Disclosed is a fruit picking method based on a visual servo control robot, comprising: placing a throwing apparatus and a fixed photosensitive device at a first position to obtain a fixed photosensitive image; generating a first throwing path, a second throwing path, and a third throwing path; arranging recovery apparatuses; performing simultaneous rotational throwing processing to throw a first wireless photosensitive device, a second wireless photosensitive device, and a third wireless photosensitive device; receiving a first photosensitive image sequence and a second photosensitive image sequence of the first wireless photosensitive device and the second wireless photosensitive device; receiving a third photosensitive image sequence of the third wireless photosensitive device; generating a spatial position of a fruit on a to-be-picked fruit tree; and performing fruit picking processing using the visual servo control robot according to the spatial position of the fruit.

An example system includes a vacuum generating device, a robotic arm, and a harvesting device coupled to the robotic arm. The harvesting device includes an end-effector having an inlet; a vacuum tube coupled to the inlet of the end-effector and to the vacuum generating device, where the vacuum generating device is configured to generate a vacuum environment in the vacuum tube; an outlet mechanism coupled to the vacuum tube; and a deceleration structure configured to decelerate fruit that has traversed at least a portion of the vacuum environment.

An example system includes a vacuum generating device, a robotic arm, and a harvesting device coupled to the robotic arm. The harvesting device includes an end-effector having an inlet; a vacuum tube coupled to the inlet of the end-effector and to the vacuum generating device, where the vacuum generating device is configured to generate a vacuum environment in the vacuum tube; an outlet mechanism coupled to the vacuum tube; and a deceleration structure configured to decelerate fruit that has traversed at least a portion of the vacuum environment.

A robotic harvesting system includes a base, a gantry system, a robotic arm, and a control system. The base is configured to move in a direction of travel. The gantry system is coupled to the base. The gantry includes a linear transport that is configured to move along the base in substantially a same direction or opposite direction as the direction of travel. The linear transport is coupled to a rod that extends downwards from a top portion of the gantry system. A robotic arm is mounted to the rod at a first joint. A control system is configured to send one or more corresponding commands that cause the linear transport, the rod, and/or the robotic arm to move.

A robotic harvesting system includes a base, a gantry system, a robotic arm, and a control system. The base is configured to move in a direction of travel. The gantry system is coupled to the base. The gantry includes a linear transport that is configured to move along the base in substantially a same direction or opposite direction as the direction of travel. The linear transport is coupled to a rod that extends downwards from a top portion of the gantry system. A robotic arm is mounted to the rod at a first joint. A control system is configured to send one or more corresponding commands that cause the linear transport, the rod, and/or the robotic arm to move.

A physically-impaired-assisting multi-function sail comprises: a stanchion, a hoisting navigator for allowing an arthritic to deploy and retract the sail without the need to bend the fingers, a hoisting teeter totter secured to the navigator, a teeter-totter hook-lock secured to the teeter totter for automatically locking and unlocking the teeter totter to deploy and retract the sail, a cable secured to a camber, a cable canal formed into the teeter totter for hiding and protecting the cable within, a pivoting pulley housing secured to the teeter totter, a pivoting pulley hub swingingly attached to the pivoting pulley housing, sail-buttresses hingedly attached to the pivoting pulley hub, a sail canopy secured to the sail-buttresses, multiple cable pulleys rotatably secured at multiple locations within the pivoting pulley housing and pivoting pulley hub, a central tube attached to the pivoting pulley hub, sail-buttress-supporting arms hingedly attached to the sail-buttresses, and a shuttling hub attached to the sail-buttress-supporting arms.

An extendable garden shears includes: an outer tube, an inner tube, a telescopic control set, a cutting structure, a wheel unit and a pull string. Through the combination of the above structure, the shears are extendable without the pull string being directly exposed, and the shears has a cutting structure capable of providing different cutting angles.

An agricultural robot includes a machine body, a wheeled traveling device to support the machine body such that the machine body is capable of traveling, the traveling device including at least three wheels, a manipulator including an arm and a robot hand, the arm being attached to the machine body, the robot hand being attached to the arm and capable of holding an object, and a balance controller to control positions of the at least three wheels, respectively, to achieve a balance between the machine body and the manipulator.

A fruit harvesting system includes a vacuum generating subsystem and an end effector connected to the vacuum generating subsystem. The end effector has a first tube having a first diameter, and a second tube having a second diameter smaller than the first diameter so the second tube fits inside the first tube. A fruit harvesting system includes a vacuum generating subsystem, a tube connected to the vacuum generating subsystem and at least one structure coupled to an inside of the tube. A fruit harvesting system includes a vacuum generating subsystem, a first tube connected to the vacuum generating subsystem, and a second tube coupled to the first tube, the second tube having a tubular portion coupled to the first tube in an orientation other than parallel, the second tube having openings on opposite sides of the first tube.

A transportation device for fruit and vegetable picking in a solar greenhouse is provided, which may include a guide rail, a moving mechanism and a picking box. The guide rail is horizontally fixed on side surfaces of multiple supporting columns in the solar greenhouse, an upper side and a lower side of the guide rail are respectively provided with horizontally extended sliding grooves, and a top of the moving mechanism is slidably connected to the guide rail through the sliding grooves, and the picking box is hung at a bottom of the moving mechanism. The transportation device is used to hang the picking box at a bottom of the moving mechanism, so that the moving mechanism can carry the picking box to move along the sliding grooves to transport the picking box to a destination, thereby saving time, saving labor and reducing a labor cost.