A first threshing section 15 and a second threshing section 16 are provided. The first threshing section 15 includes a first threshing drum 17 that rotates about a left-right-oriented axis, and the second threshing section 16 includes a second threshing drum 28 that rotates about a body front-rear-oriented axis. The second threshing drum 28 includes a rotary support shaft 29 extending along a front-rear direction, a plurality of rod-shaped frame bodies 30 that are arranged side by side extending along the front-rear direction and at and interval in the peripheral direction, radially outward of the rotary support shaft 29, and threshing teeth 31 attached to the frame bodies 30.

An agricultural harvester includes a threshing assembly configured to thresh crop material received from a feeder of the agricultural harvester. The threshing assembly, in turn, includes a concave and a rotor positioned relative to the concave such that a gap is defined between the concave and the rotor. Furthermore, the agricultural harvester includes an actuator configured to move the concave relative to the rotor to adjust a size of the gap. Additionally, the agricultural harvester includes a tailings assembly configured to receive incompletely threshed crop material that has passed through the concave. Moreover, the agricultural harvester includes an imaging device configured to capture image data depicting the incompletely threshed crop material present within the tailings assembly and a computing system communicatively coupled to the imaging device. As such, the computing system is configured to determine an amount of the incompletely threshed crop material present within the tailings assembly based on the captured image data. In addition, the computing system is configured to control an operation of the actuator based on the determined amount of the incompletely threshed crop material present within the tailings assembly.

An agricultural harvester includes a threshing assembly configured to thresh crop material received from a feeder of the agricultural harvester. The threshing assembly, in turn, includes a concave and a rotor positioned relative to the concave such that a gap is defined between the concave and the rotor. Furthermore, the agricultural harvester includes an actuator configured to move the concave relative to the rotor to adjust a size of the gap. Additionally, the agricultural harvester includes a tailings assembly configured to receive incompletely threshed crop material that has passed through the concave. Moreover, the agricultural harvester includes an imaging device configured to capture image data depicting the incompletely threshed crop material present within the tailings assembly and a computing system communicatively coupled to the imaging device. As such, the computing system is configured to determine an amount of the incompletely threshed crop material present within the tailings assembly based on the captured image data. In addition, the computing system is configured to control an operation of the actuator based on the determined amount of the incompletely threshed crop material present within the tailings assembly.

A system for controlling the aggressiveness of a tailings processor that re-threshes tailings received from the grain cleaning system in an agricultural harvester is provided with at least one imaging device to image a grain sample. At least a portion of the grain sample has at least once passed through the tailings processor. A controller is connected to the imaging device and to an arrangement to automatically adjust the aggressiveness of the tailings processor. The controller is configured to automatically adjust the aggressiveness of the tailings processor using the arrangement, based on based on the level of broken grain and/or unthreshed grain determined from the image from the at least one imaging device by comparing the level of broken grain and/or unthreshed grain to the desired level.

A system for controlling the aggressiveness of a tailings processor that re-threshes tailings received from the grain cleaning system in an agricultural harvester is provided with at least one imaging device to image a grain sample. At least a portion of the grain sample has at least once passed through the tailings processor. A controller is connected to the imaging device and to an arrangement to automatically adjust the aggressiveness of the tailings processor. The controller is configured to automatically adjust the aggressiveness of the tailings processor using the arrangement, based on based on the level of broken grain and/or unthreshed grain determined from the image from the at least one imaging device by comparing the level of broken grain and/or unthreshed grain to the desired level.

A driver assistance system for a combine harvester that has a processing stage with an input for a crop flow, a first output for a useful flow and has abundant threshed grains, and a second output for a residual flow with scarce grains. At least one operating parameter of the processing stage is adjustable. The driver assistance system has an actuatable rethreshing device arranged at the second output of the processing stage, a residual grain sensor for detecting a proportion of threshed out grain in the residual flow downstream of the rethreshing device, and an evaluating device that turns the rethreshing device on and off, compares the proportions of threshed out grains in the residual flow when the rethreshing device is turned on and when the rethreshing device is turned off, and to adapt the at least one operating parameter of the processing stage based on the comparison.

A tailings return system for use in a combine harvester includes a tailings conveyor having an upper part and a lower part. The upper part is hingedly connected to the lower part, allowing the upper part to be folded back against the lower part to create an open space in the combine harvester, facilitating access to other components within the combine harvester.

A threshing apparatus 1 includes a threshing unit 41 that has a receiving net 23 and threshes crops, and a sorting unit 42 that is provided below the threshing unit 41 and sorts grain from a threshed product that has leaked from the receiving net 23. The sorting unit 42 includes a sorter 24 that sorts grain as a sorted product from the threshed product, a first product collector 26 that collects the sorted product as a first product, a second product collector 27 that collects, as a second product, the threshed product that was not sorted as the sorted product, a second product returner 32 that returns the second product collected by the second product collector 27 to the sorter 24, and a return amount detector 71 that detects the return amount of the second product to be returned to the sorter 24.

A threshing apparatus 1 includes a threshing unit 41 that has a receiving net 23 and threshes crops, and a sorting unit 42 that is provided below the threshing unit 41 and sorts grain from a threshed product that has leaked from the receiving net 23. The sorting unit 42 includes a sorter 24 that sorts grain as a sorted product from the threshed product, a first product collector 26 that collects the sorted product as a first product, a second product collector 27 that collects, as a second product, the threshed product that was not sorted as the sorted product, a second product returner 32 that returns the second product collected by the second product collector 27 to the sorter 24, and a return amount detector 71 that detects the return amount of the second product to be returned to the sorter 24.

A system for controlling the aggressiveness of a tailings processor that re-threshes tailings received from the grain cleaning system in an agricultural harvester is provided with at least one imaging device to image a grain sample. At least a portion of the grain sample has at least once passed through the tailings processor. A controller is connected to the imaging device and to an arrangement to automatically adjust the aggressiveness of the tailings processor. The controller is configured to automatically adjust the aggressiveness of the tailings processor using the arrangement, based on information provided by the at least one imaging device.