Technologies are shown for self-elevating platform carts that can transport a load from an initial surface to a destination surface that can be at a higher level, lower level or same level across a horizontal distance and/or barrier. One example extends a front height support to contact the destination surface and extends a rear height support control to contact the initial surface. A main lift is retracted and the system moved forward until main wheels on the main lift contact the destination surface. The main lift is extended and the extensible support beams and height supports are retracted. Another example traverses intermediate surfaces using a vertical stabilizer to stabilize the main lift on surfaces at different levels. The main lift can be the only power lift for the cart.

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.

The present invention provides an automated system for spraying a wall of a building. The automated system comprises a boom lift having a linear track disposed thereon, wherein the linear track is disposed horizontally with respect to the height of the building; a robotic mechanism slidably mounted on the linear track of the boom lift, the robotic mechanism further having an end effector adapted for supporting a spray nozzle thereon; a visual monitoring system configured to scan structural characteristics and profiles of the wall; a computing device disposed in communication with the visual monitoring system and the robotic mechanism, wherein the computing device is configured to receive the scanned structural characteristics and profile of the wall from the visual monitoring system; and controller communicably coupled to the computing device, the controller configured to independently control operation of respective ones of the robotic mechanism, and the spray nozzle according to the scanned structural characteristics and profiles of the wall.

The present invention provides an automated system for spraying a wall of a building. The automated system comprises a boom lift having a linear track disposed thereon, wherein the linear track is disposed horizontally with respect to the height of the building; a robotic mechanism slidably mounted on the linear track of the boom lift, the robotic mechanism further having an end effector adapted for supporting a spray nozzle thereon; a visual monitoring system configured to scan structural characteristics and profiles of the wall; a computing device disposed in communication with the visual monitoring system and the robotic mechanism, wherein the computing device is configured to receive the scanned structural characteristics and profile of the wall from the visual monitoring system; and controller communicably coupled to the computing device, the controller configured to independently control operation of respective ones of the robotic mechanism, and the spray nozzle according to the scanned structural characteristics and profiles of the wall.

State of art techniques utilize active systems for stronger suction in surface crawlers while the passive approaches have limitation in providing consistent grip while moving across curved surfaces or dents. Embodiments herein provide an autonomous surface crawling robot for crawling over surfaces using electro-mechanical assembly for creating strong suction force and enabling the robot to smoothly crawl over flat surfaces, horizontal/vertical/inclined surfaces, curved surfaces, and surfaces with dents. Battery powered motors are used for only mobilization, while mechanical assembly generates suction to provide consistent grip across different type of surfaces. A dual flexible cam profile assembly including a cam profile and a guide rail generates required suction and addresses the technical challenge of maintaining suction across varying surfaces without using external power for suction generation. The dual flexible cam profile provides a robust, less prone to error or slippage type passive crawler mechanism, with consistent grip across uneven the surface.

A robotic system and method having a movable and adjustable platform with a plurality of vertically-adjustable legs depending from the platform, the legs having wheels for moving and turning, and a plurality of sensors incorporated with a 3-D model program and movement algorithm that utilizes the information and data collected by the sensors for directing the motors and controls units to move and adjust the robotic system and the system device provided herein.

The disclosure discloses a single-leg robot mechanism for jumping on a wall and a control method. The mechanism includes a robot leg. A plurality of rotors is fixedly connected to a fuselage of the robot leg and is distributed in a mirror image arrangement with respect to the fuselage, and operating surfaces of the plurality of rotors are parallel to each other.

The disclosure discloses a single-leg robot mechanism for jumping on a wall and a control method. The mechanism includes a robot leg. A plurality of rotors is fixedly connected to a fuselage of the robot leg and is distributed in a mirror image arrangement with respect to the fuselage, and operating surfaces of the plurality of rotors are parallel to each other.

Various embodiments generally relate to robotics and more specifically to tank seal inspections. In some embodiments, the robotic inspection device comprising a power supply, a body, a drive system, a camera, a navigational system, and/or one or more sensors. The drive system may include one or more surface engaging drivers to propel the robotic inspection device along a surface of a tank. The camera can be housed within the body to capture images and/or video of a seal. The navigational system can compute a route (or receive commands that route) and send commands to the drive system to navigate the robotic inspection device along the surface of the tank allowing the camera to capture the images or video of the seal. Some embodiments may use an artificial intelligence or machine learning engine to review the images or video of the seal and identify potential problems.

Various embodiments generally relate to robotics and more specifically to tank seal inspections. In some embodiments, the robotic inspection device comprising a power supply, a body, a drive system, a camera, a navigational system, and/or one or more sensors. The drive system may include one or more surface engaging drivers to propel the robotic inspection device along a surface of a tank. The camera can be housed within the body to capture images and/or video of a seal. The navigational system can compute a route (or receive commands that route) and send commands to the drive system to navigate the robotic inspection device along the surface of the tank allowing the camera to capture the images or video of the seal. Some embodiments may use an artificial intelligence or machine learning engine to review the images or video of the seal and identify potential problems.