The present invention is to provide an industrial robot, which is placed in vacuum for use, capable of efficiently cooling down hand- or arm-driving motors which are arranged inside the arm in air. The industrial robot is provided with a motor for rotating a second arm unit with respect to a first arm unit, a motor for rotating a hand with respect to the second arm unit, a reduction gear for reducing the rotation of the motor and transmitting it to the second arm unit, and a reduction gear for reducing the rotation of the motor and transmitting it to the hand; the hand and the arm are placed in vacuum. The reduction gears and are coaxially arranged so that the center of rotation of the second arm unit with respect to the first arm unit coincides with the axial centers of the reduction gears. The interior space of the hollow first arm unit is kept at atmospheric pressure in which the motors and the reduction gears are arranged.

A mechanism comprises a first Halbach cylinder having an inner cavity, the first Halbach cylinder magnetized to produce a first magnetic flux concentrated circumferentially inside the inner cavity. A second Halbach cylinder is concentrically received in the inner cavity of the first Halbach cylinder to concurrently form a rotational joint having a rotational axis. One of the Halbach cylinders is a rotor and the other of the Halbach cylinders is a stator, the second Halbach cylinder magnetized to produce a second magnetic flux concentrated circumferentially outwardly. An output is connected to the rotor to rotate therewith relative to the stator, the output applying a gravity load on the rotor, the gravity load being offset from the rotational axis, whereby the magnetic flux of the first Halbach cylinder and the second Halbach cylinder cooperatively produce a torque against the gravity load caused by the output.

According to an embodiment, a manipulator includes the following elements. The first joint has a rotation axis in a first direction crossing a gravity direction. The second joint has a rotation axis in a second direction crossing the first direction. The first arm and the second arm are coupled with the second joint along a third direction crossing the second direction. The variable center-of-gravity unit coupled with the first arm. The controller controls the variable center-of-gravity unit to perform an operation for moving the first weight of the variable center-of-gravity unit in a direction crossing the rotation axis of the first joint and/or an operation for moving the second weight of the variable center-of-gravity unit in a direction crossing the rotation axis of the second joint.

Provided is a robot center-of-gravity display device including: a specification setting unit that sets specifications including the weights, center-of-gravity positions, and dimensions of components of respective shafts; a posture setting unit that sets position information of the respective shafts; a robot-image generating unit that generates a three-dimensional model image of the robot in a state where the respective shafts are located at the positions indicated by the position information, based on the set position information of the respective shafts and the specifications of the components; a center-of-gravity-position calculation unit that calculates the center-of-gravity position of the overall robot, based on the set position information of the respective shafts and the specifications of the components; an image combining unit that superimposes an indication showing the center of gravity of the overall robot on the three-dimensional model image at the calculated center-of-gravity position; and a display unit that displays the generated image.

According to an embodiment, a manipulator includes the following elements. The first joint has a rotation axis in a first direction crossing a gravity direction. The second joint has a rotation axis in a second direction crossing the first direction. The first arm and the second arm are coupled with the second joint along a third direction crossing the second direction. The variable center-of-gravity unit coupled with the first arm. The controller controls the variable center-of-gravity unit to perform an operation for moving the first weight of the variable center-of-gravity unit in a direction crossing the rotation axis of the first joint and/or an operation for moving the second weight of the variable center-of-gravity unit in a direction crossing the rotation axis of the second joint.

A robot includes a lower arm mechanism having a first parallel link structure, an upper arm mechanism having a second parallel link structure, a base portion forming a lower side part of the first parallel link structure, a wrist portion forming a distal side part of the second parallel link structure, an intermediate connection portion forming an upper side part of the first parallel link structure and a proximal side part of the second parallel link structure, and an upper arm biasing unit for applying a biasing force against a rotating operation in a direction that the wrist portion descends to an upper arm configuring a lower side part of the second parallel link structure. According to the robot, the range of the portable mass of an object can be expanded without enlarging an arm drive motor and declining an arm operation speed.

The invention relates to a pipe handling apparatus that delivers and positions tubulars at a wellhead and a device for assisting pivotal movement of a boom relative to a base of the apparatus. A pneumatic spring assembly is pivotally connected between the boom and base. During operation, the pneumatic spring assembly urges the boom from a first position to a second position and resists movement of the boom from the second position to the first position. A pneumatic reservoir may be attached to the pipe handling apparatus. A gas-charging assembly fluidically connects the pneumatic spring assembly and pneumatic reservoir and allows the pneumatic reservoir to vary the pneumatic pressure within the pneumatic spring assembly. Sensors mounted in the pipe handling apparatus may provide feedback to a controller which may automatically adjust the amount of pneumatic pressure within the pneumatic springs for ideal performance of the springs.

A pipe handling apparatus has a frame, a boom pivotally connected to the frame so as to be movable between a first position and a second position, an arm extending outwardly of the boom when the boom is in the second position, and a gripper affixed to the end of the arm opposite the boom. A pair of arm-tensioning mechanisms is connected to the arm and provide for tensioning of the arm. A pair of boom-lateral-adjustment mechanisms is connected to the upper portion of the boom and provide for lateral adjustment of the boom. A pair of rocker-arm-adjustment mechanisms is connected to the link and provide for adjustment of the link.