A method for creating a narrow row head unit which may include a back plate secured to a left gearbox and a right gearbox, and which gearboxes may be positioned adjacent one another. Each gearbox may provide rotational power to a pair of stalk rolls and a drive sprocket for a gathering chain. A right mounting tab may be secured to the back plate and the right gearbox, and a left mounting tab may be secured to the back plate and left gearbox. A right plate and leg may extend outward from the back plate adjacent the right mounting tab and a left plate and leg may extend outward from the back plate adjacent the left mounting tab. A narrow row head unit positioned left-of-center on a header may have the gathering chain positioned substantially over the right plate, and right-of-center substantially over the left plate.

A system for modifying a row unit of a harvesting head, the system including at least one cutting disk adapted for being rotatably mounted to the frame of the row unit between a gathering chain drive sprocket and idler sprocket. The cutting disk includes a sprocket attached thereto for being engaged and driven by the gathering chain in order to rotate the cutting disk. Two counter-rotating cutting disks may be provided, each being driven by a separate gathering chain. A method for modifying a row unit includes loosening the gathering chains, removing existing stalk rolls and housings, installing a cover plate over a gearbox to which the housings were mounted, removing existing trash knives, drilling holes in the row unit frame for mounting the cutting disks, installing the cutting disks, and tightening the gathering chains such that the gathering chains engage sprockets attached to the cutting disks.

The disclosure relates to agricultural systems. The systems have stalk sensor assemblies and/or data visualization systems. The stalk sensor assemblies are configured for assessing the size and other characteristics about crops, such as corn and other grains entering an agricultural implement, such as a harvester. The stalk sensor assemblies may use an estimation of the stalk perimeter to establish stalk size and therefore further features about the crop. The visualization system utilizes data from the stalk sensor assemblies to calculate and display relevant information about the crop.

A drive system of a header for an agricultural vehicle. The header includes a plurality of driven devices. The drive system includes a shaft configured for conveying motive power from the agricultural vehicle to the header, a gearbox configured for being located on the header and for transferring motive power to the plurality of driven devices, and a torque damper. The torque damper is operably connected in between the shaft and the gearbox. The torque damper is configured for reducing a magnitude of a torque spike.

A detasseling apparatus includes a chassis having a head mounted to the chassis. The head supports a plurality of row units, each of the row units having an independently adjustable vertical position. Each row unit is independently vertically adjustable. Each row unit includes a puller or cutter, a height adjustment assembly for independently adjusting vertical position of the detasseling assembly to maintain the puller or cutter at a predetermined height relative to seed corn plants being engaged, and an optical sensing assembly. The optical sensing assembly includes a first photoelectric sensor at a first sensor height and a second photoelectric sensor at a second sensor height, the first sensor height being above the second sensor height. A processor receives and stores detasseling data related to detasseling including corn height, depth of cut, height after cutting. The information may be shown on displays to the operator, stored on board the detasseler and/or transmitted to a central control center.

row crop heads and pivoting assemblies associated with the row crop heads operable to displace a crop divider of the row crop heads during folding of a portion of the row crop head are disclosed. In some implementations, a pivoting assembly may include a first bracket coupled to a center frame of a row crop head, a second bracket coupled to a wing frame of the row crop head, and a rotatable locking component rotatably coupled to the first bracket. The rotatable locking component is operable to lock a row divider disposed at an interface between the wing frame and the center frame when the wing frame is moved from an unfolded position to a folded position relative to the center frame.

A system for controlling a direction of travel of a work vehicle may include a location sensor configured to capture data indicative of a location of the vehicle within a field across which the vehicle is traveling. A controller of the system may be configured to determine the location of the vehicle within the field based on the data captured by the location sensor. Furthermore, the controller may be configured to determine a centerline adjustment value based on a field map associated with the field and the determined location of the vehicle. Moreover, the controller may be configured to adjust a position of a guidance line defined between first and second crop rows within the field such that the guidance line is offset from a centerline between the first and second crop rows by the centerline adjustment value.

A multi-positional stalk stomper assembly for attaching a stalk stomper to a toolbar of a farm implement comprises a mounting bracket and a pivotal shoe assembly. The mounting bracket is adaptable to be attached to the toolbar of the farm implement and includes a rectangular plate, the plate having first and second major sides, the first side engageable with the toolbar. A first connecting member outwardly extends perpendicular from the second major side of the plate. The shoe assembly includes a torsion spring assembly, a second connecting member outwardly extending from the torsion spring assembly, the second connecting member mateable with the first connecting member, a shoe bracket pivotally connected to the torsion spring assembly, and a downwardly extending shoe attached to the shoe bracket. Upon mating the second connecting member with the first connecting member, the shoe assembly is lockable to the mounting bracket at a selected position.

A crop dividing device for an agricultural header including a hood and a divider connected to the hood. The divider includes a base member pivotally connected to the hood. The base member includes a receiving section. The divider also includes an ear dam member receivable in the receiving section. The ear dam member is positionable in between a first position for increasing an overall slope of the divider and a second position for decreasing the overall slope of the divider. The ear dam member is connected to the receiving section in the first position, and the ear dam member is connected to one of the hood and base member in the second position.

Combine harvesters are provided for use in harvesting seed corn from corn plants in fields. In connection therewith, a method for producing such seed corn from the corn plants, for use in growing subsequent corn plants, includes measuring a moisture content of corn kernels on ears of the corn plants in the field and removing, by one of the combine harvesters, the ears of corn from the corn plants when the moisture content satisfies a threshold moisture content. The method then includes separating the corn kernels from cobs of the ears of corn onboard the combine harvester and collecting the separated corn kernels for use as seed corn, whereby one or more subsequent corn plants can be grown from the collected corn kernels.