A reconfigurable autonomous workstation includes a multi-faced superstructure including a horizontally-arranged frame section supported on a plurality of posts. The posts form a plurality of vertical faces arranged between adjacent pairs of the posts, the faces including first and second faces and a power distribution and position reference face. A controllable robotic arm suspends from the rectangular frame section, and a work table fixedly couples to the power distribution and position reference face. A plurality of conveyor tables are fixedly coupled to the work table including a first conveyor table through the first face and a second conveyor table through the second face. A vision system monitors the work table and each of the conveyor tables. A programmable controller monitors signal inputs from the vision system to identify and determine orientation of the component on the first conveyor table and control the robotic arm to execute an assembly task.

A workpiece conveying apparatus includes: two SCARA robots each including a first arm supported on a raising and lowering frame through intermediation of a first joint, a second arm supported through intermediation of a second joint, a first arm driving mechanism configured to drive the first arm to rotate, and a second arm driving mechanism configured to drive the second arm to rotate; a raising and lowering mechanism for the two SCARA robots; a cross arm configured to couple distal ends of the second arms; a workpiece holding unit configured to releasably hold the workpiece; shifting devices provided to the cross arm and configured to shift a drive-side shifting member; and sliding devices provided to the workpiece holding unit and configured to shift the tool holder by an operation of causing the driven-side shifting member to be driven by the drive-side shifting member.

A drive system comprises a support structure for a guideway defining an X-Y array of tracks (22, 24) so that one or more carriages (10) can run along the tracks to any desired position. The carriages are intended to either carry a single robotic device or work together to carry a larger robotic device. The track is made up of an array of pegs (14) supported from a ceiling plane made up of an array of tiles (8) which provide for electrical connections to the carriages. Each peg carries a spool mounted between two horizontal flanges that cooperates with a rectangular sprocket connected to a base of a cuboid carriage housing. The carriages are driven by internal electric motors that are arranged to drive two pairs of omniwheels (90) on the ceiling plane while the carriage is supported and guided by means of its sprocket.

The invention relates to a robot cell (1) provided for use on machine tools and/or assembly machines. The robot cell (1) includes a handling device, e.g. an industrial robot (2). By means of the robot cell (1), a workpiece (4) to be processed on the machine tool or the assembly machine can be removed from an incoming transport container, pre-processed, orientated, inserted into the machine tool or assembly machine, removed from the machine tool or the assembly machine, measured and placed or stacked in an outgoing transport container. The robot cell (1) can be used on different machine tools or assembly machines. In order to facilitate operation of a robot cell (1) of this kind, the robot cell (1) can be used on the machine tool or the assembly machine without being linked or connected to the machine tool or the assembly machine, the robot cell (1) has an optics device (5), by means of which, in conjunction with reference markings on the machine tool or assembly machine, the robot cell (1) can be positioned in its operating position on the machine tool or the assembly machine, wherein by means of a control apparatus (6) and the handling device connected thereto or the industrial robot (2) connected thereto of the robot cell (1), operating elements on the machine tool or assembly machine can be contacted, operated and controlled.

A conveyor system includes: a pick conveyor defining a picking area for a bulk flow of parcels; a place conveyor positioned downstream of the picking area; a first robot singulator and a second robot singulator, which work in parallel to transfer parcels within a picking area of the pick conveyor to the place conveyor; and a vision and control subsystem that communicates instructions to control operation of some or all of the foregoing components. The vision and control subsystem includes a target camera for acquiring one or more images of the picking area, which are processed within the system to determine the location of parcels positioned within the picking area. The vision and control subsystem can execute one or more routines or subroutines to reduce system downtime associated with image acquisition and processing, parcel transfer to the place conveyor, and/or parcel delivery to the picking area.

A surgical robotic system includes a ceiling mount assembly and a plurality of robotic arms coupled to a ceiling of an operating room via the ceiling mount assembly.

A multi-axis robotic arm includes a pedestal, a plurality of knuckle module and at least one detachable arm module. One of the plurality of the knuckle modules is connected with the pedestal. Two knuckle modules are connected to a first connecting element and a second connecting element. The first connecting element has a first docking portion, and the second connecting element has a second docking portion. The first docking portion and the second docking portion are detachably docked with each other by a plurality of fasteners. The at least one arm module have a third docking portion and a fourth docking portion. The third docking portion is detachably docked with the first docking portion by the plurality of the fasteners. The fourth docking portion is detachably docked with the second docking portion by the plurality of the fasteners.

A robotic arm control system including a robotic arm configured to deploy one or more tools in an operating space, one or more sensors, and a control system operably configured to: scan the operating space with the one or more sensors, identify a surface of the operating space based at least in part upon information sensed by the one or more sensors, establish a virtual barrier offset from the surface, and limit movement of the robotic arm based at least in part upon the virtual barrier.

System, methods, and other embodiments described herein relate to transporting an object into and out of a vehicle using an arm mounted to the vehicle. In one embodiment, a method includes detecting a plurality of objects in an environment of the vehicle, and identifying at least one object for transportation. The method includes determining at least one attribute for the at least one object, and determining a transport plan of how to move the at least one object into the vehicle based on the determined at least one attribute. The method includes, based on the transport plan, controlling the arm to move from a retracted position inside the vehicle to an extended position outside the vehicle, to engage the at least one object, move from the extended position to the retracted position, and disengage the at least one object to move the at least one object into the vehicle.

A robot system includes a cooking device to heat a cooking container and having an operation unit configured to select a temperature level; a robot configured to control the temperature level and a cooking time of the cooking device; a dust sensor disposed around the cooking device or on the robot to sense a concentration of foreign substances; a temperature sensor disposed around the cooking device or on the robot to sense a temperature of the cooking container or the cooking device; and a controller configured to control the robot in a safe mode such that at least one of the temperature level and the cooking time is varied according to a danger level determined by a concentration sensing value of the dust sensor and a temperature sensing value of the temperature sensor.