A destemming device includes a housing, a motor, and a belt system configured to fit within the housing. The housing includes at least one cutting aperture. The belt system includes a first belt assembly and a second belt assembly. The first belt assembly includes a first plurality of rollers and a first gripper belt extending around the first plurality of rollers. The second belt assembly includes a second plurality of rollers and a second gripper belt extending around the second plurality of rollers. The first gripper belt and the second gripper belt define a nip. The at least one cutting aperture is aligned with the nip. The motor is operatively connected to the belt system.

A destemming device includes a housing, a motor, and a belt system configured to fit within the housing. The housing includes at least one cutting aperture. The belt system includes a first belt assembly and a second belt assembly. The first belt assembly includes a first plurality of rollers and a first gripper belt extending around the first plurality of rollers. The second belt assembly includes a second plurality of rollers and a second gripper belt extending around the second plurality of rollers. The first gripper belt and the second gripper belt define a nip. The at least one cutting aperture is aligned with the nip. The motor is operatively connected to the belt system.

A shaped conveyor assembly configured for use in association with a harvester comprising a first side lower conveyor sub-assembly and a second lower conveyor sub-assembly. One or both of the sub-assemblies having a frame structure, a discharge assembly and a conveyor assembly. The frame structure has a gathering portion, an outward portion and a terminating portion. The gathering portion is positioned proximate the first end and spaced apart from the second end. The terminating portion is positioned proximate the second end and spaced apart from the first end. The outward portion extends therebetween, the outward portion being inclined in an upward direction relative to the gathering portion, and directed in an outward direction, thereby extending away from the channel, and away from the other one of the first side and the second side lower conveyor sub-assemblies.

A shaped conveyor assembly configured for use in association with a harvester comprising a first side lower conveyor sub-assembly and a second lower conveyor sub-assembly. One or both of the sub-assemblies having a frame structure, a discharge assembly and a conveyor assembly. The frame structure has a gathering portion, an outward portion and a terminating portion. The gathering portion is positioned proximate the first end and spaced apart from the second end. The terminating portion is positioned proximate the second end and spaced apart from the first end. The outward portion extends therebetween, the outward portion being inclined in an upward direction relative to the gathering portion, and directed in an outward direction, thereby extending away from the channel, and away from the other one of the first side and the second side lower conveyor sub-assemblies.

A row unit for a header of an agricultural harvester is provided. The row unit includes a frame, a first deck plate assembly mounted to the frame, and a second deck plate assembly mounted to the frame. The first and second deck plate assemblies each include a deck plate, a plurality of deck plate segments extending from the deck plate and moveable between a first position and a second position relative to the deck plate, and a plurality of biasing members for biasing each respective deck plate segment. The row unit includes both operator controlled macro adjustment and automatic micro adjustment of a gap between the first deck plate assembly and the second deck plate assembly. The micro adjustment is achieved through biasing members biasing each respective deck plate segment.

A harvesting device for harvesting fruit hanging from a plant, includes a frame which is displaceable in a transport direction and carries a loop-like conveyor track which can be driven in circular manner, and at least one harvesting bin connected to the conveyor track. The conveyor track lies in a plane which is substantially parallel to the transport direction and which lies at a first acute angle to the horizon in a direction transversely of the transport direction during normal use of the harvesting device. A method for harvesting fruit hanging from a plant, wherein the harvesting device is used.

A harvesting device for harvesting fruit hanging from a plant, includes a frame which is displaceable in a transport direction and carries a loop-like conveyor track which can be driven in circular manner, and at least one harvesting bin connected to the conveyor track. The conveyor track lies in a plane which is substantially parallel to the transport direction and which lies at a first acute angle to the horizon in a direction transversely of the transport direction during normal use of the harvesting device. A method for harvesting fruit hanging from a plant, wherein the harvesting device is used.

A robotic fruit picking system includes an autonomous robot that includes a positioning subsystem that enables autonomous positioning of the robot using a computer vision guidance system. The robot also includes at least one picking arm and at least one picking head, or other type of end effector, mounted on each picking arm to either cut a stem or branch for a specific fruit or bunch of fruits or pluck that fruit or bunch. A computer vision subsystem analyses images of the fruit to be picked or stored and a control subsystem is programmed with or learns picking strategies using machine learning techniques. A quality control (QC) subsystem monitors the quality of fruit and grades that fruit according to size and/or quality. The robot has a storage subsystem for storing fruit in containers for storage or transportation, or in punnets for retail.

A robotic fruit picking system includes an autonomous robot that includes a positioning subsystem that enables autonomous positioning of the robot using a computer vision guidance system. The robot also includes at least one picking arm and at least one picking head, or other type of end effector, mounted on each picking arm to either cut a stem or branch for a specific fruit or bunch of fruits or pluck that fruit or bunch. A computer vision subsystem analyses images of the fruit to be picked or stored and a control subsystem is programmed with or learns picking strategies using machine learning techniques. A quality control (QC) subsystem monitors the quality of fruit and grades that fruit according to size and/or quality. The robot has a storage subsystem for storing fruit in containers for storage or transportation, or in punnets for retail.

The berry catcher system has an elastic catcher sheet that is sandwiched between upper and lower endless hollow rims. A protector sheet is deployed below the catcher sheet. The system is structured so that as berries are dislodged from their respective vines, the catcher sheet catches the berries as the protector sheet simultaneously protects (at least) the underside of the catcher sheet.