rotary central axis, to replace each other in position. A transport robot on the loading side passes a substrate to a third holding mechanism or a fourth holding mechanism at a first vertical position. The substrate reversed in the reverse passing part is passed to a transport robot on the unloading side from the third holding mechanism or the fourth holding mechanism at a second vertical position. Before a reverse process on the preceding substrate is finished, the transport robot on the loading side can start the transfer of the following substrate.

Abstract: The inventive concept of the metrology system (the system) actively determines the 6 Degree of Freedom (6-DOF) pose of a motion device such as, but not limited to, an industrial robot employing an end of arm tool (EOAT). A concept of the system includes using laser pointing devices without any inherent ranging capability in conjunction with the EOAT-mounted targets to actively determine the pose of the EOAT at distinct work positions of at least one motion device.

Abstract: A robot joint structure ? is composed of a metacarpal member 30 and a proximal member 40 swingably connected through a hinge 31 to a side end portion of the metacarpal member 30. The proximal member 40 includes a linear guide device 44 for an MP joint having a moving member movable in association with a self swing motion thereof, and by connecting a rod 32a and the moving member through a link mechanism 50, a driving force of an air-cylinder 32 is transmitted to the proximal member 40. On the other hand, a second robot joint structure ? is also provided with linear guide devices 48, 66, 74 and link mechanisms 69, 75, to which a driving force of the air-cylinder 62 is transmitted through a drive shaft 63 in association with a rod 62a. A robot finger is constructed by the first and second robot joint structures. According to such structures, smooth joint motion can be realized, and the robot joint structure and the robot finger having improved gripping force can be provided.

Abstract: The present invention is intended to achieve more accurate and facilitated positioning of a carrier onto a table, in a substrate processing apparatus configured for placing the carrier storing multiple sheets of wafers therein, on the table, by using a carrier arm. Before the carrier is actually carried by the carrier arm, a carrier jig having the same shape as the carrier is held by a holding part provided to the carrier arm. The carrier jig is provided with a camera, such that a central position of a region of an image taken by the camera will be coincident with a central position of an opening formed in the table, if the carrier jig is accurately located in an ideal position above the table. First, the carrier arm is actuated to move the holding part of the carrier arm to a preset lowering start position. Then, the image of the region including the opening is taken by the camera.

Abstract: An apparatus and method of handling substrates is disclosed. A detecting system, capable of determining whether a substrate is tilted in relation to the platen, is positioned proximate to the substrate. In some embodiments, the detecting system is a distance measuring system. In other embodiments, it is an angle sensor. The detecting system is in communication with a controller, which, in turn, is in communication with a substrate handling robot. If, based on information received from the detecting system, the controller determines that the substrate is tilted beyond an acceptable range, it is assumed that the substrate has remained attached to the platen. In such a case, the substrate handling robot does not attempt to remove it from the platen. In this way, the substrate is not damaged.

Abstract: In a robot arm controlling device, a mechanical impedance set value of the arm is set by an object property-concordant impedance setting device based on information of an object property database in which information associated with properties of an object being gripped by the arm is recorded, and a mechanical impedance value of the arm is controlled to the set mechanical impedance set value by an impedance controlling device.

Abstract: Methods correcting wafer position error are provided. The methods involve measuring wafer position error on a robot, e.g. a dual side-by-side end effector robot, during transfer to an intermediate station. This measurement data is then used by a second robot to perform wafer pick moves from the intermediate station with corrections to center the wafer. Wafer position correction may be performed at only one location during the transfer process. Also provided are systems and apparatuses for transferring wafers using an intermediate station.

Abstract: A robot comprises a fixed body, a movable body, and a flat-shaped cable. The fixed body is at least unmovable in a vertical direction. The movable body is movably connected to the fixed body in a predetermined movable range in the vertical direction and has an end to which a tool is attached, the tool performing operations on a workplace. The cable bundle has a plurality of cables for electric power supply and control communication among the fixed and movable bodies and the tool. The cable bundle has two ends. One end is fixedly connected to a fixing position of the fixed body, while the other end is fixedly connected to a fixing position of the movable body which is equal to or higher than the position of the fixed body in the vertical direction in a state where the movable body is located at a highest highest position within the movable range of the movable body.

Abstract: A system for tracking a navigated instrument. The system can include a first elongated instrument and a second elongated instrument. The first elongated instrument can have a first proximal end and a first distal end. The first elongated instrument can be adapted to be positioned relative to an anatomy. The second elongated instrument can move adjacent to the first elongated instrument. The second elongated instrument can have a second proximal end and a second distal end. The system can also include at least one tracking device coupled to the second elongated instrument. When the second elongated instrument is in a first position, the at least one tracking device tracks the first distal end of the first elongated instrument, and when the second elongated instrument is in a second position, the at least one tracking device tracks the second distal end of the second elongated instrument.

Abstract: An automatic case loader for loading product in a trailer is disclosed. A mobile base structure provides a support framework for a drive subassembly, conveyance subassembly, an industrial robot, a distance measurement sensor, and a control subassembly. Under the operation of the control subassembly, product advances through a powered transportation path to an industrial robot which places the product within the trailer. The control subassembly coordinates the selective articulated movement of the industrial robot and the activation of the drive subassembly based upon the distance measurement sensor detecting objects within a detection space, dimensions of the trailer provided to the control subassembly, and dimensions of the product provided to the control subassembly.

Abstract: System and apparatus for automatically stacking trays involve receiving trays on a receiving platform, detecting the arrival of the tray on the platform, and synchronously displacing the tray to a moveable tray cart located in a tray stacking area of a stacking tower. An automated tray sliding mechanism displaces the tray to the stacking area upon detection of the tray at the receiving platform. Trays displaced in the stacking area of a lower section of a stacking tower form a tray stack. A stack elevator of the tower engages and elevates the tray stack providing a space beneath the stack allowing the next incoming tray to be displaced into the stacking area and assume the provided space beneath the tray stack, the incoming tray thereby assuming the lowermost position in the tray stack. Trays are added to the lowermost position in the stack until the stack height reaches a predetermined height and is removed from the stacking area.

Abstract: A manipulator arm system on a ducted air-fan UAV is disclosed herein. The target site may be accurately located by the UAV, and the manipulator system may accurately locate the payload at the target site. The manipulator arm may select tools from a toolbox located on-board the UAV to assist in payload placement or the execution of remote operations. The system may handle the delivery of mission payloads, environmental sampling, and sensor placement and repair.

Abstract: A robot is described for moving a certain item within a three-dimensional work area, from a picking position to a placing position. The robot comprises a first motion assembly, provided with a gripping element to pick the item and to move it within a two-dimensional work area, and a second motion assembly supporting said first motion assembly and adapted to impart thereto a lateral translation so as to define a three-dimensional work area. The first motion assembly comprises a lever system with movable fulcra operated by motorization means, through transmission means.

Abstract: The present exemplary embodiment relates to motion control and planning algorithms to facilitate execution of a series of moves within a motion trajectory. In one example, a trajectory is specified as a sequence of one or more path segments. A velocity profile is calculated for each of the one or more path segments, wherein each velocity profile is divided into a blend-in region, a blend-out region and a remainder region. Each path segment is executed such that the blend-in region of its velocity profile overlaps only with the blend-out region of the previous profile.

Abstract: A wafer processing system has a wafer loading system accommodating sufficient wafer carriers to substantially maximize the processing speed capability of the processing system. Wafer carriers are placed into and removed from the loading system by one or two overhead carrier loading tracks. Carriers may be loaded or removed while other carriers are in work. One or more transfer robots may move wafers from the carriers to buffers. One or more process robots in a process module move wafers from buffers, or other locations, to processors in the process module.

Abstract: A wafer loading system accommodates sufficient wafer carriers to substantially maximize the processing speed capability of wafer processing systems. Wafer carriers are placed into and removed from the loading system by one or two overhead carrier loading elements, such as overhead track systems. Carriers may be loaded or removed while other carriers are in work. One or more transfer robots may move wafers from the carriers to buffers. Methods of operating the loading system allow delivery and removal of wafers to and from the processing systems to meet or exceed the processing speeds of the processing systems.

Abstract: The invention relates to a method for moving a camera that is disposed on a pan/tilt head along a given trajectory especially in a set or studio as well as an associated camera robot. In order to be able to move a camera with repeated accuracy along a given trajectory, an associated trajectory is determined for the spatial positions and orientations of a basic reference system of the pan/tilt head from the given trajectory for the camera, and associated control variables for shafts of a robot that can be moved in Cartesian coordinates are generated from the determined trajectory for the basic reference system of the pan/tilt head and are transmitted to the shafts, thus allowing camera movements to be made that are not possible with previously known systems.

Abstract: In order to be able to carry out a multiplicity of continuosly recurring activities at a continuous casting plant having at least one multifunction robot for implementing a plurality of different process-controlled or automated interventions at the continuous casting plant, at least one working region at the continuous casting plant and at least one multifunction robot assigned to each working region. The multifunction robot is arranged on a pivotable arm at a rotary column fastened to the pouring platform of the continuous casting plant and the robot can be pivoted with the pivot arm between a retraction position and a working position. The robot is also movable with respect to its arm.

Abstract: A robot positioned welding tip dresser assembly includes a pivot arm pivotally mountable on a welding gun apparatus. The pivot arm is pivotal about a pivot point. A welding tip dresser is mounted on a distal end of the pivot arm. A first retaining tab extends from the pivot arm. The first retaining tab includes an opening extending therethrough. At least one positioning mechanism is disposed relative to the pivot point and is cooperable with the first retaining tab to retain the pivot arm in one of a home position and a working position. The first retaining tab is engagable by end-of-arm tooling of a robot. The end-of-arm tooling is operable to release the positioning mechanism, and movement of the robot moves the pivot arm between the home and working positions.