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.

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.

An indexing apparatus includes a fixture tool, movable relative to an operation cell and an indexing feature, fixed relative to the fixture tool. The indexing apparatus also includes a gripper, configured to engage the indexing feature. The indexing apparatus further includes a controller, in communication with the gripper. The controller is configured to locate the fixture tool relative to the operation cell from a gripper location of the gripper, engaged with the indexing feature.

The present disclosure is directed to methods, computer program products, and computer systems of a robotic kitchen hub for calibrations of multi-functional robotic platforms for commercial and residential environments with artificial intelligence and machine learning. The multi-functional robotic platform includes a robotic kitchen for calibration with either a joint state trajectory or in a coordinate system like a cartesian coordinate for mass installation of robotic kitchens. Calibration verifications and minimanipulation library adaptation and adjustment of any serial model or different models provide scalability in the mass manufacturing of a robotic kitchen system. A robotic kitchen with multi-mode provides a robot mode, a collaboration mode and a user mode which a particular food dish can be prepared by the robot, a collaboration on sharing tasks between the robot and a user, or the robot serves as an aid for the user to prepare a food dish.

A system for automatic wheel alignment adjustment of a vehicle in an inspection line is provided. The system is disposed under a mounting table mounted with a vehicle and includes a front wheel adjustment apparatus disposed in correspondence with a front wheel of the vehicle and configured to adjust alignment of the front wheel by adjusting a tie-rod and a lock-nut employed in a linkage structure of the front wheel, a rear wheel moving apparatus disposed in correspondence with a rear wheel of the vehicle and slidable in a vehicle width direction, and a rear wheel adjustment apparatus disposed in correspondence with the rear wheel of the vehicle, connectable to the rear wheel moving apparatus, and configured to adjust alignment of the rear wheel by adjusting a cam-bolt and a cam-nut employed in a linkage structure of the rear wheel.

The present disclosure provides a method and system by which a precise amount of a viscous fluid sealing compound can be dispensed at required locations through computer vision-based observation of the fluid deposited, its rate and amount of deposition and location; and that the dispensed fluid may be accurately shaped through robotic or other special purpose mechanism motion. The invention enables instant quality inspection of the dispensing process in terms of the locations, amounts and shapes of newly created seals.

The present disclosure provides a method and system by which a precise amount of a viscous fluid sealing compound can be dispensed at required locations through computer vision-based observation of the fluid deposited, its rate and amount of deposition and location; and that the dispensed fluid may be accurately shaped through robotic or other special purpose mechanism motion. The invention enables instant quality inspection of the dispensing process in terms of the locations, amounts and shapes of newly created seals.

An additive manufacturing device includes a table that supports an additive manufactured object, and a manufacturing unit including a first nozzle that is movable with respect to the table and a second nozzle that is movable with respect to the table and also movable with respect to the first nozzle. The manufacturing unit discharges powder from at least one of the first nozzle and the second nozzle, and emits an energy beam from at least one of the first nozzle and the second nozzle to melt or sinter the powder to additively manufacture the object supported on the table.

The present invention provides a treatment method for treating a surface for treatment by means of an automaton (1) comprising: a base (2) configured to move over ground; a platform (6) mounted on the base and configured to move, at least in part, perpendicularly to the base; and treatment means (10) mounted on the platform and including a movable end (12) configured to treat a given area; the method comprising: a) subdividing the surface for treatment into subdivisions of area less than or equal to the given area; b) treating the surface of each subdivision by controlling movements of the treatment means (10); and c) changing subdivision by moving the platform (6) and/or by moving the base (2) over the ground. The invention also provides an automaton for performing the above method.

The present invention provides a treatment method for treating a surface for treatment by means of an automaton (1) comprising: a base (2) configured to move over ground; a platform (6) mounted on the base and configured to move, at least in part, perpendicularly to the base; and treatment means (10) mounted on the platform and including a movable end (12) configured to treat a given area; the method comprising: a) subdividing the surface for treatment into subdivisions of area less than or equal to the given area; b) treating the surface of each subdivision by controlling movements of the treatment means (10); and c) changing subdivision by moving the platform (6) and/or by moving the base (2) over the ground. The invention also provides an automaton for performing the above method.