An agricultural harvester includes a chassis and a residue handling system carried by the chassis. The residue handling system includes a set of rotating knives disposed in a housing, a first set of counter-knives, and a residue pivoting platform and/or a second set of counter-knives. Crop residue travels through the system in a residue flow direction. The first set of counter-knives are configured to enter the housing proximate to the set of rotating knives. The residue pivoting platform is positioned proximate to the first set of counter-knives in an upstream direction relative to the crop residue flow direction. The second set of counter-knives are configured to enter the housing proximate to the set of rotating knives. The second set of counter-knives are in a downstream direction relative to the crop residue flow from at least one of the residue pivoting platform and the first set of counter-knives.

A yield monitoring system is provided for an agricultural harvester. The yield monitoring system has an in-cab display and at least one configurable user defined window operable to display at least two previously collected parameters simultaneously and comparatively in graphical format. The at least two previously collected parameters include previously collected data from at least one yield monitoring sensor or vehicle sensor. The in-cab display may have a menu allowing the choice of paired data sources to be viewed simultaneously and comparatively. Data sources may include quantity of crop yielded, moisture content of crop yielded, rate of flow of crop through the agricultural harvester, protein content of crop yielded, ground speed, speed of operation of the grain elevator, and height of the header above the ground.

A method for analyzing the composition of a grain-MOG mixture comprising a kernel fraction and an MOG-fraction. The method includes steps of receiving a grain-MOG mixture, at a thermal excitation location, subjecting a sample volume of the grain-MOG mixture to a thermal excitation using a thermal excitator, generating a thermal image at an imaging location of at least a surface of the sample volume of the grain-MOG mixture that has been subjected to the thermal excitation, processing the thermal image and therewith obtaining data representing the temperature distribution over the thermal image, and relating the temperature distribution to the share of the kernel fraction in the grain-MOG mixture. A device for analyzing the composition of a grain-MOG mixture comprising a kernel fraction and an MOG-fraction is also provided.

A method for analyzing the composition of a grain-MOG mixture comprising a kernel fraction and an MOG-fraction. The method includes steps of receiving a grain-MOG mixture, at a thermal excitation location, subjecting a sample volume of the grain-MOG mixture to a thermal excitation using a thermal excitator, generating a thermal image at an imaging location of at least a surface of the sample volume of the grain-MOG mixture that has been subjected to the thermal excitation, processing the thermal image and therewith obtaining data representing the temperature distribution over the thermal image, and relating the temperature distribution to the share of the kernel fraction in the grain-MOG mixture. A device for analyzing the composition of a grain-MOG mixture comprising a kernel fraction and an MOG-fraction is also provided.

A sieve arrangement for an agricultural combine harvester includes a sieve frame for carrying a sieve, a side shaker arm, and a plurality of elongate structural members. The sieve frame includes a first side frame member and a second side frame member. The side shaker arm is connected with the first side frame member. Each structural member has a first end connected to the side shaker arm, and a second end connected with the second side frame member.

An agricultural harvester includes a grain processing section having a sieve assembly. The sieve assembly is connected to mechanism for producing a side to side oscillation by a single cast structural link having an input through slotted openings to the drive mechanism to accommodate misalignment. The link has vertical and horizontal flanges connected to a main body for interconnection between the right and left frames and structural supports interconnecting the right and left frames. The main body of the link extends through a slot in a rubber wall to accommodate the movement and seal against loss of grain.

An agricultural harvester includes a grain processing section having a sieve. The sieve is driven in fore and aft oscillation while permitting side to side movement by a pair of cast members interconnected each having three mounting points. Two of the mounting points of the members are interconnected by flexible rubber bushings and the third mounting point of one of the members receives fore and aft oscillating movement and the third mounting point on the second of the members pivotally interconnects to the sieve to drive it into fore and aft oscillation while permitting side to side movement.

A harvested material receptacle for a harvester. The harvested material receptacle includes a hopper that is open at the top with a substantially polygonal opening cross-section and extension elements arranged in pairs opposite each other. The extension elements are each pivotably articulated about a substantially horizontally running pivot shaft at the edge of an opening of the hopper to transition the extension elements from a substantially closed transport position into an open receiving position and vice versa, wherein the extension elements that are opposite one another lie sandwich-like on each other when in their transport position.

A harvested material receptacle for a harvester. The harvested material receptacle includes a hopper that is open at the top with a substantially polygonal opening cross-section and extension elements arranged in pairs opposite each other. The extension elements are each pivotably articulated about a substantially horizontally running pivot shaft at the edge of an opening of the hopper to transition the extension elements from a substantially closed transport position into an open receiving position and vice versa, wherein the extension elements that are opposite one another lie sandwich-like on each other when in their transport position.

A harvested material tank of a harvester is disclosed. The harvested material tank comprises a tank expansion formed from a plurality of movable elements. At least one of the plurality of movable elements includes at least one access flap that, when in an open position, offers access for a user to the interior of the harvested material tank.