A combine has a feeder house extending forward from the front of the combine, with the front of the feeder house defining a rectangular frame for supporting a harvesting head. A gauge wheel arrangement is supported on the rectangular frame and in turn supports the harvesting head. The gauge wheel arrangement includes a center frame that abuts the rectangular frame and pivots with respect to it. A left side frame with gauge wheels is hinged to the center frame. A right side frame with gauge wheels is hinged to the center frame. The center, left, and right frames can support the harvesting head and permit the harvesting head to pivot with respect to the feeder house, as well as supporting a part of the weight of the harvesting head on the gauge wheels.

A combine draper header and method of floating a wing of the same from a center section of the draper header. The wing is movably supported with respect to the center section to enable movement of the wing between a first position and a second position. The wing is supported with respect to the center section with a resilient float element. Increasing amounts of energy are stored in the resilient float element through movement of the wing from the first position to the second position. The resilient float element is re-oriented with a float linkage to reduce the mechanical advantage of the resilient float element for supporting the wing through movement of the wing from the first position to the second position, thus buffering the wing from a force increase from the resilient float element.

A head for an agricultural machine includes a frame with a center segment defining a first longitudinal axis and a wing defining a second longitudinal axis. The head also includes a motion control assembly connecting the center segment and the wing such that the wing is movable relative to the center segment between a deployed position and a non-deployed position. The motion control assembly is configured to maintain the second longitudinal axis in a parallel relationship with the first longitudinal axis as the wing moves between the deployed position and the non-deployed position, and the wing is movable from the deployed position to the non-deployed position along a continuous arc.

A multi-segment header (102) for an agricultural harvester comprising a multi-segment chassis (150) having a longitudinal support beam (152), an auger (156) extending widthwise across the multi-segment chassis (150) and adjacent the longitudinal support beam (152), and a backsheet extension (160) mounted to a posterior end of the longitudinal support beam (152) of the multi-segment chassis (150). The auger (156) and the backsheet extension blocks grain from passing over the backsheets (158) and going unharvested.

A maize header (2) comprising multiple mowing and infeed units (10) and comprising feeding drums (12) and turning drums (14, 15) arranged behind the mowing and infeed units (10), in the working position a feeding drum (12) is behind the two central mowing and infeed units (10a) and a first turning drum (14) is behind a transfer region between the central mowing and infeed units (10a) and a first lateral mowing and infeed unit (10b) that is laterally next to it, and to transfer the maize header (2) between the two positions, the mowing and infeed units (10) pivot relative to one another about axes (16) so the first lateral mowing and infeed units (10b) and one of the first turning drums (14) is pivotable relative to the adjoining central mowing and infeed unit (10a), so that, in the transport position, a frustoconical envelope (14a) of the respective first turning drum (14) is completely inside a permissible transport width of the maize header (2).

A maize header comprising multiple mowing and infeed units (units 10), the first lateral mowing and infeed units (units 10b) are laterally next to central mowing and infeed units (units 10a), second lateral mowing and infeed units (units 10c) are laterally next to the first units (10b), and units (10d) are laterally next to the second units (10c), wherein, to transfer the maize header (2) between the working and a transport position, the units (10) are pivotable relative to one another about horizontal pivot axes (16) so that each of the units (10b) is pivotable about a first pivot axis (16a), each of the units (10c) is pivotable about a second pivot axis (16b), and each of the units (10d) is pivotable about a third pivot axis (16c), wherein a pivot angle (?1) about the axes (16a) is 164??4?, a pivot angle (?2) about the (16b) is 180??4?, and a pivot angle (?3) about the axes (16c) is 184??4?.

An agricultural header includes: a main section including a main frame carrying at least one cutting element; at least one wing section pivotably coupled to the main section and including a wing frame; and a linkage pivotably coupling the at least one wing section to the main section, the linkage including an upper bar and a lower bar which are both coupled to the main frame and the wing frame, the upper bar defining an upper bar axis and the lower bar defining a lower bar axis which is non-parallel to the upper bar axis.

An agricultural vehicle including a chassis, at least one power take off member, and a folding header operably coupled to the agricultural vehicle and supported by the chassis. The folding header includes a center section operably coupled to the chassis of the agricultural vehicle. The center section includes a pair of lateral ends and at least one drive assembly operably coupled to the at least one power take off member of the agricultural vehicle. The folding header also includes at least one additional section pivotally coupled to one of the lateral ends of the center section and operably coupled to the at least one drive assembly. The at least one additional section is selectively pivotable between an operational position and a nonoperational position. The center section is configured to harvest a crop material in both of the operational position and nonoperational position of the at least one additional section.

A draper belt system is provided that includes a first draper belt assembly with first and second rollers, and a second draper belt assembly with third and fourth rollers. The third roller of the second draper belt assembly is disposed adjacent to the first roller of the first draper belt assembly. The first draper belt assembly is configured to pivot relative to the second draper belt assembly. Pivoting of the first draper belt assembly results in a change in a distance between the first and third rollers.

A harvester head may include a position adjustable reel having a first segment and a second segment, a hydraulic supply comprising a pump and a reservoir, a first plurality of hydraulic cylinders coupled to the first segment to reposition the first segment, a second plurality of hydraulic cylinders coupled to the second segment to reposition the second segment, a first bidirectional valve operably coupled between the hydraulic supply and the first plurality of hydraulic cylinders, a second bidirectional valve operably coupled between the hydraulic supply and the second plurality of hydraulic cylinders, at least one sensor to sense relative positioning of the first segment and the second segment and a controller. The controller may output control signals to the first bidirectional valve and the second bidirectional valve based upon signals from the at least one sensor to synchronize positioning of the first segment and the second segment.