A crop ramp for use in a combine header is provided. The crop ramp includes a flat section, a curved section, and a flange. The flat section facilitates coupling the crop ramp to a cutterbar of the combine header. The curved section extends from the flat section. The curved section is configured to facilitate transfer of crop to a belt system of the combine header. The crop is transferred in a first direction defined from the flat section to the curved section. The flange extends from the curved section. The flange is configured to hover above the belt system of the combine header to prevent dirt from flowing in a second direction which is opposite to the first direction.

A header of a harvester includes a cutter bar assembly, a side deck, and an airbag. The side deck includes a conveyor and an arm assembly. The cutter bar assembly is configured to cut crops, and the conveyor is configured to transport the crops cut by the cutter bar assembly toward a center of the header. The arm assembly is coupled to the cutter bar assembly and to the at least one airbag. The arm assembly is configured to pivot to enable the cutter bar assembly to flex along a lateral axis of the header. The airbag is configured to apply a substantially constant force to the at least one arm assembly.

A work vehicle system includes a work vehicle controller configured to output a control signal indicative of instructions to move a feeder house based at least in part on at least one header parameter. The work vehicle controller is configured to output the control signal to a network. The work vehicle also includes an agricultural header controller configured to receive the control signal and control movement of the feeder house based at least in part on the control signal. Further, the work vehicle includes a wing controller configured to receive the at least one header parameter from the network and output a wing control signal indicative of instructions to move a wing based at least in part on the at least one header parameter. The wing is coupled to a center section.

Example draper heads may include an endless belt conveyor and a catch pan disposed adjacent to the endless belt conveyor to collect crop material and defining a uniform gap formed between at least a portion of the catch pan and a portion of an endless belt of the endless belt conveyor located adjacent to the catch pan. A cleat formed on the endless belt cooperates with the catch pan to transport the collected crop material onto the endless belt. The catch pan may include a contoured end that conforms to a shape formed by the endless belt at an end of the endless belt conveyor.

An elevator assembly for a harvester may include an elevator extending within between proximal and distal ends. The elevator may be configured to carry harvested crops between its proximal and distal ends. The elevator assembly may also include a storage hopper at a location adjacent to the distal end of the elevator. The storage hopper may include a rear deflector and a hopper gate. The hopper gate may be movable between a discharge position, at which the hopper gate exposes a discharge opening of the storage hopper, and a storage position, at which the hopper gate covers the discharge opening to prevent harvested crops from being discharged from the elevator assembly. Additionally, when the hopper gate is moved to the storage position, the hopper gate and the rear deflector may at least partially define a storage volume adjacent to the distal end of the elevator for storing the harvested crop.

An elevator assembly for a harvester may include an elevator extending within between proximal and distal ends. The elevator may be configured to carry harvested crops between its proximal and distal ends. The elevator assembly may also include a storage hopper at a location adjacent to the distal end of the elevator. The storage hopper may include a rear deflector and a hopper gate. The hopper gate may be movable between a discharge position, at which the hopper gate exposes a discharge opening of the storage hopper, and a storage position, at which the hopper gate covers the discharge opening to prevent harvested crops from being discharged from the elevator assembly. Additionally, when the hopper gate is moved to the storage position, the hopper gate and the rear deflector may at least partially define a storage volume adjacent to the distal end of the elevator for storing the harvested crop.

A change of state of weed seeds to having reduced germination viability in one minute by illuminating a seed in a processing theater to achieve at least one of 0.66 J/cm2 cumulative illumination energy, and 0.06 W/cm2 irradiance, of at least one of an Indigo Region Illumination Distribution (IRID), and Medium Wavelength Infrared (MWIR) radiation, preferably 2-8 microns, with no high energy transfers, scalding, heat shock, cooking or incineration. The MWIR radiation from heated borosilicate glass or glass powder at just under 500 C offered a peak MWIR emission of 3.75 microns, and was unexpectedly effective, and can be used in a radiant and transmissive weed seed accumulator transport belt. The process can be incorporated into a harvester combine to convert a tailings flow prior to discharge on an agricultural field. An illuminated harvest combine using an illuminator according to the invention allows reduction of the weed seed bank.

A header system is provided. The headers system includes a conveyor belt and a belt roller assembly comprising a belt roller configured to contact the conveyor belt and to rotate about an axis during movement of the conveyor belt. The header system further includes a belt roller assembly mount configured to secure the belt roller on the header system, wherein the belt roller mount assembly comprises a first mounting member configured to secure the belt roller to an infeed deck frame included in the header system.

In a harvesting header having a main frame divided into a center portion and two wing portions connected for pivotal movement about axes and including a rear wall. A reel is mounted on first and second reel arms and a rear auger is mounted at the top of the rear wall. The reel and the auger are also divided into three sections arranged end to end along the rear wall. The joint in the auger is arranged not at the axis but at a position spaced inwardly of the axis so that a first flight of the auger extends inboard of the first reel arm and a second flight of the auger extends inboard of the second reel arm to carry the crop engaging the first flight past the first space to the center portion of the header frame.

A harvester includes a chassis having a head and an outlet from the head to the chassis. A conveying system moves harvested crop from the gathering assembly to the outlet, the conveying system. The conveying system includes an auger having a rotational axis extending along a longitudinal direction and including a center shaft and a helical blade. An auger pan extends parallel to the rotational axis of the auger. The pan includes a first edge, a planar portion extending beneath the auger, and a trough portion defining a lower section with a generally upward extending surface. An air nozzle extends along the first edge of the pan, the nozzle sloping upward from a first nozzle edge lower than the first edge of the pan to a second nozzle edge higher than the first edge of the pan.