Methods and systems for estimating volumes of agricultural crops are provided. A geographic position sensor provides positions of a harvesting machine as it gathers an agricultural crop and places the crop on the ground in a windrow. A speed of the harvesting machine is determined using the geographic position sensor. Signals are received from a sensor system disposed at a bottom of the harvesting machine. The signals are indicative of profiles of segments of the windrow on the ground. Cross-sectional areas of the windrow are estimated using the signals. Volumes of the agricultural crop are estimated using the speed of the harvesting machine and the estimated cross-sectional areas of the windrow.

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.

A system for removing parts from plants rooted in an agricultural field while leaving other parts of the plants rooted in the agricultural field may include a harvester apparatus with an intake throat formed by structures such as the combination of an infeed head and infeed conveyor, a pair of stripping assemblies including stripping belts, or stripping assemblies including stripping members such as chains.

A system for removing parts from plants rooted in an agricultural field while leaving other parts of the plants rooted in the agricultural field may include a harvester apparatus with an intake throat formed by structures such as the combination of an infeed head and infeed conveyor, a pair of stripping assemblies including stripping belts, or stripping assemblies including stripping members such as chains.

The present concept is a plant trimming assembly for trimming materials from plants and includes a frame, and a cylindrical slotted drum rotationally mounted to the frame along a longitudinal axis. The slotted drum includes an exterior surface and a longitudinally oriented internal passageway for receiving plant material there through. It further includes a longitudinally oriented cutting assembly retainer which is also rotationally mounted to the frame about the longitudinal axis such that it rotates concentrically around the outside of the exterior surface and along the length of the slotted drum. A longitudinally oriented blade is mounted to a cutting assembly which in turn is mounted to the cutting assembly retainer. The cutting assembly rotates in unison with the retainer around the outside of the exterior surface of the slotted drum. The cutting assembly is configured to maintain a pre-selected stand-off gap between a cutting edge of the blade and a circumferential contour of the exterior surface of the drum such that plant material projecting through a slot and beyond the stand-off gap will be trimmed off by the rotating blade cutting edge.

A harvester travels along a route within a field and selectively harvests edible crowns ready for harvesting. As the harvester travels along the route, a position of the harvester and/or the edible crowns may be determined using an encoder, imaging device(s), and/or navigational system(s). For example, image(s) captured by the imaging device(s) may be used to determine a location of the edible crowns and/or global positioning satellite (GPS) coordinates may indicate a location of the harvester within the field. These locations may be used for instructing harvesting components to harvest the edible crowns. For example, the harvester may include robotic arms having end effectors that harvest the edible crowns. Knowing the location of the edible crowns and/or the harvester therefore allows for the accurate placement of the end effectors for harvesting the edible crowns.

A harvester travels along a route within a field and selectively harvests edible crowns ready for harvesting. As the harvester travels along the route, a position of the harvester and/or the edible crowns may be determined using an encoder, imaging device(s), and/or navigational system(s). For example, image(s) captured by the imaging device(s) may be used to determine a location of the edible crowns and/or global positioning satellite (GPS) coordinates may indicate a location of the harvester within the field. These locations may be used for instructing harvesting components to harvest the edible crowns. For example, the harvester may include robotic arms having end effectors that harvest the edible crowns. Knowing the location of the edible crowns and/or the harvester therefore allows for the accurate placement of the end effectors for harvesting the edible crowns.

A harvester travels along a route within a field and selectively harvests edible crowns ready for harvesting. As the harvester travels along the route, a position of the harvester and/or the edible crowns may be determined using an encoder, imaging device(s), and/or navigational system(s). For example, image(s) captured by the imaging device(s) may be used to determine a location of the edible crowns and/or global positioning satellite (GPS) coordinates may indicate a location of the harvester within the field. These locations may be used for instructing harvesting components to harvest the edible crowns. For example, the harvester may include robotic arms having end effectors that harvest the edible crowns. Knowing the location of the edible crowns and/or the harvester therefore allows for the accurate placement of the end effectors for harvesting the edible crowns.

A harvester travels along a route within a field and selectively harvests edible crowns ready for harvesting. As the harvester travels along the route, a position of the harvester and/or the edible crowns may be determined using an encoder, imaging device(s), and/or navigational system(s). For example, image(s) captured by the imaging device(s) may be used to determine a location of the edible crowns and/or global positioning satellite (GPS) coordinates may indicate a location of the harvester within the field. These locations may be used for instructing harvesting components to harvest the edible crowns. For example, the harvester may include robotic arms having end effectors that harvest the edible crowns. Knowing the location of the edible crowns and/or the harvester therefore allows for the accurate placement of the end effectors for harvesting the edible crowns.