A residue handling system for an agricultural harvester includes a chopper that is positionable within a straw hood of the combine harvester and a seed mill that is mounted directly to the chopper. The chopper has projecting elements for chopping straw within the straw hood as the chopper rotates. The seed mill includes a rotatable rotor that is at least partially positioned within a concave. The rotor and the chopper are connected or unitized so as to rotate together.

A sugarcane harvester includes a basecutter assembly for cutting sugarcane stalks from sugarcane plants; a chopping section for receiving the sugarcane stalks from the intake and cutting assembly and chopping the sugarcane stalks into billets; a discharge assembly for receiving the billets from the chopping section and discharging the billets to a storage vehicle; and a height adjustment system for automatically adjusting a height of the basecutter to avoid unwanted contact between the basecutter and a ground surface.

An agricultural harvesting machine includes crop processing functionality configured to engage crop in a field, perform a crop processing operation on the crop, and move the processed crop to a harvested crop repository, and a control system configured to identify a weed seed area indicating presence of weed seeds, and generate a control signal associated with a pre-emergence weed seed treatment operation based on the identified weed seed area.

An agricultural residue depositing apparatus includes a human-controllable mobile vehicle that is capable of generating agricultural residue and depositing it on a ground surface over which the mobile vehicle is moveable. The vehicle includes an interface device that is capable of generating one or more output that is interpretable by a human operator. The apparatus include sensors of agricultural residue deposited by the mobile vehicle and processors to which the sensors are operatively connected. The processors are additionally operatively connected to the interface device such that the interface device generates one or more outputs, based on one or more signals generated by the one or more sensors, of or relating to agricultural residue deposited by the mobile vehicle. The processors are capable of adding human-interpretable augmentation to the outputs indicating one or more parameters of or relating to the deposition of residue.

An agricultural residue depositing apparatus includes a human-controllable mobile vehicle that is capable of generating agricultural residue and depositing it on a ground surface over which the mobile vehicle is moveable. The vehicle includes an interface device that is capable of generating one or more output that is interpretable by a human operator. The apparatus include sensors of agricultural residue deposited by the mobile vehicle and processors to which the sensors are operatively connected. The processors are additionally operatively connected to the interface device such that the interface device generates one or more outputs, based on one or more signals generated by the one or more sensors, of or relating to agricultural residue deposited by the mobile vehicle. The processors are capable of adding human-interpretable augmentation to the outputs indicating one or more parameters of or relating to the deposition of residue.

A spreader system for use in an agricultural harvester having a threshing system and a cleaning system. The spreader system includes a chopper for the chopping of straw from the threshing system and a chaff spreader system and a straw spreader system. The chaff spreader system is configured to receive a flow of chaff from the cleaning system; and the straw spreader system is configured to receive a flow of straw from the chopper. The chaff spreader system is configured to emit a chaff airflow stream in a first flow path, and the straw spreader system is configured to emit a straw airflow stream in a second flow path. The first flow path and the second flow path intersect at a place of confluence apart from the chaff spreader system and the straw spreader system.

Compound headers may include two or more crop harvester types that are operable to harvest different crops simultaneously, such as different crops grown in the same field in an intercropped relationship. The simultaneously harvested crops may be separated into individual crop flows that are handled separately from each other.

Compound headers may include two or more crop harvester types that are operable to harvest different crops simultaneously, such as different crops grown in the same field in an intercropped relationship. The simultaneously harvested crops may be separated into individual crop flows that are handled separately from each other.

A spreader system of an agricultural vehicle for spreading crop residue over a field includes a first spreader device including a plurality of first paddles configured to rotate about a first axis to define a first spread path; and a second spreader device including a plurality of second paddles configured to rotate about a second axis to define a second spread path. The second spreader device and the first spreader device are located side-by-side. The spreader system further includes deflector that include a first deflector portion for deflecting the first spread path and a second deflector portion for deflecting the second spread path. The spreader further includes a deflector driver connected to the deflector. The deflector driver is configured to move the first deflector portion and the second deflector portion of the deflector in a direction generally parallel to the first axis or the second axis in an oscillating pattern.

Weed seeds are destroyed in the chaff from a combine harvester by repeated high speed impacts caused by a rotor mounted in one of a pair of side by side housings which accelerate the discarded seeds into contact with stator bars at angularly spaced positions around the axis of the rotor. The stator bars are formed from bent sheet metal which are L-shaped or U-shaped in cross-section to define a first leg lying in a cylindrical surface surrounding the axis of the rotor and a second leg extending outwardly from the cylindrical surface connected to the first leg at an apex at a leading end of the first leg relative to the direction of rotation of the rotor. When U-shaped, the bars are symmetrical and can be reversed when the second leg is worn for extended life.