A robot device includes a first link configured to rotate on a first axis, a second link supported by a tip-end part of the first link so as to be rotatable on a second axis, and a hand part supported by a tip-end part of the second link. When one direction perpendicular to the first axis is a first perpendicular direction, and a direction perpendicular to both the first axis and the first perpendicular direction is a second perpendicular direction, the second axis extends in parallel to the first perpendicular direction and is deviated from the first axis in the second perpendicular direction.

An end-effector may include a base, a plurality of underactuated fingers coupled to the base; and an adhesion gripper coupled to the base. An end-effector may include a base, an actuator, a first underactuated finger comprising a proximal link and a distal link, the proximal link including a distal end, a guide for a first tendon spaced a first distance away from the distal end of the proximal link and the distal link including a lever arm disposed on a proximal side to the distal pad and which extends in a volar direction from a first axis, and a node disposed on the lever arm sized and shaped to receive a first tendon. The end-effector may include a first revolute joint compliant in a first direction disposed between the base and the proximal link; and a second revolute joint compliant in the first direction disposed between the proximal link and the distal link.

An inspection robot comprises a control cabinet, an actuator, and a base. The control cabinet and the actuator are oppositely arranged on the base in a direction parallel to a plane where the base is located. The control cabinet is configured to control a path of movement of the actuator. The actuator and the control cabinet are both installed on the same panel of the base, so that the load is more uniformly distributed on the base. Also provided is an inspection method.

A coordinate positioning arm includes: a base end and a head end; a drive frame for moving the head end relative to the base end; and a metrology frame for measuring a position and orientation of the head end relative to the base end. The drive frame includes a plurality of drive axes arranged in series between the base end and the head end. The metrology frame includes a plurality of metrology axes arranged in series between the base end and the head end. The metrology frame is adapted and arranged to be substantially separate and/or independent from the drive frame, for example by supporting the metrology frame substantially only at the base end and head end and by providing the metrology frame with sufficient degrees of freedom (via the metrology axes) to avoid creating an additional constraint between the metrology frame and the drive frame.

A robot includes a wrist unit that has a tool attached to a distal end face thereof and that changes the orientation of the tool, the tool performing work on a work target device secured to an installation surface; and a movable unit that changes the three-dimensional position of the wrist unit. The movable unit includes an arm that has a longitudinal axis and the wrist unit is attached to the distal end thereof, and a visual sensor that has a field of view oriented in a direction intersecting the longitudinal axis of the arm is attached to the a positon closer to the base end than the distal end face of the wrist unit is.

Provided is a robot. For example, a joint part of this robot is provided with: a motor; a reduction gear coupled to the motor; an output-side member fixed to the output shaft of the reduction gear; a position detection mechanism for detecting the rotational position of the motor; a circuit board to which the motor and the position detection mechanism are electrically connected; and a case in which the motor, the reduction gear, the position detection mechanism, and the circuit board are housed. The motor and the reduction gear are fixed to the case. A motor driving circuit for driving the motor, a signal transmission circuit for outputting a signal inputted to the circuit board to outside the circuit board, and a connector to which an end of a wiring is connected are mounted to the circuit board.

An operating device configured to operate in a work space, the operating device including: a robot arm, which includes a succession of arm elements mounted on one another in a rotatable way about respective axes of rotation and which carries an operating unit on its end; and at least one presence sensor prearranged for detecting the presence of an operator. The device includes a positioning system, including a support by which the at least one presence sensor is carried and which is mounted on an arm element of the robot arm, according to a pre-set orientation and in such a way as to be orientable with respect to the arm element, and wherein the positioning system further includes a positioning unit prearranged for rotating the support with respect to the arm element, as a result of a movement of the robot arm, so as to keep the pre-set orientation of the support unchanged.

A robot includes a base, a spin body rotatably connected to the base, a tilting base tiltably connected at a tilting shaft to the spin body, a first tilting housing to which the tilting base is fixed therein, a second tilting housing which is fastened to the first tilting housing and to which the tilting base is fixed therein, and a tilting supporter connecting an inner side of the first tilting housing and an inner side of the second tilting housing. The tilting supporter is disposed at a position through which a rotational axis of the spin body passes.

Methods and systems are provided for providing real world assistance by a robot utility and interface device (RUID) are provided. A method provides for identifying a position of a user in a physical environment and a surface within the physical environment for projecting an interactive interface. The method also provides for moving to a location within the physical environment based on the position of the user and the surface for projecting the interactive interface. Moreover, the method provides for capturing a plurality of images of the interactive interface while the interactive interface is being interacted with by the use and for determining a selection of an input option made by the user.

A foldable boom for conveying an item, said foldable boom being foldable about at least one folding axis, said foldable boom being locatable in a folded stowed position, and moveable to unfolded extended positions; said foldable boom having a near end arranged for pivotal movement about a first horizontal axis located on a turret, said turret being rotatable about a vertical axis; said foldable boom having first conveying apparatus to convey an item therealong, internally within said foldable boom, to a remote end of the foldable boom; wherein said foldable boom is foldable about a folding axis, and a pivoting shuttle equipped with a clamp to releasably hold an item is provided at said folding axis to transfer said item between said first conveying apparatus in boom elements connected about said folding axis.