A method of treating refractory-lined equipment includes accessing an interior of the refractory-lined equipment with an equipment repair apparatus, wherein the equipment repair apparatus includes a robotic arm and one or more end effectors coupled to an end of the robotic arm, inspecting refractory material that lines an inner wall of the refractory-lined equipment with a first end effector coupled to the end of the robotic arm, removing damaged refractory material from the inner wall with a second end effector coupled to the end of the robotic arm, removing one or more anchors from the inner wall with a third end effector coupled to the end of the robotic arm, and installing new refractory material on the inner wall with a fourth end effector coupled to the end of the robotic arm.

A drape includes a first drape portion configured to receive a manipulator arm of a surgical system and a pocket coupled to a distal portion of the first drape portion. The pocket is configured to receive a manipulator of the surgical system. The pocket includes a flexible membrane positionable between an output of the manipulator and an input of a surgical instrument mountable to the manipulator. In some embodiments, the flexible membrane is located at a distal end of the pocket. In some embodiments, the flexible membrane is configured to allow an actuating force to be transmitted from the output of the manipulator to the input of the surgical instrument. In some embodiments, the pocket provides a sterile barrier between the manipulator and the surgical instrument. In some embodiments, the drape further includes a rotatable seal configured to couple a proximal opening of the pocket to the first drape portion.

A robot includes a movable section capable of moving a discharging section including a discharge port capable of discharging an object. While the movable section is moving on the basis of a track including a curve, when the object is discharged to a target object from the discharge port, an absolute value of moving speed of the discharge port is larger than 0 mm/s.

An automated system for mounting a front-end module (FEM) including a first headlamp assembly and a second headlamp assembly assembled to both sides of a carrier body, and a FEM installation portion of a vehicle body, the automated system includes a FEM gripper mounted on an arm of a first handling robot, a vision sensor mounted on an arm of a second handling robot through a mounting bracket and configured to vision-photograph a first reference portion formed on the vehicle body and a first vehicle body coupling hole formed on the first headlamp assembly and vision-photograph a formed on the vehicle body second a second vehicle body coupling hole formed on reference portion and the second headlamp assembly, while the front-end module is loaded on the FEM installation portion by the FEM gripper, and a controller configured to analyze vision data obtained from the vision sensor and apply a position control signal to the first handling robot.

A system for handling a first component includes: a main-device and a module-device, the module-device having a pressing section arranged to form an outer surface of the module-device, the module-device configured to releasably receive the first component, such that a connection section of the first component is attachable to the pressing section of the module-device. The module-device is releasably connected to a second component, wherein the main-device includes a grabbing unit adapted for releasably connecting the module-device, such that the pressing section is arranged to form a first outer surface section of the main-device, and wherein the main-device includes a connector for connecting to a handling-unit for arranging the main-device at the second component, such that the connection section of the first component, if attached to the pressing section of the module-device, is at least indirectly attachable to a front surface of the second component.

An example robotic arm includes a base linkage and a first end effector connected to a second end of the base linkage through a first rotational joint. The robotic arm additionally includes a control arm. The control arm includes a first linkage and a second linkage, each having a first end and a second end. The first end of the first linkage is connected to the second end of the base linkage through a second rotational joint. The first end of the second linkage is connected to the second end of the first linkage through a third rotational joint. The control arm also includes a second end effector connected to the second end of the second linkage through a fourth rotational joint. The first, second, third, and fourth rotational joints are configured to rotate in or parallel to a first plane.

An example robotic device includes a mobile base and a base linkage. The base linkage has a first end and a second end where the first end is connected to the mobile base. The robotic device also includes a first end effector connected to the second end of the base linkage. The first end effector includes a shovel tool. The robotic device additionally includes an actuated control arm having a first end and a second end. The first end of the actuated control arm is connected to the second end of the base linkage. The robotic device further includes a second end effector connected to the second end of the actuated control arm. The second end effector includes a sweeping tool. The actuated control arm is configured to move the sweeping tool to engage with the shovel tool to sweep one or more objects onto the shovel tool.

A retainer apparatus configured to releasably retain an article, comprising a face plate member each having a front face, a plurality of vacuum cups and a plurality of support pins each extending distally relative to the front face, respectively, wherein the vacuum cups and the support pins are laterally spaced from one another, wherein the plurality of vacuum cups retain the article to the retainer apparatus in a presence of vacuum, wherein the plurality of support pins are extendable/retractable relative to the face plate member, wherein each of the support pins have a longitudinal axis, respectively, and are configured to contact the article to support the article against movement along the longitudinal axis and support the article against movement transverse to the longitudinal axis, and a locking mechanism configured to inhibit the support pins from being retractable and extendable when the locking mechanism is engaged.

A machine tool is provided which can execute various works while suppressing increase in cost or size. The machine tool includes a tool spindle device which is a movable member which can move with respect to a mounting surface of the machine tool, and one or more serial-manipulator-type robots attached on the tool spindle device, which can move with the tool spindle device, and which have two or more degrees of freedom, and the robot includes two or more end effectors provided at positions different from each other with one or more joints therebetween.

The present utility model relates to an autonomous interior painting robot for homes, commercial premises, hotels, etc. The robot is designed for painting and outlining while recognizing obstacles in the work area and aimed at reducing the efforts and time needed to carry out these operations. It is applicable in the field of interior design and the completion of small conditioning works. The autonomous painting robot comprises a mobile base (1) equipped with a paint tank and a pump or compressor, characterized in that the base (1) comprises a series of detectors configured to locate the base (1) and to detect obstacles, a substantially vertical lifting column (4), at the end of which a robot arm (5) is articulated and topped with a head (6) that carries a paint gun (7) connected to the pump, one or more cameras (9), and a proximity sensor (10).