A self-guided blossom picker uses a vision system to identify and locate blossoms or inflorescence growing on a plant. The device can be towed by a tractor or it can be self-propelled. Image data captured by the vision system is sent to an machine vision module, which interprets the data and identifies a location of blossom. A controller uses the location data to command a picker to the proper location. A cutter on the picker is actuated to remove the blossom.

A fruit harvesting machine, including a sealed container (12), for collecting fruits, a vacuum pump (13), connected to the sealed container (12), for generating a vacuum in the sealed container (12), a flexible tube (14), connected to the sealed container (12), for drifting therethrough a fruit, a vehicle (28) on which the container a is placed on, a cutting device (27) located at the end (22) of the flexible tube (14), inside the tube, and a ladder (26) installed on the vehicle.

A fruit harvesting machine, including a sealed container (12), for collecting fruits, a vacuum pump (13), connected to the sealed container (12), for generating a vacuum in the sealed container (12), a flexible tube (14), connected to the sealed container (12), for drifting therethrough a fruit, a vehicle (28) on which the container a is placed on, a cutting device (27) located at the end (22) of the flexible tube (14), inside the tube, and a ladder (26) installed on the vehicle.

Devices, systems and methods for harvesting fruits, such as apples, pears, apricots, peaches, citrus fruits, small-citrus fruit, lemon, avocado, vines, tomatoes, eggplants, cucumbers and peppers.

The present invention provides an improved, autonomous unmanned aircraft vehicle (UAV) for harvesting or diluting fruit, and a control unit for coordinating flight and/or harvesting missions thereof, as well as a system and method for harvesting fruits.

The present invention provides an improved, autonomous unmanned aircraft vehicle (UAV) for harvesting or diluting fruit, and a control unit for coordinating flight and/or harvesting missions thereof, as well as a system and method for harvesting fruits.

The present invention provides a fruit harvesting, dilution and/or pruning system comprising: (a) a computerized system for mapping an orchard or a map of trees position and their contour in a plantation; (b) a management system for autonomous unmanned aircraft vehicle (UAV) fleet management for harvesting, diluting or pruning fruits; and a method for UAV autonomous harvesting, dilution and/or pruning of an orchard.

The present invention provides a fruit harvesting, dilution and/or pruning system comprising: (a) a computerized system for mapping an orchard or a map of trees position and their contour in a plantation; (b) a management system for autonomous unmanned aircraft vehicle (UAV) fleet management for harvesting, diluting or pruning fruits; and a method for UAV autonomous harvesting, dilution and/or pruning of an orchard.

A robotic system (100) for harvesting fruit (12) includes an end effector (102) with a conduit extending between an input port and an output port. A vacuum system (108) coupled to the end effector (102) provides suction to suck an object into the input port. A collection system (110) includes multiple channels that extend along a vertical axis and are positioned in series along a horizontal axis. A positioning system (104) moves the end effector (102) along the horizontal and/or vertical axes and extends the end effector (102) away from the collection system (110) to position the input port near an object (e.g., fruit). Responsive to the object being sucked into the conduit, the positioning system (104) moves the end effector (102) to position the output port at a selected channel of the multiple channels to allow the object to be dispensed into the selected channel The selected channel is closest to the end effector (102) along the horizontal axis.

A robotic system (100) for harvesting fruit (12) includes an end effector (102) with a conduit extending between an input port and an output port. A vacuum system (108) coupled to the end effector (102) provides suction to suck an object into the input port. A collection system (110) includes multiple channels that extend along a vertical axis and are positioned in series along a horizontal axis. A positioning system (104) moves the end effector (102) along the horizontal and/or vertical axes and extends the end effector (102) away from the collection system (110) to position the input port near an object (e.g., fruit). Responsive to the object being sucked into the conduit, the positioning system (104) moves the end effector (102) to position the output port at a selected channel of the multiple channels to allow the object to be dispensed into the selected channel The selected channel is closest to the end effector (102) along the horizontal axis.