An automated assembly apparatus, system and method of use thereof, characterized by comprising an assembly robot having a plurality of hands, the plurality of hands being movable in an X-axis direction and a Y-axis direction by an X-axis moving unit and a Y-axis moving unit, and a plurality of workbenches which are provided with Z-axis moving unit and which are movable in a Z-axis direction by the Z-axis moving unit. A work area is independently provided for the plurality of workbenches, a width of a predetermined work area among the work areas is larger than clearance widths of the plurality of hands, widths of the work areas other than the predetermined work area are smaller than the clearance widths of at least some of the plurality of hands, and the hand which performs a job on the predetermined work area is disposed at a lowermost level in the Z-axis direction.

Provided are a measurement system, a measurement device, a measurement method, and a measurement program. 3D data is registered to 3D data based on the displacements of joints of a robot at a point in time when a 3D sensor measures 3D data of a measurement object at a specific measurement point while the robot is stopped, and the displacements of the joints of the robot at a point in time when the 3D sensor measures 3D data of the measurement object at a measurement point other than the specific measurement point while that robot is in motion. The 3D data is further registered to the 3D data such that a registration error between the 3D data and the 3D data is less than a threshold value. Similarly, each of 3D data is registered to the 3D data.

A system is for automatic storage, picking, and packing of items. The system has: an arrangement of shelves for supporting storage boxes; a movable robotic arm, the robotic arm being configured for reaching into and picking an item from a storage box, and for grabbing and moving a storage box; and a camera and control unit, the arrangement of shelves comprises a first sub arrangement of shelves with a first vertical distance between the shelves, and a second sub arrangement of shelves with a second vertical distance between the shelves. The first vertical distance is chosen to allow the robotic arm to reach into and pick an item from said storage boxes. The second vertical distance is chosen so that each storage box must be moved out before the robotic arm can pick an item from the storage box.

A catching mechanism includes an end effector and a return mechanism coupled to the end effector. The catching mechanism has a defined field of motion that permits the end effector to move in at least one dimension. The return mechanism is configured to return the catching mechanism to a predetermined starting position in which the catching mechanism is not being moved by a force away from the predetermined starting position.

A construction robot for a ceiling is provided. The construction robot includes: a robot base having an upper plate; a targeting unit on the upper plate, wherein the targeting unit moves a robotic arm assembly combined with the targeting unit, and wherein the robotic arm assembly includes: a first robotic arm where a drill is mounted, wherein a first elevating unit of the first robotic arm is elevated or lowered according to information on the ceiling, a second robotic arm where an anchor bolt inserting equipment is mounted, wherein a second elevating unit of the second robotic arm is elevated or lowered according to the information, and a third robotic arm where an impact wrench is mounted, wherein a third elevating unit of the third robotic arm is elevated or lowered likewise; and a loading unit on the upper plate or the targeting unit for providing anchor bolt assemblies.

A collapsible, versatile, multiple axis Cartesian robot system is aimed directly at solving the issue of the inverse relationship of robot portability to workspace volume. The collapsible, multiple axis Cartesian robot, minimizes the collapsed size of the robot while maximizing the workspace volume in the use of multiple, alternating linear and rotary actuators.

Broadly speaking, embodiments of the present techniques provide a configurable robotic processing system in which the sequence of operations performed by the system may vary (in contrast to a conveyor-based system) and may be dynamically-scheduled.

The present invention relates to an automatic cooking system with a cooking tool, further comprising an ingredient storage and feeding apparatus and an ingredient conveying and dispensing apparatus; wherein, the ingredient storage and feeding apparatus comprises a plurality of storage units with inlets and outlets, a plurality of ingredient boxes are provided between the inlets and outlets; the ingredient conveying and dispensing apparatus is provided with a work position, which is located on one side of the cooking tool; and the ingredient conveying and dispensing apparatus transports the ingredient boxes to the work position and then rotates so that the ingredient boxes are turned over to pour the required ingredients into the cooking tool. The present invention provides an innovative automatic cooking system, which realizes the integration of the classified storage and transportation of ingredients, and a single ingredient is used as a storage unit, and ingredients can be automatically transported from different storage units to the pot according to the order of adding the ingredients to the dishes, so that one cooking machine can cook more different dishes, thereby avoiding the change of the taste due to pre-mixing of multiple ingredients, and reducing the labor demand.

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.

A coordinate calibration method of a manipulator is provided and includes steps of: (a) controlling the manipulator to move in accordance with a movement command, and acquiring the reference anchor points reached by the manipulator; (b) acquiring a rotation matrix and a translation vector according to the reference anchor points, and acquiring a reference coordinate system accordingly; (c) when the manipulator returning to the work space after temporarily leaving, controlling the manipulator to move in accordance with the movement command, and acquiring the actual anchor points reached by the manipulator; (d) acquiring a rotation matrix and a translation vector according to the actual anchor points, acquiring a corresponding actual coordinate system accordingly, and acquiring a coordinate compensation information by comparing the rotation matrixes and the translation vectors; and (e) adjusting the manipulator according to the coordinate compensation information, and maintaining the manipulator to operate in the reference coordinate system.