The present invention relates to a robotic inspection device (10) comprising at least one pair of robotic modules (1) connected together by means of an articulated joint (9), with at least one displacement device (2) coupled to a rail (11); the displacement device (2) comprising at least one pair of pivoted brackets (3); at least one of the robotic modules (1) comprising at least one within an instrumentation system (7) and a manipulator arm (8).

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.

A programmable digital machine vision inspection system is disclosed having a programmable automatic feeding system that supplies elements to be inspected, a programmable robot system, a programmable inspection system, a qualified product receiving container, and an unqualified product receiving container. The programmable robot system has a first vision system with an inspection area, and a robot that grips the supplied element and moves the gripped element to and from the inspection area. The programmable inspection system has a second vision system that identifies features of the elements in the inspection area, and determines whether the element is a qualified product based on the identified features. The qualified product receiving container receives identified qualified products from the robot, and the unqualified product receiving container that receives identified unqualified products from the robot.

Described herein is a local electrical room (LER) for use in an industrial facility such as an oil and gas facility. The LER includes one or more robots that perform functions on the electrical equipment enclosed therein. The LER is filled with a non-atmospheric fluid or gas and may be cooled and/or pressurized for optimal performance of the electrical equipment.

An electrical discharge machine is disclosed having a concentration detection function for a rust inhibitor containing an organic compound uses coloring of a metal complex produced through the reaction of the rust inhibitor with a color reagent to enable a detector to detect the change of characteristics involved in the change of the color of the metal complex. A predetermined amount of working fluid is sampled in a sampling cell at regular time intervals, a predetermined amount of color reagent is added to the working fluid, and the change of the color of the working fluid is detected by the detector.

Provided is a blade maintenance device for a wind turbine. The blade maintenance device for the wind turbine includes: a body that travels along a leading edge of a blade; support units that extend from the body to both sides of the blade and support the sides of the blade; and a maintenance unit installed at at least one of the body and the support units so as to perform maintenance of an outer side of the blade.

A line bypass system is provided having a guide wire. The line bypass system has a support structure defining a first channel, into which a first wire portion of the guide wire is received. The support structure has a second channel, extending parallel to the first channel, into which a second wire portion of the guide wire is received. The first channel is dimensioned to facilitate engagement of a robot with the first wire portion and the second channel is dimensioned to facilitate engagement of a robot with the second wire portion as the robot traverses the support structure.

A position detection system includes: a contactor including a tracing unit that traces and fits with a recess or a protrusion of an object; a slide member; a sliding unit that causes the slide member to slide in two directions; a moving unit that causes the contactor to move in a direction perpendicular to a plane so as to cause the tracing unit of the contactor to trace and fit with the recess or the protrusion of the object; a contactor detecting unit that detects a position of the contactor in the plane; and an object position detecting unit that detects the position of the object based on movement amount of the contactor before and after the slide member slides on the sliding unit to slide, when the tracing unit traces the recess or the protrusion.

Sensory processing of visual, auditory, and other sensor information (e.g., visual imagery, LIDAR, RADAR) is conventionally based on stovepiped, or isolated processing, with little interactions between modules. Biological systems, on the other hand, fuse multi-sensory information to identify nearby objects of interest more quickly, more efficiently, and with higher signal-to-noise ratios. Similarly, examples of the OpenSense technology disclosed herein use neurally inspired processing to identify and locate objects in a robot's environment. This enables the robot to navigate its environment more quickly and with lower computational and power requirements.

To reduce influence of vibrations resulting from operations of a robot and also ensure excellent workability in installation.

An industrial robot according to an embodiment of the present technology includes a robot main body, a first base, a second base, and a coupling frame. The first base includes a first upper end portion and a first bottom portion, the first upper end portion supporting the robot main body, the first bottom portion being provided on a floor surface. The second base includes a second upper end portion and a second bottom portion, a plurality of works processed by the robot main body being placed on the second upper end portion, the second bottom portion being provided on the floor surface. The coupling frame couples the first bottom portion and the second bottom portion to each other.