The present invention relates to a device for transferring media from an industrial robot to a tool, and an industrial robot including the device. The device comprises a swivel adapter (1) having a body (5) including a first coupling unit (7) arranged in one end of the body for coupling the swivel adapter to the robot, and second coupling unit (9) arranged in an opposite end of the body for coupling the swivel adapter to the tool, and a distance element (13) having a lower portion (15) attached to the first coupling unit and an upper portion (17) attached to the second coupling unit, wherein the first and second coupling units are spaced apart from each other along a common central axis (C1) so that a gap (11) is formed between them. The lower portion of the distance element is disposed at a distance the periphery of the first coupling unit, and the second coupling unit is provided with a penetration hole (19) in communication with the gap (11). The upper portion (17) of the distance element is arranged so that a space is formed between the upper portion of the distance element (13) and the first coupling unit (7). The penetration hole is formed between the distance element and the second coupling unit (9). The penetration hole is partly surrounding the distance element. The penetration hole extends an angle around the common central axis and in a curved direction around the distance element.

Systems and methods of a robotic arm coupling for connecting a tool with a robotic arm are disclosed. In an embodiment, the robotic arm coupling includes: a mounting interface for mounting the robotic arm coupling on a robotic arm; a coupler interface on which differently actuated tools are releasably and interchangeably coupled; a fluid inlet port connected to an external fluid source to receive a pneumatic fluid; a plurality of interface fluid ports; at least one valve in fluid a communication with the fluid inlet port and settable to at least a first and a second operating state; and a suction device configured to apply a fluid suction pressure to an interface fluid port when a fluid pressure is provided to the suction device.

A system includes an inspection robot having an input sensor comprising a laser profiler and a plurality of wheels structured to engage a curved portion of an inspection surface, wherein the laser profiler is configured to provide laser profiler data of the inspection surface; a controller, comprising: a profiler data circuit structured to interpret the laser profiler data; determine a feature of interest is present at a location of the inspection surface in response to the laser profiler data; and wherein the feature of interest comprises a shape description of the inspection surface at the location of the feature of interest.

Provided is a wire body processing structure for a robot having a wrist, a base end of which is connected to a forearm in a rotatable manner about a first axis and a distal end of which has a plurality of working tools attached thereto. The wire body processing structure includes a first flexible conduit disposed along the first axis from the forearm to the distal end of the wrist and also includes a second flexible conduit disposed longitudinally within the first conduit. A first wire body for one of the working tools is extended longitudinally through the second conduit. A second wire body for another one of the working tools is extended longitudinally through a space between the first conduit and the second conduit.

A linear object handling structure of a robot includes a rotational drum supported above a base in a rotatable manner about a vertical axis line, a plurality of operation shafts supported by the rotational drum, and a hollow part near the vertical axis line in the rotational drum. A first linear object group including cables for driving the operation shafts has one end fixed to the base and the other end wired to the motors of the operation shafts supported by the rotational drum, and is disposed to penetrate through the hollow part. A second linear object group for a peripheral device supported by any one of the operation shafts is collectively covered by a flexible conduit pipe, disposed to penetrate through the hollow part, and detachably fixed to the base and the rotational drum.

Provided is a robot pivot shaft structure that includes a revolving drum rotatably supported at an upper portion of a base and that has a hollow portion, a drive motor rotating the revolving drum, and a speed reduction mechanism reducing the rotational speed of the drive motor. The speed reduction mechanism has a small gear fixed to a shaft of the drive motor, a large gear meshed with the small gear, an input hypoid gear fixed to the large gear, and an output hypoid gear meshed with the input hypoid gear. The output hypoid gear is fixed to the revolving drum and is disposed in the base. The input hypoid gear and the large gear are rotatably supported at the base. The drive motor is fixed to the base and disposed below the revolving drum, the position being horizontally shifted from vertically below the hollow portion.

A robot includes first and second arms to rotate and convey an object; a first rotary body to support the first arm and having a first fluid passage and at least one second fluid passage communicating with the first fluid passage; a base-end-side arm formed with an internal space and a hole part into which a part of the first rotary body is inserted; a second rotary body to support the second arm and having a third fluid passage communicating at one end thereof with the second fluid passage and communicating at the other end thereof with the internal space; a supplying device disposed in the internal space and connected to an upstream-end side of the first fluid passage, and to supply fluid to the first fluid passage; a first motor to rotate the first rotary body; and a second motor to rotate the second rotary body.

A method for assembling a humanoid type robot comprises two elements and an articulation with freedom in rotation linking the two elements about an axis, the articulation mounted and dismantled to join and separate the two elements. The robot comprises: a box with circular section fixed to a first element and extending along an axis parallel to the axis of rotation of the articulation, a cable having two ends, a first is connected to the first element and a second is connected to the second element. The cable is partly wound in the box about the axis of the box and extends out of the box to its second end. Between a separated and joined configuration of the two elements, an elasticity of the cable allows it to be wound in the box. The robot is assembled by connecting the cable at its two ends then mechanically mounting the articulation.

The invention relates to a joint arrangement having at least one driven axis, in particular for activating a movement of a component of a robot, wherein a first base element (15) receives a first rotary element (16), and the first rotary element (16) is rotatable about a first axis of rotation (14), the first rotary element (16) receives a second axis of rotation (18), separate from the first axis of rotation (14) and about which a second rotary element (22) is pivotably mounted on the first rotary element (16), the second rotary element (22) has a third axis of rotation (25) separate from the second axis of rotation (18) and about which a second base element (26) is rotatable with respect to the second rotary element (22), the second axis of rotation (18) has an axial offset (19) in relation to the first axis of rotation (14), and the second axis of rotation (18) is inclined with respect to the first axis of rotation (14), and the first and second axes of rotation (14, 18) have a point of intersection (29) which lies outside the joint arrangement (11).

Described herein is a multi-axial industrial robot, in particular of a SCARA type, where the base structure designed to enable installation of the robot on an external supporting structure, can be mounted according to two opposite orientations, where one orientation is upside down with respect to the other, while at the same time the operating head of the robot may instead maintain one and the same orientation.