A draper seal for a crop harvesting header is provided. The 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 conveyor belt for an agricultural harvesting head includes a base web of elastomer-impregnated fabric; elongate cleats that extend upward from the base web and extend across substantially the entire width of the base web; and a plurality of textured protrusions that extend upward from the web between adjacent elongate cleats, wherein the textured protrusions are organized in rows of pockets between adjacent cleats and extend over substantially the entire width of the base web.

A draper having an additional strip of a resilient material attached on to the outer surface of the base layer at the front edge is connected at ends to form a continuous loop by a coupling comprising a first and second end edge which are turned so as to stand upwardly from the band and a clamping assembly clamping the upwardly standing edges together. The additional band at each end of the canvas is recessed from the outer surface and a strip portion formed of a flexible continuous strip material extending longitudinally of the additional band connects the two ends. The strip is bolted at each end to the recessed portion and has a thickness so that its outer surface is slightly less than that of the additional band thus forming in effect a continuation of the band bridging the ends of the canvas.

The feeder device located at the centre section of a front of a harvester. The feeder device comprises one or more flights configured for improving operation of the feeder device. The feeder device comprises a shaft including a plurality of flights. They extend substantially along the entire length of the shaft and are arranged in a spaced apart relationship with respect to each other. In this manner, a threaded-like formation defined by the spaced apart arrangement of flights extends substantially along the entire length of the shaft of the feeder device.

A draper belt system is provided that includes a first draper frame pivotally coupled to a second draper frame at a pivot joint. The pivot joint includes a central longitudinal axis about which rotation at the pivot joint occurs. The draper belt system includes a draper belt assembly including a first roller rotatably coupled to the first draper frame, a second roller rotatably coupled to the second draper frame, and a third roller rotatably coupled between the first and second draper frames. The third roller includes a central longitudinal axis about which the third roller rotates. The central longitudinal axis of the third roller is the same as the central longitudinal axis of the pivot joint.

A draper seal for a crop harvesting header is provided. The 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 roller support for draper belt supporting rollers of a harvester header may include a base, a first post extending from the base in a direction to support a first roller, a second post extending from the base in the direction to support a second roller, an arm extending from the base in the direction between the first post and the second post and a wear structure supported by and immovable relative to the arm. The wear structure may have a wear surface facing downwardly.

In a draper harvesting head having a frame, a left side conveyor supported on the frame, a right side conveyor supported on the frame, a central conveyor supported on the frame and disposed between the left side conveyor and the right side conveyor, and a reciprocating knife fixed to the front of the frame and extending laterally across the frame, a method of controlling slippage between an endless conveyor belt of one of the left side conveyor and the right side conveyor and a crop mat carried on the endless conveyor belt is provided, including determining a speed of the endless conveyor belt and a speed of the crop mat; comparing a difference in the speed of the endless conveyor belt and the speed of the crop mat with a first threshold speed difference; and changing the speed of the endless conveyor belt based upon the step of comparing.

An agricultural harvesting head having an elongate frame, a rear wall, side conveyors and a center conveyor. The side conveyor having an endless belt conveyor with an endless recirculating belt supported on an idler roller and a drive roller. The side conveyor is driven by an endless drive belt nested within the endless recirculating belt.

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.