A drive arrangement for a harvesting header of a harvesting machine having a running gear on which a feeder housing is mounted. A front side of the feeder housing has a header mount that moves relative to the feeder housing and on which the harvesting header is detachably fastened. An automated coupling mechanism is provided to link a driven shaft from the harvesting machine to a drive shaft of the harvesting header as the header is connected to the harvesting machine. The drive connector connected with the header mount is movable relative thereto during the attachment of the harvesting header to axially align the driven shaft and drive shaft as the harvesting header approaches the feeder housing during the attachment to accommodate differing header drive shaft orientations.

A harvester or combine includes a folding corn head with a center section and folding wing sections. A folding row separator cover at the hinge location of the folding head sections folds to an angled position so that the folding action between the wings and the center section is not impaired. A single assembly actuates the folding of the row separator as well as locking and unlocking of the wing sections relative to the center frame section. A hydraulic cylinder actuates a main link that connects to the row separator cover and to a lock pin. Actuation of the hydraulic cylinder raises and lowers the cover and disengages and engages the locking pin.

A plant stalk stomper assembly is operable to be mounted relative to a toolbar of a row crop header for advancement over the ground in a forward travel direction. The stomper assembly includes a frame and an elongated stomper skid plate operable to engage the ground as the stomper assembly is advanced in the forward travel direction. The skid plate presents an attachment section along which the skid plate is mounted relative to the frame. At least part of the skid plate includes a unitary plate element that depends below the attachment section to present a lowermost ground-engaging margin. The unitary plate element includes a deformation region located between the attachment section and the ground-engaging margin, with the unitary plate element operable to bend along the deformation region in response to relative movement between the attachment section and the ground-engaging margin.

An arm assembly of an agricultural header includes a leaf spring configured to couple to a frame of the agricultural header. The arm assembly also includes an arm coupled to the leaf spring, in which the arm is configured to support a cutter bar assembly of the agricultural header. In addition, the arm assembly includes an actuator coupled to the arm and configured to couple to the frame of the agricultural header. The actuator is configured to urge the arm to move the cutter bar assembly upwardly relative to a soil surface, and the arm assembly is configured to be coupled to the frame only by the leaf spring and the actuator.

An arm assembly of an agricultural header includes a leaf spring configured to couple to a frame of the agricultural header. The arm assembly also includes an arm coupled to the leaf spring, in which the arm is configured to support a cutter bar assembly of the agricultural header. In addition, the arm assembly includes an actuator coupled to the arm and configured to couple to the frame of the agricultural header. The actuator is configured to urge the arm to move the cutter bar assembly upwardly relative to a soil surface, and the arm assembly is configured to be coupled to the frame only by the leaf spring and the actuator.

A yard maintenance device having a working assembly selectively rotatable based on operation of an engine of the device may include a belt drive system. The belt drive system may include at least one driven pulley operably coupled to the working assembly, a drive shaft operably coupled to the engine, a drive belt configured to selectively couple the drive shaft to the at least one driven pulley, a tension adjustment assembly, and a control unit. The tension adjustment assembly may be configured to operably couple to at least one component of the belt drive system to adjust a position thereof to modify tension of the drive belt. The control unit may be configured to provide electronic control of the tension adjustment assembly.

An agricultural harvester includes a harvester body, a header which is adapted for harvesting a crop, a feeder house which is adapted to receive said harvested crop from the header, a header adapter which is arranged between the header and the feeder house, which header adapter is adapted to allow the header to pivot relative to the feeder house about a horizontal pivot axis substantially parallel to the longitudinal axis of the header. A first actuator has a first end that is pivotably connected to the feeder house and a second end that is pivotably connected to the header adapter. A second actuator has a first end and a second end, which first end is pivotably connected to the harvester body. A coupling device is pivotably connected to the second end of the second actuator, the feeder house and the header adapter.

An agricultural system includes a controller comprising a memory and a processor, wherein the controller is configured to receive data from a first and second sensor, each of which are mounted on an agricultural header and configured to output data indicative of one-dimensional (1D) distances. The controller is configured to determine a first horizontal distance from the first sensor to a first plant stalk and a second horizontal distance from the second sensor to a second plant stalk based on the 1D distance data. The controller is also configured to control a steering system of the agricultural system to adjust a position of the agricultural header relative to the first and second plant stalks based on a difference between the first horizontal distance and the second horizontal distance.

A header for an agricultural harvester comprising a chassis and an auger having a tube extending in end to end relation with and rotatably supported by the chassis. The header further includes a drive mounted adjacent a mid-portion of the auger and operatively engaged with the mid-portion of the auger for driving rotation thereof. The header thus provides an auger which is driven at its mid-portion, thereby eliminating the hydraulic complexities of augers that are driven at their ends. In addition, when the auger tube is continuous, the mid-portion driven, continuous tube auger eliminates the crop dead spot that typically occurs when split augers are deployed.

A combine header comprising a header table with a knife extending along the front lower edge thereof. Seed pans are evenly spaced and extend forward from the front lower edge of the header table and slot is formed between them. At a middle portion of each slot a stripping plate slopes upward, outward, and rearward from a middle first point on a first one of the sidewalls forming the slot to an upper stripping edge of the stripping plate. The upper stripping edge is located above a top rear edge of a second one of the sidewalls forming the slot and aligned with same such that a vertically oriented stripping gap is formed between the upper stripping edge of the stripping plate and the top rear edge of the second one of the sidewalls. A rotating reel moves material from the seed pans rearward onto the header table.