A chopper for an agricultural harvester comprises a housing, a rotor, a bank of counter-knives, and an adjuster. The housing comprises a variable geometry outlet floor. The is positioned in an interior region of the housing for rotation therein relative to the housing. The bank of counter-knives is movable relative to the rotor between a first aggressiveness position and a second aggressiveness position to adjust chopping aggressiveness of the chopper. The outlet floor comprises a ramp movable relative to the rotor between a first ramp position and a second ramp position. The adjuster positions the ramp in the first ramp position when the bank of counter-knives is positioned in the first aggressiveness position and positions the ramp in the second ramp position when the bank of counter-knives is positioned in the second aggressiveness position.

A driver pacing information apparatus for providing a driver of transport vehicle with pacing information for operating the transport vehicle alongside a harvester may include a position sensing assembly configured to sense a position of a transfer spout of the harvester with respect to a frame of the harvester, a pacing indication display configured to provide pacing information to the driver of the transport vehicle, and a controller assembly configured to control the pacing indication display based upon position sensing of the position sensing assembly. The pacing indication display may be configured to visually provide pacing information to the driver of the transport vehicle.

A straw chopper for a combine harvester including a rotor supporting a plurality of chopping elements. A rotor housing including an inlet opening, an outlet axially aligned with the inlet opening, and at least one outlet that is axially offset from the inlet opening. A portion of the straw is conveyed tangentially to the axially-aligned outlet, whilst a further portion is conveyed from the inlet opening to the axially offset outlet(s) via a path having an axial component, for example a helical path. Guide vanes may be provided on the inside of the housing to impart an axial force upon the straw.

A combine harvester separates crop into straw and chaff and weed seeds using a sieve, a chopping rotor with a spreading device and at least one weed seed devitalization section. The components can be operated in a first mode where both the first material and said second material are directed to the chopper and a second mode the first material is directed to the chopper inlet and the second material is directed to the WSD. This can be effected by providing a guide wall which has a leading edge attached adjacent a rear edge of the sieve and extends rearwardly therefrom. The chopper and the WSD can also be moved to provide the change of modes. A construction of destructor mill with an outer stator on the housing is also disclosed along with a method of feeding the lost grain to the WSD.

A combine harvester separates crop into straw and chaff and weed seeds using a sieve, a chopping rotor with a spreading device and at least one weed seed devitalization section. The components can be operated in a first mode where both the first material and said second material are directed to the chopper and a second mode the first material is directed to the chopper inlet and the second material is directed to the WSD. This can be effected by providing a guide wall which has a leading edge attached adjacent a rear edge of the sieve and extends rearwardly therefrom. The chopper and the WSD can also be moved to provide the change of modes. A construction of destructor mill with an outer stator on the housing is also disclosed along with a method of feeding the lost grain to the WSD.

A residue vision system includes a harvesting machine configured to traverse a field and harvest an agricultural material, a residue distribution system carried by the harvesting machine and configured to distribute a residue of the agricultural material onto a first harvested area of the field, at least one camera coupled to the harvesting machine and configured to acquire an image of a second harvested area of the field, and an electronic control unit in communication with the at least one camera and the residue distribution system. The electronic control unit is configured to analyze the image acquired by the at least one camera, and in response to the analysis adjust the residue distribution system to adjust distribution of the residue onto the first harvested area of the field.

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 in a direction centrifugally away from the rotor onto a stator including angularly adjustable stator surfaces around the axis. Thus the discarded seeds rebound back and forth between the rotor and the stator to provide a plurality of impacts. The seeds are carried axially of the rotor by a controlled airstream so that they move to an axial discharge location where a discharge fan is mounted. The angle of the discharge around the rotor axis can be changed to direct the seeds to the side of the combine away from a straw chopper, towards the guide fins of the tailboard of the chopper, or into the housing of the straw chopper.

A swath lifter includes a rotor over which the crop is carried for aeration with the rotor driven in a direction so that an underside of the rotor adjacent the ground is driven opposite to the direction of movement. The rotor carries rows of tines at angularly spaced positions around the rotor each associated with a flexible strip of a resilient material located in front of the tines and covering an inner part of the tines with the outer part exposed so that, as the rotor rotates forwardly relative to the ground, the strip is presented to the swath on the ground in advance of the tines to avoid contact of the inner portion of the tines with the crop material at the top of the swath while the exposed outer ends of the tines operate on the wetter part of the swath at the ground.

A control tower crop production method for the production of processed crop products from crop material. A control tower entity enters into a plurality of presale contracts and supply contracts, to purchase sufficient crop material with at least one supplied material characteristic to avow for processing of same into an aggregate product sold quantity amount of crop material fractions or crop material derivatives. Controlling the quantity and character of the crop material purchased allows for precise acquisition of feed stock for the preparation of a required amount of processed crop products. Various processing methods for the processing and fractionation of crop material including hemp grain are also disclosed.

A residue management system comprises a chopper to chop crop residue, a residue spreader, and a floor extension. The residue spreader is mounted for pivotable movement relative to the chopper between a dispersal position to disperse crop residue and a windrow position to deposit crop residue in a windrow. The residue spreader comprises a first spreading device, a second spreading device, and a splitter positioned laterally between the first and second spreading devices to divide flow of crop residue therebetween. A floor of the chopper and a floor of the residue spreader are spaced apart from one another to define a gap. The floor extension projects rearwardly from the floor of the chopper partially over the floor of the residue spreader about the gap alongside the splitter to guide flow of crop residue from the chopper to the residue spreader.