Telerobotic, telesurgical, and surgical robotic devices, systems, and methods selectively calibrate end effector jaws by bringing the jaw elements into engagement with each other. Commanded torque signals may bring the end effector elements into engagement while monitoring the resulting position of a drive system, optionally using a second derivative of the torque/position relationship so as to identify an end effector engagement position. Calibration can allow the end effector engagement position to correspond to a nominal closed position of an input handle by compensating for wear on the end effector, the end effector drive system, then manipulator, the manipulator drive system, the manipulator/end effector interfacing, and manufacturing tolerances.

This disclosure provides systems and methods for an actuated sensor module for in situ gap inspection robots. A mounting interface attaches to the sensor module to the robot system. A least one arm is operatively connected to the mounting interface and has a joint. A sensor head is operatively connected to the arm at the joint and an actuator operatively connected to the arm moves the sensor head around the second joint.

A method for robotic inspection of a part, includes the steps of: supporting the part with a robot mechanism; obtaining part-related sensor input with a sensor positioned to inspect the part supported by the robot mechanism; and controlling movement of the robot mechanism relative to the sensor, wherein the controlling is done by a feedback control unit which receives the sensor input, and the feedback control unit is configured to control the robot mechanism based upon the sensor input.

A line bypass system includes a support structure including a first support portion and a second support portion spaced apart from the first support portion. The support structure includes an attachment portion that attaches the first support portion to the second support portion. The first support portion and the second support portion define a first opening on a first side of the attachment portion and a second opening on a second side of the attachment portion. The first opening movably receives a first guide wire and the second opening movably receives a second guide wire.

Disclosed herein are systems and methods for a robotic system capable of carrying out operations in a hazardous or confined space. The system comprises a manipulator arm, a plinth, a trolley, an end effector, and a control system. The plinth and trolley each comprise one or more locking pawls for securing the system to mounting points. The system is capable of maneuvering between mounting points in an inch-worm-like fashion. Motion starts from a fixed position where both the trolley and plinth locking pawls are secured to a first mounting point. The trolley locking pawls are then released and the trolley runs along the manipulator and secures locking pawls to a second mounting point. The plinth locking pawls are then released and the plinth is drawn to the second mounting point where it is secured via locking pawls. When both the plinth and trolley are secured, operations can be carried out.

A leak check system is provided, which supplies air to inspection target space that an object to be inspected has and checks leak based on a pressure change of inspection target space. System includes pedestal, robotic arm including plurality of arm bodies serially coupled from pedestal, robot control device configured to control operation of robotic arm, air supply hand, having air discharge part connected to object to be inspected to discharge air into inspection target space, and attachably and detachably attached to a tip-end part of robotic arm, air supply source, air supply pipe configured to lead air from air supply source to air discharge part, pressure sensor, provided to air supply pipe, and configured to send detected pressure data to robot control device, and air supply mechanism of which supply of air from air supply source to air discharge part is controlled by robot control device.

A method of locating a maintenance vehicle in a solar power field can include driving the maintenance vehicle on a track. A plurality of flags are coupled to the track at spaced locations. Each flag can include an ID tag and a contact target or a non-contact target. The maintenance vehicle can include an ID tag reader and a sensor configured to detect the contact target or the non-contact target. The method also can include driving the maintenance vehicle along the track to a position adjacent to a flag of the plurality of flags, reading by the ID tag reader the ID tag of that flag, and sensing by the sensor the contact target or the non-contact target. The method also can include, based on the reading and the sensing, identifying a unique location of the maintenance vehicle in the solar power field.

The sealing of a crack in a pool of a nuclear facility, using a robot. The sealing, concerns in particular, that of a crack in a wall of a pool of a nuclear facility. In particular, it implements a mobile robot carrying an adhesive tape dispenser. At least the following are provided: controlling a plurality of suction systems, the dispenser being mechanically integral with a first suction system, and controlling the movement of the first system relative to the other systems of said plurality of systems.

A method includes receiving, via at least one sensor of a robot, sensor data indicating one or more characteristics of an asset. The method includes detecting, based on the sensor data, an existing or imminent defect of the asset. The method includes fabricating a part suitable for use in correcting the defect. The structure of the part is derived using one or both of a digital representation of the asset generated using the sensor data or stored reference data related to the asset.

In one embodiment, a method includes receiving, from a first sensor on a robot, first sensor data indicative of an environment of the robot. The method also includes identifying, based on the first sensor data, an object of an object type in the environment of the robot, where the object type is associated with a classifier that takes sensor data from a predetermined pose relative to the object as input. The method further includes causing the robot to position a second sensor on the robot at the predetermined pose relative to the object. The method additionally includes receiving, from the second sensor, second sensor data indicative of the object while the second sensor is positioned at the predetermined pose relative to the object. The method further includes determining, by inputting the second sensor data into the classifier, a property of the object.