Vehicle dimension data describing dimensions of a vehicle are obtained, a robotic apparatus is moved to a position about the vehicle, a reference point of the vehicle is determined, and the robotic apparatus is caused to move to positions about the vehicle based on the reference point. The reference point may be a center point of a selected wheel of the vehicle. A coordinate system of the robotic apparatus is aligned to the reference point of the selected wheel of the vehicle. Based on the aligned coordinate system of the robotic apparatus, operations are performed by the robotic apparatus to remove lug nuts from a wheel hub of the vehicle.

A manufacturing process adopting the reconfigurable robotic manufacturing cells that can work conjointly and yet have the capabilities to be reconfigured to disconnect from other cells and handle multiple tasks. The reconfigurable robotic cell is not dependent on any other robotic cells to complete work in progress.

In various examples, a computer-implemented method of generating instructions for a welding robot. The computer-implemented method comprises identifying an expected position of a candidate seam on a part to be welded based on a Computer Aided Design (CAD) model of the part, scanning a workspace containing the part to produce a representation of the part, identifying the candidate seam on the part based on the representation of the part and the expected position of the candidate seam, determining an actual position of the candidate seam, and generating welding instructions for the welding robot based at least in part on the actual position of the candidate seam.

An installation device for carrying out installation steps on a wall, and a method for exchanging a tool received by the installation apparatus, include an installation apparatus having a drive unit coupled to a tool holder. The tool holder receives a tool that extends away from the tool holder in a tool direction and which tool is driven by the drive unit. The tool holder can assume a locked state and an unlocked state, wherein a tool received by the tool holder can be removed from the tool holder in the unlocked state and is fixed in the tool holder, and therefore cannot be removed, in the locked state. The installation apparatus has an unlocking device controllable by an actuator and the tool holder can be brought from the locked state into the unlocked state by the actuator to release the tool.

A device (1) for rolling rings, comprising: a rolling device (10) with a main roll (11) and at least one mandrel roll (13a) onto which a ring is loadable, wherein the rolling device (10) is designed to roll the ring, with the mandrel roll (13a) impacting an interior face of the ring and the main roll (11) impacting an exterior face of the ring ;and a manipulator (20) comprising at least one robot (21) designed to manipulate the ring, comprising loading the ring onto the mandrel roll (13a) and/or unloading the ring from the mandrel roll (13a).

An autonomous self-driving assembly for confined regions. The assembly is configured to move within and through narrow spaces as well as larger wider spaces. Once more, the assembly may support the carrying out of load-based applications even within the wider spaces. The assembly includes bracing capacity within such wide spaces to facilitate the carrying out of such load-based applications.

A self-driving assembly capable of traversing an elevated window. The elevated narrow space window may be present within a confined area, for example, at a wall separating different wide space rooms. The assembly is configured to carry out unique techniques for gaining access to the window from a floor level location. Further, in addition to gaining access unique stabilizing features may be employed both in terms of physical security at an edge defining the window as well as in the form of maintaining balance through unique control over mass transfer when secured at the window.

An automatic robotic arm system and a coordinating method for robotic arm and computer vision thereof are disclosed. A beam-splitting mirror splits an incident light into a visible light and a ranging light and respectively guides to an image capturing device and an optical ranging device arranged in the different reference axes. In a calibration mode, a transformation relation is computed based on a plurality of the calibration postures and corresponding calibration images. In an operation mode, a mechanical space coordinate is determined based on an operation image and the transformation relation, and the robotic arm is controlled to move based on the mechanical space coordinate.

A rebar tying system including a chassis with a central opening that passes from top to bottom of the chassis, a plurality of driven wheels coupled to the chassis and configured to propel the rebar tying system bidirectionally over a rebar mat, a plurality of foot members coupled to the chassis and configured to selectively move the rebar tying system in a lateral direction relative the bidirectional wheel propelled movement, and a rebar tying gun configured to be selectively positionable both horizontally and vertically in the central opening to perform rebar tying operations.

A system and method for assembling a plurality of components into an assembly is provided. The system includes an assembling robot and an adhesive dispensing robot. The assembling robot is configured to attach a first sub-assembly to a second sub-assembly. The first sub-assembly includes at least one of the plurality of components, and the second sub-assembly includes remaining ones of the plurality of components. The adhesive dispensing robot is configured to apply an adhesive between the first sub-assembly and the second sub-assembly, after the first sub-assembly is attached to the second sub-assembly, to bond the first sub-assembly to the second sub-assembly.