A mobile robotic system including a floor assembly having a support surface and a reconfigurable pathway, wherein an automated guided vehicle is configured to travel on the support surface and follow the reconfigurable pathway.

A triaxial motion device includes first, second and third bases, first and second power sources, and a workpiece positioning member. The first power source is disposed on the first base and has a first driving shaft. The second base is connected with the first driving shaft through a cannular rotary shaft in a way that the second base is rotatable about a first axis. The second power source is disposed on the first base and has a second driving shaft penetrating through the cannular rotary shaft. The third base is connected with the second driving shaft in a way that the third base is rotatable about a second axis perpendicular to the first axis. The workpiece positioning member is disposed on the third base and rotatable about a third axis perpendicular to the second axis. Therefore, the triaxial motion device has small volume and performs highly precise motion.

In an embodiment, a mobile robotic device includes a mobile base and a mounting column fixed to the mobile base. The robotic device further includes a seven-degree-of-freedom (7DOF) robotic arm, including a rotatable joint that enables rotation of the 7DOF robotic arm relative to the mounting column. The robotic device additionally includes a perception housing comprising at least one sensor, where the mounting column, the rotatable joint of the 7DOF arm, and the perception housing are arranged in a stacked tower such that the rotatable joint of the 7DOF arm is above the mounting column and below the perception housing.

A mobile robotic device includes a mobile base and a mast fixed relative to the mobile base. The mast includes a carved-out portion. The mobile robotic device further includes a three-dimensional (3D) lidar sensor mounted in the carved-out portion of the mast and fixed relative to the mast such that a vertical field of view of the 3D lidar sensor is angled downward toward an are in front of the mobile robotic device.

A robot arm comprising a number N of actuator-drivable joint connections GV.sub.n, which are connected in series via arm links GL.sub.i, where n=1, 2, . . . , N, and i=1, 2, . . . , N1, and N6, wherein the robot arm is configured in such a way that the axes of rotation R.sub.GV,N-2 and R.sub.GV,N-1 of each of joint connections GV.sub.N-1, GV.sub.N-2 intersect at an angle in the range from 50 to 130, an axis of rotation R.sub.GV,N of joint connection GV.sub.N, is arranged radially at a constant distance D1 from the axis of rotation R.sub.GV,N-1, and a sensor is present in the joint connection GV.sub.N-1 to detect a force or a torque about the axis of rotation R.sub.GV,N-1.

A working device includes a link actuation device and a control device for the link actuation device. The control device includes: a storage unit configured to store a plurality of the target positions; a calculation unit configured to sequentially read out the respective target positions stored to calculate movement amounts and movement speeds of the respective actuators between the target positions; and a control unit configured to operate the respective actuators by the movement amounts and at the movement speeds of the respective actuators calculated by the calculation unit. The control unit is capable of changing acceleration and deceleration times of the actuators for each of the target positions.

A vehicle charging station includes a track configured to extend across a plurality of vehicle parking spaces. The charging station further includes a movable charging apparatus supported by the track and translatable along the track between the plurality of vehicle parking spaces. The charging station further includes a first contact wire extending approximately parallel to the track. The charging station further includes a first conductor pole configured to couple the movable charging apparatus to the first contact wire at a plurality of locations along a width of the first contact wire. The first conductor pole is configured to move with the movable charging apparatus. In such a manner, a one-to-many charging station can be accomplished.

Disclosed is an inspection robot, comprising a control cabinet, an actuator, and a base. The control cabinet and the actuator are oppositely arranged on the base in a direction parallel to a plane where the base is located. The control cabinet is configured to control a path of movement of the actuator. The actuator and the control cabinet are both installed on the same panel of the base, so that the load is more uniformly distributed on the base. Also provided is an inspection method.

A robotic system includes a base and at least one axis actuation module. The base includes an input power conversion device. A power input terminal of the input power conversion device receives an input voltage. The input voltage is converted into a first voltage by the input power conversion device. The first voltage is outputted from a power output terminal of the input power conversion device. The at least one axis actuation module is installed on the base. Each axis actuation module includes a motor, an axis power conversion device and a driving device. The first voltage is converted into a second voltage with a rated voltage value by the axis power conversion device. The second voltage is converted into a third voltage by the driving device. The third voltage is provided to the motor.

A machine tool for machining a workpiece has a spindle arm with a spindle for receiving a tool or workpiece. The spindle arm is movably attached to a spindle arm receiving section. The spindle arm has a first spindle arm section, being a longitudinal element, having a first rotational axis with respect to the spindle arm receiving section and is hinged to the spindle arm receiving section; a second spindle arm section, rotatable about a second rotational axis with respect to and is hinged to the first. The spindle arm receiving section has a first subsection and a second subsection, arranged on the machine column at a distance from one another to receive the spindle arm. The first spindle arm section has first and second subsections, which are arranged on the spindle arm receiving section at a distance from each other to receive the second spindle arm section.