A cable-mounted object, such as a camera, is movable using one or more robotic cable mounts. The robotic cable mounts have a head which support a first portion of the cable. The head is movable in three-dimensional space, such as linearly along three orthogonal axis (or combinations thereof). Changes in the position of the head of the robotic mount change the position of the cable, thus changing the position of the cable-mounted object. In one embodiment, two ends of cable may be connected to first and second robotic cable mounts, or an object might be mounted to multiple cables, each of which is connected to a different robotic mount.

This solution is for washing and cleaning the external walls of a building, and adopts a lightweight six axis robotic arm mounted on a mini-gondola hoisted by a pulley system with the controlling motor located within the mini-gondola, while another set of motor located on the pulley system at the roof-top end drives the mini-gondola to traverse laterally on a set of twin-rails on the roof-top of the building. Four vacuum suction cups mounted on the minigondola through linear actuator are used to secure the mini-gondola to the wall. Each linear actuator has three ultrasonic distance sensors that measure and manage the distance between the mini-gondola and the wall to be cleaned. Once the gondola is in position, the robotic arm will be activated to start the cleaning process.

A method and apparatus for installing a fastener in a surface of a structure. A crawler robot may comprise a first movement system and a second movement system. The first movement system may be configured to move the crawler robot and a track system along the surface. The second movement system may be configured to move the crawler robot along the track system on the surface.

A method and apparatus for installing a fastener in a surface of a structure. A crawler robot may comprise a first movement system and a second movement system. The first movement system may be configured to move the crawler robot and a track system along the surface. The second movement system may be configured to move the crawler robot along the track system on the surface.

A workpiece information recognition system includes a workpiece placing tool (20) capable of placing a workpiece, a reference block (31) detachably provided on workpiece placing tool (20), an information detector configured to detect information about reference block (31), and a control device configured to receive the information of reference block (31) from the information detector. The control device includes a storage configured to store data on a relationship between the information about reference block (31) and information about the workpiece and a controller configured to recognize the information about the workpiece placed on workpiece placing tool (20) by checking the information about reference block (31) detected by the information detector with the data stored in the storage. With this configuration, the workpiece information recognition system capable of easily cope with a change in a type of the workpiece is provided.

A workpiece information recognition system includes a workpiece placing tool (20) capable of placing a workpiece, a reference block (31) detachably provided on workpiece placing tool (20), an information detector configured to detect information about reference block (31), and a control device configured to receive the information of reference block (31) from the information detector. The control device includes a storage configured to store data on a relationship between the information about reference block (31) and information about the workpiece and a controller configured to recognize the information about the workpiece placed on workpiece placing tool (20) by checking the information about reference block (31) detected by the information detector with the data stored in the storage. With this configuration, the workpiece information recognition system capable of easily cope with a change in a type of the workpiece is provided.

The present invention provides for a wall mountable system for automated drawing of an image upon a wall which includes a horizontal mounting track for mounting on a wall, a robot having a y-track rigidly mounted it where the robot and the mounted y-track travel along the horizontal track. An end effector, which includes a pen holding mechanism holding a pen, is in electrical communication with the robot and travels along the y-track of the robot. The present invention provides a system and device that can attach to a wall or vertical surface in a damage-free manner and draw fast any complexity or style image of custom size in both the horizontal (X) and vertical (Y) directions, that is easy to remove and transport and require small floor space to operate.

A drive system comprises a support structure for a guideway defining an X-Y array of tracks (22, 24) so that one or more carriages (10) can run along the tracks to any desired position. The carriages are intended to either carry a single robotic device or work together to carry a larger robotic device. The track is made up of an array of pegs (14) supported from a ceiling plane made up of an array of tiles (8) which provide for electrical connections to the carriages. Each peg carries a spool mounted between two horizontal flanges that cooperates with a rectangular sprocket connected to a base of a cuboid carriage housing. The carriages are driven by internal electric motors that are arranged to drive two pairs of omniwheels (90) on the ceiling plane while the carriage is supported and guided by means of its sprocket.

An embodiment of the present disclosure provides a manipulator for a finishing work, including: a base; an arm comprising a plurality of links, a plurality of joints connecting the plurality of links, and a plurality of actuators generating rotation of at least some of the plurality of joints; and a processor determining a driving torque of each of the plurality of actuators considering a self-weight effect of the manipulator and controlling the plurality of actuators based on the determined driving torque.

A frame body may be parallel to and proximate with an external surface of a structure and extend substantially horizontally from a first side to a second side. A connecting portion may be provided to be attached to a cable to provide for vertical movement of the frame body. A robotic arm may be affixed proximate to a bottom of the frame body and be able to move horizontally during treatment of the external surface. Moreover, the robotic arm may extend to an end proximate with the external surface, and a cleaning portion may be attached to the robotic arm near the end proximate with the external surface. The robotic arm may rotate, vertically moving the cleaning portion during treatment of the external surface. In addition, the cleaning portion may be separately rotated to remain substantially parallel to and proximate with the external surface during rotation of the robotic arm.