A crop head for a harvester includes a folding frame having a first frame portion and a second frame portion configured to be folded in a transport state and unfolded in a harvesting state. The first and second frame portions are lockable with respect to each other to inhibit folding and unlockable with respect to each other to allow folding. A plurality of crop dividers is supported by the first frame portion. The plurality of crop dividers includes at least one movable crop divider that is movable with respect to the first frame portion. The crop head also includes a cylinder and a piston movable with respect to the cylinder. The piston is operable to move the movable crop divider between the first and second positions and is configured to directly engage the first and second frame portions to lock the first and second frame portions with respect to each other.

Gathering chains for row crop harvester heads which improve yield by minimizing the loss of kernels that may prematurely break loose and be lost to the ground. The gathering chains include continuous loops with a plurality of lateral extension segments which provide a substantially continuous conveying surface extending substantially across the width of the slot defining the path of travel of the row crop entering the row unit.

Described herein are methods and harvesters for adjusting settings of a harvester. In one embodiment, a computer Implemented method includes capturing, with at least one image capture device that is located on the harvester, images of a field view of an unharvested region to be harvested, analyzing the captured images to determine crop information for a crop of a harvested region that is adjacent to the unharvested region, and adjusting settings or operating parameters of the harvester for the unharvested region based on the crop information for the crop of the harvested region.

A header for harvesting stalk-like plants includes a number of gatherer assemblies arranged side by side for cutting off and conveying plants to a picking device arranged downstream of the gatherer assemblies. The picking device extends transversely to a direction of travel over the entire working width of at least one half of the header and includes a picking gap and stalk roll below the picking gap to separate fruits from the plants and to deliver them for a separate utilization.

A harvest head having a device to remove grains from plants to be harvested and a device to transfer harvested grains to a feeder and to a discharge tube. The harvest head having a support structure; a threshing comb; a first conveyor belt; a second conveyor belt, the threshing comb transfers the grains into the first and the second conveyor belts. The first and the second conveyor belts are convergent. A transverse conveyor belt is located between the first conveyor belt and the second conveyor belt. A reinforcement arranged on the back and the front cover and projecting out of the harvest head. The first and the second convergent conveyor belts carry the grain to the transverse conveyor belt, the transverse conveyor belt introduce the grains into a feeder that ends in a discharge tube. The convergent conveyor belts and the transverse conveyor belt are bands made of composite resins.

A system and method for automatic row alignment driving by a harvester when harvesting above-ground crops includes an elastic row sensing module, a processing module, a controlling module, and a steering module. The elastic row sensing module is disposed on a front grain thresher/grain isolator of the harvester, collecting data as to physical contact with the crop. The elastic row sensing module includes a deformable elastomer in contact with the high stem crop, the sensor detects and reports deformation of the elastomer. The processing module determines current alignment state of the harvester and the controlling module determines any corrective steering signal for the harvester. The steering module controls steering direction.

A system and method for automatic row alignment driving by a harvester when harvesting above-ground crops includes an elastic row sensing module, a processing module, a controlling module, and a steering module. The elastic row sensing module is disposed on a front grain thresher/grain isolator of the harvester, collecting data as to physical contact with the crop. The elastic row sensing module includes a deformable elastomer in contact with the high stem crop, the sensor detects and reports deformation of the elastomer. The processing module determines current alignment state of the harvester and the controlling module determines any corrective steering signal for the harvester. The steering module controls steering direction.

A stomping shoe assembly for an agricultural harvester header including a stomping shoe having a substantially planar proximal end for connecting to an agricultural harvester header, and a curved distal end for engaging crop. The assembly further includes a stalk cutter having an elongated body mounted to the stomping shoe and extending from the stomping shoe from the curved distal end to the substantially planar proximal end. Also provided is an agricultural harvester header including the stomping shoe assembly.

An image capture device captures an image of crop after it has been processed by a kernel processing unit on a forage harvester. A size distribution indicative of the distribution of kernel fragment sizes in the harvested crop is identified from the image captured by the image capture device. A control system generates control signals to control a speed differential in the speed of rotation of kernel processing rollers based on the size distribution. Control signals can also be generated to control a size of a gap between the kernel processing rollers.

An image capture device captures an image of crop after it has been processed by a kernel processing unit on a forage harvester. A size distribution indicative of the distribution of kernel fragment sizes in the harvested crop is identified from the image captured by the image capture device. A control system generates control signals to control a speed differential in the speed of rotation of kernel processing rollers based on the size distribution. Control signals can also be generated to control a size of a gap between the kernel processing rollers.