Systems and methods are provided for adapting picker yield data collected by pickers (e.g., ear pickers, combines, etc.) to account for errors in calibration of the pickers. One exemplary computer-implemented method includes accessing data for a field harvested by multiple pickers, wherein the accessed data includes yield data for the field received from of the pickers, and determining a mass differential for a crop harvested by the pickers from the field. When the mass differential exceeds a threshold, the method then further includes calculating a normalization factor for at least one pair of the pickers, calculating a scaling factor associated with one of the pickers of the at least one pair of the pickers based on the normalization factor, and applying the scaling factor to the yield data received from the pickers such that the yield data is normalized.

An adjustable stalk stomper and/or chopper curtain assembly for a header of an agricultural harvester. The adjustable assembly comprises a control arm, at least one member connected to the control arm, wherein the at least one member is configured to knock down plant stalks and/or to shield the agricultural harvester from flying debris, and wherein the control arm is configured to provide for adjustment of the orientation of the at least one member relative to the ground and the header. An agricultural harvester header may include the above adjustable assembly and a frame having a toolbar. An agricultural harvester may include such header.

A divider of a header for an agricultural vehicle including a divider body, a receiving member configured for being connected to the frame of the header, and an adjustable connector positionable in between an unfolded work position and a folded transport position. The adjustable connector includes a first member, a second member, and an articulating joint for pivotally connecting the first and second members. The first member mounts the divider body, the second member is slidably connected to and received within the receiving member, and the articulating joint is at least partially received within the receiving member in the unfolded work position such that the first and second members are substantially immobilized and the articulating joint is positioned outside of the receiving member in the folded transport position such that the first and second members are movable relative to one another.

The disclosed apparatus, systems and methods relate to a physical stalk sensing system comprising at least one resilient member. Sensors having the resilient member or members are able to estimate the size of the stalks of row crops as they pass through a field, such as a corn field. The sensors can be mounted on a corn head and the results can be analyzed and visualized.

A harvest head having a threshing comb, two covers, and two convergent conveyor belts over a third conveyor belt arranged transversely to the first two.

A hybrid flute for a stalk roll may be configured with a sharp edge positioned between a first blunt edge and a second blunt edge along a length of the flute edge. The flute edge may extend radially outward from a main cylinder of the stalk roll. The flute edge may be engaged with a radius at the base of the flute edge, and a flute base may extend from the radius. A plurality of flute bases positioned adjacent to one another may be configured to form a main cylinder for the stalk roll.

A conveying and conditioning roller for a harvesting machine is provided on the surface thereof with teeth in the form of toothed strips which extend over the longitudinal extent of the roller and in each case have a leading tooth flank and a trailing tooth flank as well as a tooth edge. The roller is provided with wear protection zones continuously or in partial regions, the wear resistance thereof being greater than that of the material of the base body of the roller. The base body has a tooth structure determining the shape of the teeth and tooth wear protection zones are formed on the trailing tooth flanks by a high energy radiation process, substantially maintaining the geometry of the tooth structure, roller wear protection zones being formed together thereby on the rollers, as well as a method for producing such a roller wear protection zone.

A conveying and conditioning roller for a harvesting machine is provided on the surface thereof with teeth in the form of toothed strips which extend over the longitudinal extent of the roller and in each case have a leading tooth flank and a trailing tooth flank as well as a tooth edge. The roller is provided with wear protection zones continuously or in partial regions, the wear resistance thereof being greater than that of the material of the base body of the roller. The base body has a tooth structure determining the shape of the teeth and tooth wear protection zones are formed on the trailing tooth flanks by a high energy radiation process, substantially maintaining the geometry of the tooth structure, roller wear protection zones being formed together thereby on the rollers, as well as a method for producing such a roller wear protection zone.

A deck plate extension for a row unit of an agricultural harvester. The deck plate extension configured to attach to the return side of the row unit side thereby preventing a kernel crop from dropping to the ground during harvesting. The deck plate extension is further provided with a kernel channel configured to direct the kernel crop along the return side of the row unit side to the harvest side of the row unit side. The deck plate extension may be provided as part of a deck plate of a row unit side or may be provided as a second plate added to the row unit side. The deck plate extension is configured to be added as original equipment and as a retrofit to existing row units.

A method for operating an agricultural vehicle. The method includes an initial step of providing the agricultural vehicle which includes a feeder housing and a header. The header includes at least one row unit, which has a pair of deck plates, and a deck plate adjustment system. The deck plate adjustment system includes at least one actuator connected to the deck plates, an electronic control unit operably connected to the at least one actuator, and at least one sensor. The method includes the further steps of pivoting the feeder housing to raise the header, sending, by the at least one sensor, a signal to the electronic control unit, and cycling the deck plates, by the electronic control unit actuating the at least one actuator to move the deck plates, for removing a buildup of material on the deck plates.