A combine harvester is provided with: a threshing device that performs a threshing process of threshing a crop; a grain tank that stores grain obtained by the threshing process; a grain discharging device that discharges grain to be stored in the grain tank to the outside of the vehicle body; a travel driving device that drives travel of the vehicle body; and an engine that serves as a power source. The combine harvester includes a first relay shaft to which power is transmitted from an output shaft of the engine, and the power of the engine is transmitted from the first relay shaft to the grain discharging device and the travel driving device in a branched manner.

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 reinforced feeder housing for an agricultural machine includes a housing body having a top surface, a bottom surface, and two opposing side surfaces each extending between the top and bottom surfaces. The housing body includes a front opening through which crop material is directed into the feeder housing from a header of the agricultural machine, and a rear opening that is substantially opposite the front opening through which crop is expelled from the feeder housing and is delivered to a threshing mechanism of the agricultural machine. Various panels of the housing body are reinforced to improve the structural integrity of the feeder housing and prevent damage to the welds in the housing body.

A merger system for an agricultural vehicle includes: at least one frame mount configured to couple to a chassis; a movable merger frame coupled to the at least one frame mount; a conveyor supported by the merger frame and configured to convey crop material; at least one load sensor associated with the at least one frame mount and configured to output load signals corresponding to a mass of the merger frame; and a controller operatively coupled to the at least one load sensor. The controller is configured to: determine a mass of crop material conveyed by the conveyor based at least partially on the mass of the merger frame; determine a crop yield based at least partially on the determined mass of crop material; and output a yield signal corresponding to the determined crop yield.

A merger system for an agricultural vehicle includes: at least one frame mount configured to couple to a chassis; a movable merger frame coupled to the at least one frame mount; a conveyor supported by the merger frame and configured to convey crop material; at least one load sensor associated with the at least one frame mount and configured to output load signals corresponding to a mass of the merger frame; and a controller operatively coupled to the at least one load sensor. The controller is configured to: determine a mass of crop material conveyed by the conveyor based at least partially on the mass of the merger frame; determine a crop yield based at least partially on the determined mass of crop material; and output a yield signal corresponding to the determined crop yield.

A header includes a forwardly disposed cutter bar assembly and a rearwardly disposed draper deck assembly. The draper seal includes a flexible strip that runs parallel to the cutter bar assembly and perpendicular to the direction of travel. A bracket secures the forward edge of the flexible strip to an upper surface of the cutter bar assembly, which bracket also biases a rearward edge of the flexible strip into engagement with an upper surface of the draper deck assembly, thereby creating a seal between the cutter bar assembly and the draper deck assembly.

A header (102) for an agricultural harvester (100) comprising a frame (104), a cutter bar (106), a draper belt and a cutter bar support sub-assembly connected to the frame is disclosed. The cutter bar support sub-assembly generally includes a draper support sub-assembly (200A,200B) and a support arm subassembly. The draper support sub-assembly is pivotably connected to the support arm sub-assembly and pivotable about a longitudinal axis of the support arm sub-assembly. The draper support sub-assembly includes a first draper support (608) that includes a curved surface engaging the draper belt and a cutter bar mount (606) supporting the cutter bar. The support arm sub assembly includes a support member connected to the frame.

Transverse conveyor (10) of an agricultural harvesting machine, with a basic body (13), the axis of rotation of which extends transversely with respect to the longitudinal direction of a harvesting vehicle carrying the harvesting machine, and with at least two helical transverse conveyor elements (14a, 14b) which are connected to the basic body (13) and have at least two windings (15a, 15b), wherein the respective transverse conveyor element (14a, 14b) serves for conveying crop from a respective lateral edge portion (16, 18) of the transverse conveyor in the direction of a central portion (17) of the transverse conveyor. According to the invention, a distance between adjacently arranged windings (15a, 15c, 15b, 15d) of the transverse conveyor element (14a, 14c, 14b, 14d) is smaller in the region of the lateral edge portions (16, 18) of the transverse conveyor (10) than in the central portion (17) of the transverse conveyor (10).

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 foldable auger having a first and second auger assemblies, each having a respective housing, auger screw and rotation axis. A pivot joins the assemblies, and is configured to permit the second auger assembly to fold relative to the first auger assembly. A first drive coupler is located at an end of the first auger screw and offset from the first axis, and a second drive coupler is located at an end of the second auger screw and offset from the second axis. A drive sleeve is rigidly connected to the end of the second auger screw. The drive sleeve has at least one slot that slidingly receives the second drive coupler. The second drive coupler is movable between a first position in driving connection with the first drive coupler, and a second position not in driving connection with the first drive coupler.