A grass management system includes a first moisture-obtaining device to obtain a first moisture value of grass in a mowing operation performed by a mower, a position-detecting device to detect a mowing position of the mower, and a creation supporting circuit to support creation of an operation plan for a working machine based on the first moisture value and the mowing position, the working machine being configured to perform an operation relating to the grass already mowed. The grass management system includes a moisture map creating circuit to create a moisture map of an agricultural field based on the first moisture value and the mowing position. The creation supporting circuit is configured to display the moisture map that is created by the moisture map creating circuit in creating the operation plan.

An adjustable stalk stomper and/or chopper curtain assembly for a header of an agricultural harvester. The adjustable assembly comprises a control arm, at least one member connected to the control arm, wherein the at least one member is configured to knock down plant stalks and/or to shield the agricultural harvester from flying debris, and wherein the control arm is configured to provide for adjustment of the orientation of the at least one member relative to the ground and the header. An agricultural harvester header may include the above adjustable assembly and a frame having a toolbar. An agricultural harvester may include such header.

A residue vision system includes a harvesting machine configured to traverse a field and harvest an agricultural material, a residue distribution system carried by the harvesting machine and configured to distribute a residue of the agricultural material onto a first harvested area of the field, at least one camera coupled to the harvesting machine and configured to acquire an image of a second harvested area of the field, and an electronic control unit in communication with the at least one camera and the residue distribution system. The electronic control unit is configured to analyze the image acquired by the at least one camera, and in response to the analysis adjust the residue distribution system to adjust distribution of the residue onto the first harvested area of the field.

An orchard sanitation implement disposes of unharvested nuts which may otherwise be utilized as habitat and food for navel orangeworms. Unharvested nuts are lifted from the orchard floor and delivered to a storage bin of the implement. Once received within the storage bin, the unharvested nuts are separated from other orchard debris by a looping belt which allows unharvested nuts to fall through, but other orchard debris is conveyed outside of the storage bin for deposit either into a container or back to the orchard floor. The unharvested nuts fall through openings in the looping belt, through an outlet at the bottom of the storage bin and into a shredding unit attached to the outlet. The shredding unit shreds and pulverizes the unharvested nuts into a composition which is too small to be utilized by navel orangeworms for habitat or a source of food.

A system and computer-implemented method for sensing an amount of free water in cut crop material and automatically adjusting an operating parameter of a mower conditioner to optimize the amount of free water. A sensor located at the exit of a conditioning mechanism measures an actual free water content value of the material as it exits the conditioning mechanism, a processor compares the actual value to maximum and minimum values, and if the actual value is outside this range, automatically adjusts an operating parameter, such as a gap between pairs of conditioning rollers, a pressure exerted by the rollers, or a speed of the mower conditioner, to optimize the actual value. Another sensor may be located at the entrance of the conditioning mechanism. The processor may take into account an operator-selectable value weighting the actual free water content versus a dry down time when adjusting the operating parameter.

A forage harvester is configured to chop harvested material and includes at least one conditioning unit for conditioning the chopped harvested material. The conditioning unit may transfer from its active position (in which operatively connected with other working units) to its passive position (in which the conditioning unit is released from the operational connection). In the passive position, the condition unit may be removed from the entirety of the forage harvester. The forage harvester further includes at least two track drives arranged on opposing ends of a front axle of the forage harvester. The forage harvester includes a free cross-section positioned on a removal side of the forage harvester through which the conditioning unit, in its passive position, can be removed laterally from the rest of the forage harvester, as well as removed above the track drive assigned to the removal side.

Various types of lawnmowers are disclosed that include a cutter housing having a chamber wall and a discharge opening therein. A mulch gate can be provided with an interior scroll-shaped face and can be pivotably attached to the cutter housing so as to be movable between an opened gate position and a closed position. In the opened position, the mulch gate is positioned such that the discharge opening is opened to an exterior of the lawnmower to allow clippings to pass therethrough and out of the lawnmower. In the closed position the mulch gate closes the discharge opening to provide a mulch mode in which clippings remain in the cutter housing for added cutting by the lawnmower blade. When the mulch gate is in the closed gate position, the interior scroll-shaped face of the mulch gate can be substantially continuous with a wall interior surface of the chamber wall.

A sugarcane harvester includes an improved discharge assembly that receives sugarcane billets and discharges the billets into a storage vehicle that travels alongside the harvester. The discharge assembly includes an elevator and a conveyor. The elevator lifts the billets vertically about an elevator axis that is substantially perpendicular to the longitudinal axis of the harvester. The conveyor receives the billets from the elevator and moves the billets horizontally along a conveyor axis that is substantially perpendicular to both the elevator axis and the longitudinal axis of the harvester. The discharge assembly also comprises height adjustment mechanism for vertically raising or lowering the conveyor and lateral adjustment mechanism for laterally adjusting positions of the conveyor. The height adjustment mechanism and the lateral adjustment mechanism can be manually or automatically operated to shift the conveyor between a number of use positions and a transport/storage position.

A sugarcane harvester includes an improved discharge assembly that receives sugarcane billets and discharges the billets into a storage vehicle that travels alongside the harvester. The discharge assembly includes an elevator and a conveyor. The elevator lifts the billets vertically about an elevator axis that is substantially perpendicular to the longitudinal axis of the harvester. The conveyor receives the billets from the elevator and moves the billets horizontally along a conveyor axis that is substantially perpendicular to both the elevator axis and the longitudinal axis of the harvester. The discharge assembly also comprises height adjustment mechanism for vertically raising or lowering the conveyor and lateral adjustment mechanism for laterally adjusting positions of the conveyor. The height adjustment mechanism and the lateral adjustment mechanism can be manually or automatically operated to shift the conveyor between a number of use positions and a transport/storage position.

The invention relates to a shear bar (20), in particular for a forage harvester or another agricultural or silvicultural machine, having a carrier (21) that comprises a cutting region (30); a plurality of cutting elements (31) being set alongside one another in the cutting region (30); the cutting elements (31) comprising a partial edge and at least some of the partial edges forming a cutting edge (32) that is embodied to form, with a knife bar, a cutting engagement for the material to be shredded; the cutting edge (32) forming a transition between a cutting surface (32.1) that is constituted by the cutting elements (31) and extends transversely to the cutting direction, and an exposed surface (32.2) that extends substantially in a cutting direction and indirectly or directly adjoins the cutting edge (32). A shear bar of this kind can be configured to be break-resistant with little complexity in terms of parts and manufacture if provision is made that an infeed element (34), which is embodied as a sintered part made of hard material having an infeed bevel (34.6) profiled on in the sintering process, is provided on or in the row of cutting elements (31); the infeed bevel (34.6) being carried over indirectly or directly into the cutting edge (32); and the infeed bevel (34.6) being arranged at a tilt with respect to the cutting edge (32) in such a way that it is arranged with a setback with respect to the exposed surface (32.2) and toward the cutting surface (32.1).