Embodiments relate to a crop harvesting apparatus configured to garner or harvest crops from plants via vacuum suction and sort the garnered crops via a quick-switching gate system. A vacuum source generates the vacuum suction for the apparatus so that crops are garnered (or plucked) from the plant via suction through an end-effector, which are then transferred to a crop sorter by way of tubing that has a smooth inner surface. The crop sorter utilizes a gate system that exploits vacuum suction from the vacuum source and gravity to quickly and effectively sort the garnered crops into a hopper and a rejection bin.

An example system includes a nozzle having an inlet: an outlet mechanism disposed longitudinally adjacent to the nozzle; a conduit longitudinally adjacent to the outlet mechanism where the conduit includes a distal chamber, a middle chamber, and a proximal chamber, that; are longitudinally disposed along a length of the conduit; a partition block configured to move between (i) a first position at which the partition block: is disposed laterally adjacent to the middle chamber, such that the partition block is offset from a longitudinal axis of the conduit, and (ii) a second position at which the partition block resides in the middle chamber between the distal chamber and the proximal chamber; and a deceleration structure disposed at a proximal, end of the conduit and bounding the proximal chamber, where the deceleration structure is configured to decelerate fruit feat has traversed the conduit.

A harvesting system includes a vertical frame, a plurality of linear robots, a plurality of cameras and a processor. The vertical frame is configured to be positioned opposite a sector to be harvested. The robots are arranged in pairs stacked vertically in the frame, each pair including first and second robots that are configured to move together along a vertical axis, to move independently of one another along a horizontal axis, and have respective first and second robot arms that are configured to approach the sector and harvest fruit. The plurality of cameras is configured to acquire images of the sector. The processor is configured to identify the fruit in the images and control the robots to harvest the fruit.

An agricultural leaf stripper which can adopt numerous configurations allowing leaf stripping of bushes and trees of varying shapes and sizes consists of a structure capable of being transported along a horizontal axis parallel to the ground and consisting of a structure formed of two parts one of which is fixed to the transporter vehicle and the other of which can slide vertically on the fixed part and supports a rectilinear rail generally parallel to the structure and able to be moved horizontally towards and away from the structure and tilted with respect thereto, the rail carrying at least two pneumatic leaf stripping heads, each stripping head being able to be set to a desired position on the rail independently of the other leaf stripping heads, and each being able to be set to a desired orientation about its working axis on the rail.

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.

An agricultural leaf stripper which can adopt numerous configurations allowing leaf stripping of bushes and trees of varying shapes and sizes consists of a structure capable of being transported along a horizontal axis parallel to the ground and consisting of a structure formed of two parts one of which is fixed to the transporter vehicle and the other of which can slide vertically on the fixed part and supports a rectilinear rail generally parallel to the structure and able to be moved horizontally towards and away from the structure and tilted with respect thereto, the rail carrying at least two pneumatic leaf stripping heads, each stripping head being able to be set to a desired position on the rail independently of the other leaf stripping heads, and each being able to be set to a desired orientation about its working axis on the rail.

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.

Systems and methods here may include a vehicle with automated subcomponents for harvesting delicate targets such as agriculture. In some examples, the vehicle includes a targeting subcomponent and a harvesting subcomponent. In some examples, the harvesting subcomponent includes vacuum features which gently attach to target agriculture to secure it. In some examples, the harvesting subcomponent includes padded spoons to grasp and remove the target agriculture from the foliage.

A pollen collection device for collecting pollen from crop plants grown in rows includes a housing assembly configured to be mounted on a base for being transported through a row of crop plants. The housing assembly receives at least a portion of the plants as the housing assembly is transported through the row of crop plants. An agitation assembly is attached to the housing assembly for agitating the plants as the housing assembly is transported through the row of crop plants to displace pollen from the plants. A pollen collection assembly is attached to the housing assembly for collecting the pollen displaced from the plants as the housing assembly is transported through the row of crop plants.

An example system includes a nozzle having an inlet; an outlet mechanism disposed longitudinally adjacent to the nozzle; a conduit longitudinally adjacent to the outlet mechanism, where the conduit includes a distal chamber, a middle chamber, and a proximal chamber that are longitudinally disposed along a length of the conduit; a partition block configured to move between (i) a first position at which the partition block is disposed laterally adjacent to the middle chamber, such that the partition block is offset from a longitudinal axis of the conduit, and (ii) a second position at which the partition block resides in the middle chamber between the distal chamber and the proximal chamber; and a deceleration structure disposed at a proximal end of the conduit and bounding the proximal chamber, where the deceleration structure is configured to decelerate fruit that has traversed the conduit.