A displaceable robot for performing operations using a tool near a high temperature furnace containing molten metal, wherein the robot is displaceable using a vehicle. The robot comprising: a frame having a ground interface for coming into contact with a ground surface while defining a clearance under a portion of the frame for engaging with the vehicle to displace the robot about the furnace when the ground interface is off the ground; an arm mounted to the frame, the arm comprising an end effector which is adapted for mounting the tool; a sensor for collecting at least one of exteroceptive data in a vicinity of the robot and proprioceptive data from the robot; and a controller receiving the collected data from the sensor and controlling a movement of at least the arm based on the collected data.

The present disclosure provides an object recognition apparatus, which includes: an actuator unit configured to contact an object and generate vibrations and transmit them through objects based on the inherent characteristic of the object; and a sensor unit connected to the actuator unit to receive the vibration and generate a voltage signal.

Methods and systems for enhancing robot's ability to collaborate with human operators by constructing models of objects and processes which are manipulatable by a robot (situation models) and sharing such models with operators. Sharing situation models allows robot to explain its actions to operators in the format they can readily understand. Reciprocally, operators can formulate their instructions to the robot in the format that is both easy to produce for the human and straightforward to interpret in the machine. In this way, the disclosed method and system for constructing situation models in the robot facilitate both adaptation of human operators to robots and adaptation of robots to human operators, thus enhancing collaboration between them.

A method for force or torque sensing in an electromechanical actuator-driven robot comprising one or more links, one or more joints, an end effector and a controller is provided, the method comprising: estimating a first set of load torques in one or more joints in a given configuration of the robot without external force or load applied to the end effector; identifying gravitational and frictional components in the first set of load torques; estimating a second set of load torques in the one or more joints in the given configuration of the robot with an external force or load applied to the end effector; calculating a difference between the second set of load torques and the first set of load torques, taking into account the identified gravitational and frictional components; calculating an external force or torque acting on the end effector based on the difference between the second set of load torques and the first set of load torques using a Jacobian matrix for the given configuration of the robot; and presenting the external force or torque in a Cartesian space. An apparatus for force or torque sensing in an electromechanical actuator-driven robot, the apparatus comprising at least one processor programmed to perform said method, a computer program which, when executed by at least one processor, causes the at least one processor to perform force or torque sensing in an electromechanical actuator-driven robot according to said method, and a non-transitory storage medium for storing said program are also provided. The technical result consists in improved precision of force or torque sensing on an end effector of an electromechanical actuator-driven robot in a manner which does not require using expensive force/torque sensors in robot joints.

A mobile robot including a mobile base element and at least one multi-jointed manipulator, wherein the robot includes several telemedical devices. The invention also relates to a robot for performing a movement sequence together with a limb of a human with the help of a manipulator.

A robot for detecting and saving a life, includes: a body part including a plurality of unit joints; a head part which is provided at the front of the body part in the direction in which the body part moves forward, and which has a gripper capable of picking up an object by a plurality of tongs parts that are folded and unfolded; and an extension part capable of extending forward from the head part so as to enter a small space that is difficult for the body part to enter.

A robot includes a body, a wheel having a ground contacting surface when moving, and a wheel drive mechanism that drives the wheel so as to advance from a housing space provided in the body to an exterior and withdraw. The wheel drive mechanism causes the wheel to withdraw to the housing space in a non-ground contacting state when a housing condition is satisfied. The body has a ground contacting bottom face that comes into contact with the ground when the wheel is housed in the housing space in a non-ground contacting state.

An autonomous solar module installation platform can be used for solar module installation onto a solar tracker. The autonomous solar module installation platform can include an autonomous ground vehicle and a robotic arm for the solar module installation onto the solar tracker. The autonomous ground vehicle can autonomously drive itself to the solar tracker using a global positioning system and align itself with the solar tracker using at least a vision system in order to place one or more solar modules onto the solar tracker.

A generation laser irradiation device irradiates a weld after welding with a generation laser. A detection laser probe irradiates an ultrasonic detection point that passes through the weld and is capable of detecting an ultrasonic wave reflected on a lower surface of a base material with detection laser. A control device determines existence of an internal defect of the weld based on a measurement result of a laser interferometer. The generation laser irradiation device includes a scanning mechanism that scans an irradiation position of the generation laser in a direction intersecting a welding direction.

Systems, methods and apparatus for automated vehicle wheel removal and replacement are provided. One system includes a computer system with applications for scheduling the replacement of tires for the vehicle. An electronically controlled lift device and robotic apparatus is configured for interaction with the computer system. The lift device mechanically adjusts arms for placement on lift points of vehicles. The robotic apparatus detects positioning of lug nut configuration for a wheel, removes lug nuts, and then removes the wheel from the wheel hub with gripping arms. The wheel and tire are then handed off to a separate tire changing machine. When a new tire is replaced the robotic apparatus then mounts the wheel to the original wheel hub, and then secures the lug nuts to the lug nut bolts.