A robotic arm device includes a robotic arm including a base, a first arm and a second arm, a wire set adjacent to the first arm and the second arm, and a wire take-up module set in the first arm and including a rail, a sliding block and an elastic member. The sliding block is vertically slidably set on the rail and connected with the wire set and the elastic member. With the configuration of the wire take-up module, the robotic arm device can achieve the effects of improving wiring convenience, reducing wiring interference and saving wiring time.

A transfer robot comprises a movable chassis, a door frame vertically arranged on the movable chassis, and a temporary storage mechanism and a cargo box conveying mechanism which are arranged on the door frame, wherein the temporary storage mechanism is provided with a plurality of temporary storage spaces used for temporarily storing cargo boxes, and the cargo box conveying mechanism can stretch horizontally and lift vertically relative to the door frame so as to convey the cargo boxes between the temporary storage space and a temporary inventory container.

A robot includes one or more rotary joints, each of the rotary joints including a motor, a reducer that reduces the rotational speed of the motor, and a first member and a second member that are connected by the reducer and that are supported so as to be rotatable about a center axis of the reducer. The first member of at least one of the rotary joints is provided with a flange securing portion that secures a flange of the motor at an eccentric position with respect to the center axis of the reducer. Bolts that secure the first member to the reducer are disposed in a region in which the flange is disposed when viewed from a direction along the center axis.

A robot arm including a first joint, a second joint, and a coupling element is provided. The first joint has a first inclined surface. The second joint is jointed to the first joint and has a second inclined surface. The coupling element has a third inclined surface and a fourth inclined surface opposite to the third inclined surface, wherein the third inclined surface contacts the first inclined surface, and the fourth inclined surface contacts the second inclined surface.

Provided is a robot including a main body provided with a pair of traveling wheels that are spaced apart from each other in a horizontal direction, a seating body disposed above the main body, a foot supporter disposed on a front lower portion of the main body, at least one front wheel disposed on the foot supporter, and a rear wheel disposed on the main body so as to be closer to a rear end of the main body than a front end of the main body and the traveling wheel is closer to the front end of the main body than the rear end of the main body.

A robotic post system includes one or more composable robotic posts each having a processor and a memory. At least one composable post includes a set of modules including one or more pairable latches which is configured to couple and lock with another pairable latch from among another set of modules included on another of the composable posts, such that the composable robotic posts form a composable surface supported by the composable robotic posts.

Embodiments of the present disclosure disclose a mounting bracket and a self-propelled robot. The mounting bracket includes a housing, a rotating shaft and a magnetic positioning assembly. The housing is provided with an inner cavity. The rotating shaft is configured to rotate about an axis in the inner cavity. The magnetic positioning assembly includes a first magnetic element and a second magnetic element which are respectively arranged on the housing and the rotating shaft. The laser distance sensor is attached to the rotating shaft and configured to rotate about the axis. The mounting bracket is configured to prevent the rotating shaft from deviating from the axis by generating a force between the first magnetic element and the second magnetic element in a radial direction of the rotating shaft.

A robot includes a base installed on an installation surface, a robot arm coupled to the base, a force detection section coupled to the base and detecting a force applied to the robot arm, a coupling member having a plurality of convex parts provided between the installation surface and the force detection section, projecting toward the force detection section side, and contacting the force detection section, and first fixing members provided in positions where the convex parts are provided and fixing the force detection section and the coupling member.

A modular frame for an intelligent robot includes a base and one or more devices for performing specified functions. The base controls the actions and functions of the robot and contains a memory of operating instructions for a plurality of modules, each module performing unique functions. The base has a smart connector. The devices for performing specified functions have a smart connector which contains a unique code for that device or module and firmware for operation of the module. When a module is affixed on the modular frame, the smart connector of the module electronically communicates with the smart connector of the base, thereby providing the base with sufficient operating information to operate the intelligent robot.

A robotic medical system can include a motorized arm that is supported by a column of the system. The robotic arm can be operated by rotating a link of the motorized arm by actuating an actuator to drive rotation of a rotary joint. A brake can then be applied to the rotary joint to stop rotation of the link. The arm can also include an arbor that can be actuated to increase a torsional stiffness of the rotary joint.