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 subassembly. 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 process for conveying a flow of harvested crop along a first conveyor, which is configured to convey the flow along a first direction, and a second conveyor arranged downstream of the first conveyor and which is configured to convey the flow along a second direction different from the first direction. The process includes operating the first conveyor at a variable conveyor speed presenting a cycle of acceleration and deceleration, the cycle being operable to ensure a spatial repartition of the flow of harvested crop on the second conveyor, which receives the flow at a location that is variable according to the first direction.

A process for conveying a flow of harvested crop along a first conveyor, which is configured to convey the flow along a first direction, and a second conveyor arranged downstream of the first conveyor and which is configured to convey the flow along a second direction different from the first direction. The process includes operating the first conveyor at a variable conveyor speed presenting a cycle of acceleration and deceleration, the cycle being operable to ensure a spatial repartition of the flow of harvested crop on the second conveyor, which receives the flow at a location that is variable according to the first direction.

A shaker device including at least one motorized member that is intended to transmit by contact a shaking force to objects to be shaken. The member includes a plurality of structural inserts that are covered by a wear jacket. Each of the structural inserts has respective left lobes and right lobes. The inserts are distributed in the jacket so as to form a respective discrete stack of left lobes and right lobes.

A shaker device including at least one motorized member that is intended to transmit by contact a shaking force to objects to be shaken. The member includes a plurality of structural inserts that are covered by a wear jacket. Each of the structural inserts has respective left lobes and right lobes. The inserts are distributed in the jacket so as to form a respective discrete stack of left lobes and right lobes.

A system for cleaning a flow of harvested crop, including a conveyor to convey the flow downstream of the conveyor into a cleaning zone into which the flow is discharged, and a cleaning unit located above the cleaning zone and operable to generate an upward air flow through the cleaning zone for extracting residues contained in the discharged flow. The system further includes at least two conveying rolls that are disposed behind a downstream end of the conveyor in an upstream part of the cleaning zone to be fed with the flow of harvested crop discharged from the conveyor. The conveying rolls are arranged to convey the crop flow and to discharge it into a downstream part of the cleaning zone. Passages are formed between or through the rolls, and are arranged to allow an upward air flow therethrough for extracting residues from the crop present on the conveying rolls.

An agricultural mechanical harvesting system useable with a harvester machine. The system includes at least one airflow generator connected to nozzles via air conduction systems for ejecting pressurized air flows from the nozzles located in the harvester machine above fruit receiving units and under fruit harvester units. The nozzles are positioned above the fruit receiving units and under the fruit harvester units of the harvester machine.

An agricultural mechanical harvesting system useable with a harvester machine. The system includes at least one airflow generator connected to nozzles via air conduction systems for ejecting pressurized air flows from the nozzles located in the harvester machine above fruit receiving units and under fruit harvester units. The nozzles are positioned above the fruit receiving units and under the fruit harvester units of the harvester machine.

Harvesting tools are disclosed which may comprise a gripper including a set of finger elements constructed and arranged to envelop a target object pertaining to agricultural produce, and a manipulator carriage configured to actuate the gripper during operation to grasp the target object. Related systems and methods are also disclosed.

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.