In this invention it is disclosed a remote-controlled vehicle for operations in the extreme conditions (10) which comprises a base vehicle (100), a gripper (200), a manipulator arm (300), a mission module wherein base vehicle comprises front (110) and rear part (120), wherein on the front part of the base vehicle gripper is mounted and on the rear part of the base vehicle the manipulator arm is mounted and when in operation, the gripper and the manipulator arm are remotely operated. Also, it is disclosed whole system for remote operations comprising said remote-controlled vehicle and a control centre comprising a set of graphical user interfaces (GUI) and video displays (VD) arranged so that two way communication between the vehicle and control centre is established and wherein from GUI person can control and operate with the vehicle.

The present disclosure relates to the technical field of cable inspection, and specifically, to a cable trench inspection robot. The cable trench inspection robot includes a base spreading system, and a camera lifting system disposed on the base spreading system, where the base spreading system includes a base plate, a linear action unit, a cantilever plate, a walking assembly, and a jacking assembly, and the camera lifting system includes a travel block, an imitated four-bar assembly, a support rod, and a camera assembly. The present disclosure can realize a through-wall operation by using a cable trench, thereby avoiding many use problems caused by a firewall, and efficiently completing a predetermined inspection task.

The invention relates to a demolition robot (1), comprising a cable (12) intended to be connected to an electric network to power a motor (21), a pump (22) that is powered by the electric motor for generating a hydraulic flow to consumers (13), wherein the motor (21) is activable at varying thermal load values (PT), depending on the current consumer's (13) need for hydraulic power, a control unit (24) arranged to receive information about the thermal load (PT) on the motor, to determine a partial thermal damage value (SL, SM, SH) at various thermal loads (PT) on the motor. To minimize the risk of thermal damage to the motor, the control unit (24) is adapted to compare said partial thermal damage values (SL, SM, SH) with a normative partial thermal damage (A) and is adapted to limit the thermal load (PT) on the motor (21) to a maximum allowable thermal load value (PTmax), if the partial thermal damage value (SL, SM, SH) exceeds the normative partial thermal damage (A) at a predetermined value (A′).

An automatic method for autonomous interactions between robots, comprising an action of automatically receiving, by a transport robot, a request for transporting a service robot. The method comprises an action of automatically computing a location of the service robot. The method comprises an action of automatically moving the transport robot to the location of the service robot. The method comprises an action of automatically sending a signal from the service robot to the transport robot using a signal emitter incorporated into a mechanical element attached to the service robot. The method comprises an action of automatically coupling, using the signal, the mechanical element to a carrier element attached to the transport robot.

An unmanned ground vehicle includes a main body, a drive system supported by the main body, a manipulator arm pivotally coupled to the main body, and a sensor module. The drive system includes right and left driven track assemblies mounted on right and left sides of the main body. The manipulator arm includes a first link coupled to the main body, an elbow coupled to the first link, and a second link coupled to the elbow. The elbow is configured to rotate independently of the first and second links. The sensor module is mounted on the elbow.

An omni-bearing intelligent nursing system and method for a high-infectious isolation ward, including: a nursing robot, including a robot body and a controller; a plurality of collectors, arranged in the isolation ward and used for detecting the physiological index of the user and transmitting the physiological index to a remote control system; a communication network, in a star topology structure and including a plurality of communication modules, and configured to realize the communication of each the nursing robot, the collector and the remote control system; and the remote control system, receiving the information of the collector, performing feature extraction on the collect multi-element physiological signals, combining the basic information of the user, perform learning by a decision tree model, dynamically adjusting the corresponding nursing level, and sending an instruction to the corresponding nursing robot.

A method and system for installing Stockbridge dampers on wires, such as power lines and guy wires, is described. The method and system include the use of a robotic Stockbridge damper installer onto the wires where the robotic installer is configured to place Stockbridge dampers on the wire as the robotic installer travels along the wire.

A robotic device may include a spine defining a yaw axis. The robotic device may also include an arm joint rotatably connected to the spine at a first position along the yaw axis and configured to rotate about the yaw axis. The robotic device may further include an actuator including a ring that defines a bore. The spine may be fixedly connected to the ring at a second position along the yaw axis and may extend through the bore. The actuator may be connected to the arm joint and configured to rotate the arm joint about the yaw axis without rotating the spine.

Disclosed is a rebar automating robot for rebar tying on at least one rebar intersection. The rebar automating robot includes a control box 120 and a processing device 108. The control box 108 includes at least one intersection detection sensor 104 and at least one positioning sensor 106. The at least one intersection detection sensor 104 and the at least one positioning sensor 106 identifies a location of the at least one rebar intersection of a work area. The method includes (a) navigating, the rebar automating robot to a first rebar intersection for tying the first rebar intersection, (b) tying, by a rebar tying tool, the first rebar intersection of the work area, and (c) navigating, the rebar automating robot, from the first rebar intersection to a second rebar intersection for performing rebar tying at the second rebar intersection of the work area.

A novel sprocket for a track drive of a mobile robot may allow for some deformation of the track so that the track better conforms to the surface on which the robot travels. The novel sprocket also may prevent excessive track deformation or deflection that may result in undesirable de-tracking.