A robotic platform manipulating peripheral nerve system includes a manipulator and a recorder. The manipulator includes a rotating guide, a plurality of rotating movers and a plurality of manipulating units. The rotating guide has an opening portion through which the recorder records, and has a guide rail at a side. The rotating movers are combined with the rotating guide and move along the guide rail. The manipulating units are respectively fixed to the rotating movers, and a manipulating part performs the operation being connected to an end of each of the manipulating units.

Disclosed is a biped robot and multi-configuration robot capable of being spliced autonomously, and a control method of the multi-configuration robot. The biped robot comprises a torso, arms, legs, a tolerance docking sleeve, and a torso docking device. The arms are correspondingly arranged at the left and right sides of the torso, and two legs are arranged at the lower side of the torso. The tolerance docking sleeve is movably arranged at the rear side of the torso through a base, and the torso docking device is fixed to the front side of the torso. Single biped robots in the present disclosure can form a multi-configuration legged combined body in a self-organization and reconstruction mode so as to achieve bipedal, quadrupedal, hexapodal and other multi-legged configurations. The motion stability and the load capacity of the legged robot are improved through the splicing combination of the modular legged robots.

A robotic arm comprising a first arm portion, a second arm portion, the second arm portion moveable between a first axial position, in which the first arm portion and the second arm portion are mutually spaced from each other along said axis, and a second axial position, in which a first end of first arm portion and a second end of the second arm portion are in contact to define a housing, a head rotatable with respect to the first arm portion and around said axis; and a robotic joint. The joint is configured for adopting an operative condition, to make the second arm portion integral with the head. The robotic arm is configured so that said operative condition corresponds to said second axial position and said second angular position and the robotic arm is configured so that, in said operative condition, the joint is located within said housing.

Provided is a device, comprising: a barrier configured to impeded or prevent particles shed by a robot in a first volume of space from entering a second volume of space in which the robot manipulates a workpiece; and a robot having three or more degrees of freedom, the robot comprising: a first portion disposed on a first side of the barrier in the first volume, the first portion comprising an actuator of the robot, the actuator being configured to drive movement of the robot to manipulate the workpiece; and a second portion disposed on a second side of the barrier in the second volume, the second portion comprising an end-effector of the robot by which the robot makes contact with the workpiece.

A labware transport apparatus includes a frame, defining a labware space, and a robotic multi-link arm operably connected to the frame via a drive section. The arm has a predetermined link configuration determining a minimum footprint of the arm and a corresponding maximum reach of an end effector of the robotic multi-link arm within a range of motion of the end effector. The range of motion, at least in part of the labware space, of the end effector is delimited by a blockage of a substantially vertical axis of motion, of the drive section of the robotic multi-link arm, extending through the range of motion, wherein the blockage is sized and shaped based on and so as to maximize the range of motion of the end effector of the robotic multi-link arm having the predetermined link configuration that is common determining the minimum foot print and the corresponding maximum reach.

Provided is a robot including a main body including a traveling wheel, an accessory mounting portion and an opening, the opening being spaced apart from the accessory mounting portion, a rear sensor which is accommodated in the opening and facing a rear of the robot to sense outside of the main body, and an accessory including a mounter mounted on the accessory mounting portion and a supporter for supporting an article.

A robot is provided with driving wheels, a battery, a charging terminal, a charging terminal mounter in which the charging terminal is disposed, a first spring elastically supporting the charging terminal in an outward direction, a switch switched by the charging terminal mounter when the charging terminal mounter retreats, and a processor for stopping the driving wheels when the switch is switched by the charging terminal mounter.

The present invention relates to a working robot. According to one embodiment of the present invention, the working robot comprises: a body; a plurality of traveling units connected to the body, having supporting members and traveling members rotatably connected to the supporting members, and provided so as to be travelable with respect to the ground; and a plurality of adjusting units connecting the body and the traveling units, and provided to enable the relative positions of the traveling units to the body to be adjusted, wherein the plurality of traveling units are traveled and the plurality of adjusting units are adjusted so as to maintain the horizontal state of the body.

In order to extend a life span of a flexible cable passing through a movable portion, provided is a hand mechanism which has a plurality of fingers and grips an object with the fingers, including: a flexible cable; a joint which flexes or extends with the grip of the object, has a path for the flexible cable, and has a first surface and a second surface that is a surface bending from the first surface at a bending portion in the path; and a sheet which is provided between the first surface and the flexible cable to have flexibility and is formed such that a gap is provided between the second surface and the sheet.

In a packaging line (1) comprising a plurality of robots (7), in order to be able to replace a faulty unit, in particular robot (7), quickly and with minimal, preferably no manpower, in particular during running operation of the packaging line (1), the unit to be changed is automatically decoupled from the power and data feeds and from the purely mechanical connections and is removed from the packaging line (1), preferably transversely to the throughput direction (10′) of the packaging line (1), and the new unit is automatically introduced in the opposite direction, is positioned, and is mechanically fixed, and the energy and data supplies are automatically coupled.