A draper header for harvesting agricultural crops includes a tension draper track assembly for supporting a return run of a draper belt. The draper header includes a header frame with first and second support legs, and the draper belt extends across the first and second support legs for transporting harvested agricultural crops. The tension draper track assembly is operatively coupled between the first and second support legs and includes an elongated draper track. The elongated draper track is secured to one of the first and second support legs and includes a tensioning mechanism coupled to the other of the first and second support legs for tensioning the elongated draper track across the first and second support legs for supporting the return run of the draper belt. The elongated draper track may also be coated in a low-friction material to reduce friction and wear on the return run of the draper belt.

A harvesting machine feederhouse that comprises an outer body connectable to and between a head unit and a thresher of the machine. The feederhouse additionally comprises a liner disposed across a bottom surface of the outer body, and at least one conveyor rotatably disposed within the outer body for conveying harvested plant product received from the head unit along the liner into the thresher. Each conveyor includes a first guide, a second guide, a pair of conveyor transports that extend between, and are disposed around, the first guide and the second guide. Each conveyor additionally includes a plurality of plant product sweeps disposed across and connected to the transports. Each sweep is sized to contact the liner as the conveyor transports are rotated around the first guide and second guide, thereby conveying plant product received from the head unit along the liner into the thresher.

A system for removing parts from plants rooted in an agricultural field while leaving other parts of the plants rooted in the agricultural field may include a harvester apparatus with an intake throat formed by structures such as the combination of an infeed head and infeed conveyor, a pair of stripping assemblies including stripping belts, or stripping assemblies including stripping members such as chains.

A header for an agricultural vehicle, and an agricultural vehicle having the header. The header includes a center section extending in a lateral direction, a wing section movably connected at a lateral end of the center section and extending in the lateral direction from the center section, a ground support attached to and extending in a downward direction from the wing section, and a resilient support operatively connected to the wing section and the ground support. The resilient support is configured to generate an adjustable predetermined force to bias the ground support in the downward direction.

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.

An elevator assembly for a harvester may include an elevator housing and an elevator extending within the elevator housing between a proximal end and a distal end. As such, the elevator may be configured to carry harvested crops between its proximal and distal ends. Furthermore, the elevator assembly may include a storage hopper extending from the elevator housing at a location adjacent to the distal end of the elevator. The storage hopper may include a conveyor extending within the storage hopper between a first end and a second end, with the conveyor configured to carry the harvested crops between its first and second ends towards a discharge opening of the storage hopper.

A harvesting header for attachment to a harvesting machine, the header including two or more sub-assemblies each which includes a respective crop gathering mechanism and a respective drive mechanism coupled to operate the crop gathering mechanism. The drive mechanisms for the respective sub-assemblies are operable independently of one another to enable them to run at different speeds when the harvesting machine is performing a turn manoeuver.

A header of a combine harvester includes a belt conveyor configured to direct a movement of harvested crop material toward a feederhouse of the combine harvester. The belt conveyor is located adjacent an inlet of the feederhouse. The belt conveyor includes at least one protrusion extending radially from the belt conveyor that helps direct movement of harvested crop material toward the feederhouse.

A sensor assembly for determining yield of grain harvested by a harvesting machine during harvesting operations. The sensor assembly includes a sensor housing, a displaceable sensor member and a displacement sensor. The sensor housing is mounted to the grain elevator housing above an upper sprocket of a conveyor disposed within the grain elevator housing. The sensor member is displaceably supported via the sensor housing within the elevator housing above the upper sprocket and along a direction of travel of the grain piles thrown by the conveyor flights rotating around the upper sprocket. The thrown grain piles produce a grain force on the sensor member causing a displacement of the sensor member in relation to the grain force. The displacement sensor generates a grain force signal corresponding to the displacement of the sensor member.

A sensor assembly for determining yield of grain harvested by a harvesting machine during harvesting operations. The sensor assembly includes a sensor housing, a displaceable sensor member and a displacement sensor. The sensor housing is mounted to the grain elevator housing above an upper sprocket of a conveyor disposed within the grain elevator housing. The sensor member is displaceably supported via the sensor housing within the elevator housing above the upper sprocket and along a direction of travel of the grain piles thrown by the conveyor flights rotating around the upper sprocket. The thrown grain piles produce a grain force on the sensor member causing a displacement of the sensor member in relation to the grain force. The displacement sensor generates a grain force signal corresponding to the displacement of the sensor member.