The embodiments of this application provide a goods box take-out mechanism, device, and method, and a transport robot, belong to the field of transport robot technologies, and are intended to resolve the problem of wasting part of storage space of the warehouse when the current transport robots are used to carry goods boxes. The goods box take-out device includes a take-out assembly that is connected to a front surface of a to-be-transferred goods box and that can take out the goods box from a warehousing shelving unit. Since the take-out assembly is connected to the front surface of the to-be-transferred goods box, there is no need to reserve space below, above, or on left and right sides of the goods box for insertion and movement of the take-out assembly. Therefore, the storage space of the warehouse is fully utilized, and the storage density of the warehouse is improved.

Various gripped objects having different sizes, weights, centers of gravity, and the like are continuously and stably moved at a high speed. A control device includes: a state information generation unit that generates and updates state information on a robot and a gripped object; and a control information generation unit that generates, based on the state information and a base trajectory generated in advance on which the robot is configured to move the gripped object from a start point to an end point, control information for controlling the robot.

A registration system for robot-oriented augmented reality teaching system, comprising: a physical robot unit, a registration unit, a virtual robot generation unit and a computer; the physical robot unit comprising a physical robot, a physical robot controller and a robot point-to-point intermittent movement control program; the physical robot provided thereon with a physical robot base coordinate system; the physical robot controller connected with the physical robot and the computer respectively; the robot point-to-point intermittent movement control program installed in the computer; the registration unit comprising a registration marker, a camera and a conversion calculation unit; the registration marker arranged on the physical robot body; the camera fixed in a physical environment except the physical robot; the camera connected with the computer, and the conversion calculation unit arranged in the computer; the virtual robot generation unit arranged in the computer and used for generating a virtual robot model.

Provided is an alimentary-product assembling and dispensing device comprising: a plurality of alimentary-ingredient dispensers positioned to dispense respective ingredients in a plurality of different locations of a robotic work environment; a robot configured to receive an open-top vessel from an open-top-vessel dispenser and move the open-top vessel to the different locations to receive different ingredients from the plurality of alimentary-ingredient dispensers, wherein the robot comprises four or fewer degrees of freedom; and a vending aperture through which consumers retrieve vended alimentary products assembled by the robot from ingredients dispensed from the plurality of alimentary-ingredient dispensers.

A gripping device includes: a gripping portion configured to be displaced between a closed position in which a workpiece is grasped and an open position in which the workpiece is released; a holding portion configured to hold the gripping portion; a shaft portion that extends from the holding portion; a support portion configured to support the shaft portion such that the gripping portion faces the workpiece; a driving unit configured to displace the gripping portion between the closed position and the open position; and a moving mechanism configured to move the support portion in an axial direction of the shaft portion, in which the support portion is configured to support the shaft portion such that when a load acts on the shaft portion in the axial direction, the shaft portion is slidable relative to the support portion.

A dialyzer housing manufacturing system includes a molding device configured to mold a dialyzer housing, and a tool coupled to a robotic arm and configured to retrieve the dialyzer housing from the molding device after the dialyzer housing is molded. The tool includes a frame, a first suction cup connected to a first portion of the frame, and a second suction cup connected to a second portion of the frame, the second suction cup being oriented about 70 degrees to about 110 degrees relative to the first suction cup.

In variants, a method for robot control can include: receiving sensor data of a scene, modeling the physical objects within the scene, determining a set of potential grasp configurations for grasping a physical object within the scene, determining a reach behavior based on the potential grasp configuration, determining a trajectory for the reach behavior, and grasping the object using the trajectory.

A spraying robot, a control method, and a computer readable storage medium are disclosed. The spraying robot includes a frame body, a first lifting mechanism, a lifting motor, and a spraying gun; a lifting channel is provided inside the frame body; the first lifting mechanism is provided inside the lifting channel; a first portion of the first lifting mechanism is fixedly connected to the frame body; the lifting motor is connected to the first lifting mechanism in a transmission manner, so that under the driving of the lifting motor, the first lifting mechanism moves in the lifting channel; the spraying gun is provided in a second portion of the first lifting mechanism; wherein the first portion and the second portion are provided on both sides of the first lifting mechanism.

Systems, devices, articles, and methods, described in greater detail herein, including robotic systems which include at least one rangefinder, at least one manipulator, and at least one processor in communication with the at least one rangefinder, and methods of operation of the same. The at least one processor obtains rangefinder pose information which represents, at least, the at least one manipulator in a plurality of poses. The at least one processor obtains manipulator pose information, optimizes a model of mismatch between the rangefinder pose information and the manipulator pose information, wherein the model of mismatch includes a plurality of parameters, and updates at least one processor readable storage device with the plurality of parameters based at least in part on the optimization.

A gripping mechanism includes a frame and two or more spheres. The frame houses the two or more spheres. At least two spheres of the two or more spheres grip an object. Preferably, the frame includes two or more side plates. The number of the two or more side plates is the same as the number of the two or more spheres. Each of the two or more side plates is inclined toward a center axis of the frame. Each of the two or more spheres is in contact with at least one side plate of the two or more side plates.