A shear stud welding system is disclosed. The system comprises a shear stud holder, a robotic arm and a microcontroller. The shear stud holder comprises a turret and a first motor coupled to the turret and configured to rotate the turret about an axis to a predetermined angle such that a shear stud among the plurality of shear studs is at a dispensing position. The robotic arm is configured to transfer the shear stud from the shear stud holder to a workpiece. The microcontroller is configured to control the movement of the robotic arm to pick up the shear stud from the dispensing position and transfer the shear stud holder to the workpiece at a welding position and cause the first motor to rotate the turret to a predetermined angle to cause a shear stud among the plurality of shear studs assume the dispensing position.

A part assembly system is disclosed that includes a first conveyor configured to convey fastening target parts and a second conveyor configured to convey correlated parts to which the fastening target part is to be fastened, including: i) a bolt supplying unit configured in a robot working section between the first and second conveyors and supplying bolts to a predetermined position; and ii) a robot gripper configured in the robot working section, picking up the bolts to distribute the bolts to a fastening position of the fastening target part, and moving the fastening target part to a manual working section of the second conveyor.

A switch-gear or control-gear system for medium or high voltage use includes an external housing containing the switch-gear or control-gear system, which is configured for unmanned operation and maintenance. The switch-gear or control-gear system is configured for unmanned operation and maintenance with a robotic system or manipulator and the robotic system or manipulator is provided with a camera system and an image recognition system. The robotic system is provided with a data network or an external data communication interface.

Methods of operating a robotic breaker-racking apparatus are provided. A method of operating a robotic breaker-racking apparatus includes controlling a motor to drive the robotic breaker-racking apparatus to a first circuit breaker. The method includes accessing the first circuit breaker via remote or autonomous control of the robotic breaker-racking apparatus. Moreover, the method includes visually inspecting, via a camera of the robotic breaker-racking apparatus, a first relay of the first circuit breaker and/or a second relay of a second circuit breaker. Related robotic breaker-racking apparatuses are also provided.

A robot apparatus includes a clamp mechanism; a transport mechanism; and a control unit. The clamp mechanism includes a first finger that has a first support surface and a housing portion and a second finger. The first support surface supports an aligned wire group that includes a plurality of wires, the housing portion includes a guide wall that is connected to the first support surface and regulates an amount of movement of the band member in a width direction. The second finger has a second support surface facing the first support surface and a facing portion being connected to the second support surface and facing the housing portion. The transport mechanism is capable of moving the clamp mechanism. The control unit controls a grip force of the clamp mechanism and a direction of movement of the clamp mechanism by the transport mechanism.

A master unit includes a welding DB in which prescribed motion data associated with an object to be welded is stored, a state sensor which measures, as welding state data, a situation of welding by a robot which executes welding in a real environment according to the prescribed motion data, a simulated environment which imitates the real environment and notifies a worker of the welding state data, and a motion control unit which receives, as an input, worker motion data indicating a motion of welding by the worker from the simulated environment, operates the robot in the real environment by using the worker motion data instead of the prescribed motion data, and records, as new prescribed motion data, the input worker motion data in the welding DB.

A rotor assembly system for a manufacturing cell includes a central robotic system comprising a multi-axial central robot and a conveyor platform and one or more multi-axial auxiliary robotic systems secured at one or more locations within the cell. The conveyor platform is operable to move the central robot within the cell. The central robotic system and the one or more auxiliary robotic systems are configured to perform a plurality of rotor manufacturing processes on at least one rotor component in coordination with one another, and the central robotic system is configured to transfer the at least one rotor component between one or more rotor manufacturing processes of the plurality of rotor manufacturing processes.

A surface disease repair system and method for an infrastructure based on climbing robots are provided. The system includes a detection and marking climbing robot and a repair climbing robot. In the process of moving on a surface of an infrastructure to be detected, the detection and marking climbing robot collects a front surface image in real time through a binocular camera arranged at a front end, detects a disease on the basis of the front surface image, and performs localization and map reconstruction at the same time; when a disease is detected, the position of the disease is recorded, and a marking device is controlled to mark the disease; after detection and marking are completed, the position of the disease and the map are sent to the repair climbing robot; and the repair climbing robot receives the map and the position of the disease, reaches the position of the disease, and repairs the disease according to the mark by using a repair device.

System for automatically manipulating primary packaging in secondary packaging, comprising a robot having at least one robot arm with a clamping gripper installed at a tool centre point, wherein each tool centre point has a force-torque sensor, an image recording module for recording images of at least the upper segment of the primary packaging, comprising at least two stereo cameras for recording 3-D images, and one or more processors for providing a three-dimensional point cloud, controlling the image recording module and controlling the robot on the basis of the analysis of the three-dimensional point cloud and the measurements from the force-torque sensors.

A tool and associated method for forming an attachment pad on a sheet material made from high strength steel. The tool includes a housing, an anvil supported on the housing and defining a working axis for forming the pad, and a slide block supported on the housing for movement at least along the working axis of the anvil. A die block is supported on the housing opposite the slide block, and is movable in directions along the working axis. The die block cooperates with anvil to form the pad at a target location defined along the working axis. The tool further includes a heating device supported for movement to and between first and second positions relative to the target location. The first position is adjacent to and aligned with the target location, while the second position is displaced from the first position and away from the target location.