The disclosed robot enables the efficient transportation of objects scattered over a wide area. The disclosed robot may include: a main body having one or more support; a moving mechanism for moving the main body; and a manipulator installed on one support, among the one or more support, thereby having the one support as a rotating shaft so as to be rotatable by 360° or higher

A robotic system comprising a mobile chassis, a conveyor oriented substantially parallel to a longitudinal axis of the chassis, one or more robotic arms disposed adjacent to the conveyor, and one or more cameras positioned to view at least a portion of a top surface of the conveyor is disclosed. The system uses the mobile chassis, the conveyor, and the robotic arms to load items into a truck or other container, including by using image data generated by the one or more cameras to assess a state of items on the top surface of the conveyor; determine based at least in part on the image data that an additional item is to be added to the top surface of the conveyor; and operate a robotically controlled structure to cause an item to be added to the top surface of the conveyor.

A door opening/closing robot includes: a base provided at a position different from a conveyance line on which a vehicle body is conveyed; a first arm attached to the base to rotate around a first axis and extending away from the first axis; a second arm attached to the first arm to rotate around a second axis and extending away from the second axis; a third arm attached to the second arm to rotate around a third axis and extending away from the third axis; and a fourth arm attached to the third arm to extend vertically and configured to vertically move a tool for holding a door of the vehicle body. At least a portion of a connection area including a distal end of the second arm and a proximal end of the third arm is positioned at a same height as at least a portion of the base.

A painting system includes: a conveying apparatus that conveys a vehicle body having a door in a painting area; an operation robot that includes a base fixed in the painting area, a holding tool capable of holding the door, and a horizontal articulated arm that moves the holding tool, and opens the door of the vehicle body that is being conveyed by the conveying apparatus; and a painting robot that paints an inside of the vehicle body in a state where the door is opened by the operation robot. In the vertical direction, at least a portion of the horizontal articulated arm is disposed at a position lower than a height of a lower end of the door where the height of the lower end of the door is maintained by the conveying apparatus.

An apparatus includes a plurality of connector track elements, each extending substantially perpendicularly from a coupling plane, wherein a particular connector track element of the plurality of connector track elements includes a distribution of at least two magnets adjacent unattached end thereof, a polarity of the magnets on the particular connector track element being selected to provide magnetic repulsion as to at least one adjacent connector track element.

Embodiments of the present disclosure are directed to methods, computer program products, and computer systems of a robotic apparatus with robotic instructions replicating a food preparation recipe. In one embodiment, a robotic control platform, comprises one or more sensors; a mechanical robotic structure including one or more end effectors, and one or more robotic arms; an electronic library database of minimanipulations; a robotic planning module configured for real-time planning and adjustment based at least in part on the sensor data received from the one or more sensors in an electronic multi-stage process file, the electronic multi-stage process recipe file including a sequence of minimanipulations and associated timing data; a robotic interpreter module configured for reading the minimanipulation steps from the minimanipulation library and converting to a machine code; and a robotic execution module configured for executing the minimanipulation steps by the robotic platform to accomplish a functional result.

The objective of the present invention is to provide a vehicle charging robot device, of which a robot for charging a vehicle is stored in a case, so as to protect the robot from external conditions including rain, wind, temperature, humidity, and the like, and prevent malfunction or failure, or damage to the robot.

The present invention discloses an automatic high-shear low-pressure force-controlled grinding device for a complicated curved surface and a machining method thereof, which belong to the field of complicated curved surface grinding technologies of difficult-to-machine materials. The device comprises a base, columns, an industrial robot, an electrical spindle, a force-controlled floating work holder, a workpiece chuck, a grinder plate, a six-dimensional force sensor, a rotary table, a triaxial precision displacement table, a safeguard hood, a safety door, and a pedestal. The grinder plate comprises a grinder plate substrate, a press plate, a lining plate, and an abrasive layer. Each module is effectively communicated, and a control system collects and processes signals as well as transmits commands to achieve automatic force-controlled grinding of the complicated curved surface. The abrasive layer of the grinder plate generates the shear thickening effect; so, the material can be removed in a high-shear low-pressure grinding manner.

A transport vehicle (2) is provided with: a support region (22) where a container (W) is supported; a container transfer apparatus (24) that inserts/takes a container (W) into/out of a container shelf; a recognition apparatus (27) that recognizes at least one of an article stored in a container (W) in a first state in which the container (W) is supported in the support region (22) and an article stored in a container (W) in a second state in which the container (W) is supported by the container transfer apparatus (24); and an article transfer apparatus (26) that transfers an article recognized by the recognition apparatus (27) between a container (W) in the first state and a container (W) in the second state.

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.