Thus, there is disclosed an autonomous robotic construction system comprising at least one frame comprising at least one substantially horizontal track and at least one set of substantially vertical track; at least one nozzle; at least one movable device coupled to the frame and configured to move said nozzle around said frame; at least one pump configured to pump building materials through said at least one nozzle; and at least one computer system comprising at least one microprocessor configured to control said at least one nozzle, said at least one movable device and said at least one pump to control deposition of any building materials on a site.

Processe and system for preparing a vehicle surface (e.g., an aircraft fuselage) for painting include a preparation booth (100) which is sized and configured to house the vehicle (F). At least one robotic assembly (200a, 200b) is reciprocally movable within the preparation booth (100) relative to a longitudinal axis of the vehicle (F), and is provided with a robotic hand (230) having at least one abrasive disc (242a) attached to an attachment pad (242) of the robotic hand (230), and at least one nozzle (252a, 252b, 252c) for discharging a stream of rinse fluid. Operation of the at least one robotic assembly (230) will cause the at least one abrasive disc (242a) of the robot hand (230) to abrade the surface of the vehicle (F). The robotic hand (230) may thereafter be maneuvered so that the at least one nozzle (252a, 252b, 252c) is directed toward the abraded vehicle surface (F). A stream of rinse fluid may then be discharged through the at least one nozzle (252a, 252b, 252c) and towards the abraded surface of the vehicle (F) so as to rinse the abraded surface of particulate matter.

A combination link actuation device has two link actuation devices combined with each other. Each link actuation device is provided so as to connect a distal end side link hub to a proximal end side link hub such that an orientation of the distal end side link hub is changed relative to the proximal end side link hub through three link mechanisms aligned in a circumferential direction. An orientation controlling actuator is provided in two or more link mechanisms among the three link mechanisms to optionally change an orientation of the distal end side link hub relative to the proximal end side link hub. At least one circumferential separation angle among separation angles of the three link mechanisms is greater than 120. The two link actuation devices are disposed such that portions, of the link mechanisms, where the separation angle is greater than 120 oppose each other.

A combination link actuation device has two link actuation devices combined with each other. Each link actuation device is provided so as to connect a distal end side link hub to a proximal end side link hub such that an orientation of the distal end side link hub is changed relative to the proximal end side link hub through three link mechanisms aligned in a circumferential direction. An orientation controlling actuator is provided in two or more link mechanisms among the three link mechanisms to optionally change an orientation of the distal end side link hub relative to the proximal end side link hub. At least one circumferential separation angle among separation angles of the three link mechanisms is greater than 120. The two link actuation devices are disposed such that portions, of the link mechanisms, where the separation angle is greater than 120 oppose each other.

A working device has a configuration with seven degrees of freedom, and is configured to perform work using an end effector. The working device includes: a linear motion unit having three degrees of freedom; a rotary unit having three degrees of freedom; and a rotary drive mechanism having one degree of freedom. The rotary drive mechanism is configured to rotate the rotary unit relative to the linear motion unit. The linear motion unit is mounted on a mount such that a base portion thereof is fixed to the mount. The rotary drive mechanism is mounted on an output portion of the linear motion unit. The rotary unit is mounted on an output portion of the rotary drive mechanism. The end effector is mounted on an output portion of the rotary unit.

Systems, devices, and methods are directed to automated preparation of food or consumable items, such as for preparation of fried foods. An example cooking apparatus may include processing devices for the consumable items. In some examples, a robot arm is provided that extends from a moveable base. Locators may define a relative position of the moveable base relative to processing device(s) of the cooking apparatus, such that the robot arm is configured to determine robot arm movements to move the consumable items to and from the processing device(s). In some examples, one or more zones may be used to detect movement near a robot arm, with one or more restrictions being placed upon robot arm and/or base movement in response. In some examples, a cooking apparatus provides automated transport of food ingredients for preparation of food or other consumable items.

Systems, devices, and methods are directed to automated preparation of food or consumable items, such as for preparation of fried foods. An example cooking apparatus may include processing devices for the consumable items. In some examples, a robot arm is provided that extends from a moveable base. Locators may define a relative position of the moveable base relative to processing device(s) of the cooking apparatus, such that the robot arm is configured to determine robot arm movements to move the consumable items to and from the processing device(s). In some examples, one or more zones may be used to detect movement near a robot arm, with one or more restrictions being placed upon robot arm and/or base movement in response. In some examples, a cooking apparatus provides automated transport of food ingredients for preparation of food or other consumable items.

A team of robots may fabricate a tubular structure. Each robot may fabricate a tube by winding resin-covered fiber around an inflated, cylindrical mandrel of the robot. The resin may cure, resulting in a hardened tube segment The robot may extend the tube by fabricating additional segments of the tube, one segment at a time. After a first segment cures, the mandrel may deflate, then the robot may move up inside the tube, then the mandrel may inflate, and the robot may begin fabricating another tube segment. After completing a tube segment, the robot may tilt relative to that segment, before starting the next segment. By doing so, the robot may cause the tube to be curved. A computer may guide the team of robots during fabrication of the tubes, by executing a flocking algorithm. The algorithm may prevent collisions with already fabricated tube segments.

A team of robots may fabricate a tubular structure. Each robot may fabricate a tube by winding resin-covered fiber around an inflated, cylindrical mandrel of the robot. The resin may cure, resulting in a hardened tube segment The robot may extend the tube by fabricating additional segments of the tube, one segment at a time. After a first segment cures, the mandrel may deflate, then the robot may move up inside the tube, then the mandrel may inflate, and the robot may begin fabricating another tube segment. After completing a tube segment, the robot may tilt relative to that segment, before starting the next segment. By doing so, the robot may cause the tube to be curved. A computer may guide the team of robots during fabrication of the tubes, by executing a flocking algorithm. The algorithm may prevent collisions with already fabricated tube segments.

A machine for the machining of railway wagons comprising: a holding structure having a first upright and a second upright that extend along respective first direction and second direction substantially parallel and adapted to be arranged on the opposite side with respect to a wagon to be machined; sliding means of the structure along a main direction; machining means of the wagon comprising at least a first anthropomorphic robot associated sliding with the first upright, and at least a second anthropomorphic robot associated sliding with the second upright.