A method for operating a baler including an initial step of providing a cleaning system that includes a floor plate having a plurality of slots therein, at least one knife tray, at least one actuator operably connected to the at least one knife tray, and a controller operably connected to the at least one actuator. The method further includes the steps of determining whether the plurality of knives of the at least one knife tray is retracted, determining whether to conduct a knife tray cleanout procedure for cleaning the floor plate based upon at least one cleaning parameter, and conducting the knife tray cleanout procedure by actuating the at least one actuator for cycling the plurality of knives of the at least one knife tray for dislodging debris from the floor plate.

A roll assembly, which may be included in an agricultural baler, includes: a first roll having a first roll surface with a plurality of first extensions extending therefrom, the first extensions defining a first rotation path when rotated; and a second roll having a second roll surface with a plurality of second extensions extending therefrom, the second extensions defining a second rotation path when rotated. The first roll and the second roll are disposed adjacent to one another such that the first rotation path and the second rotation path partially overlap. At least one roll driver is coupled to at least one of the first roll or the second roll and configured to rotate the first roll and the second roll in the rotation direction such that the first extensions and the second extensions do not collide with each other during rotation of the first roll and the second roll.

A shredding and baling apparatus provided includes a shredding assembly operatively connected to a baling assembly via a conveyor. A rotatable drum with cutting teeth spirally arranged along the drum is preferably centered within a lower portion of an intake hopper for cutting through material as it is fed into the hopper. Fixed cutting teeth are preferably arranged in a row or rows along each of the longitudinal sidewalls of the hopper, adjacent the cutting drum. A touch screen display and computer may be used in combination with sensors to monitor and control the shredding and baling operation, and a hydraulic system is used to drive the components. The shredding and baling assembly is preferably designed in an industrial size to handle high volumes of material and may be driven or transported from one location to another.

A rotor assembly that has a support tube having a first diameter, at least one tooth coupled to the support tube, wherein the tooth rotates with the support tube to direct crop toward a chamber, and an undershot auger having an auger flight extending radially away from an auger core, the auger flight configured to cause the crop to flow towards a bale chamber region of the rotor assembly when rotation of the rotor assembly causes the crop to flow under the rotor assembly. Wherein, the auger core has a second diameter that is greater than the first diameter.

A feeding assembly includes: a frame; a pickup assembly carried by the frame and including a pickup roll, a plurality of tines carried by the pickup roll, and a pair of end flares, each of the end flares being disposed adjacent to a respective lateral end of the pickup roll and configured to redirect crop material picked up by the tines as the pickup roll rotates; and a windguard assembly including a windguard roll coupled to the frame by a pair of arm assemblies. Each of the arm assemblies includes: a first arm pivotably coupled to the frame; a second arm coupled to the first arm and the windguard roll; and an arm connector coupling the first arm to the second arm such that the second arm is laterally offset relative to the first arm and is positioned laterally between a pair of vertical planes defined by the end flares.

The present disclosure relates to a method for operating a round baler. The method comprises providing a nonstop baler type machine; feeding of crop into a prechamber and a main bale forming chamber; and providing, by a binding unit, a binding material to the main bale forming chamber for wrapping a bale formed in the main bale forming chamber, comprising, in a first mode of operation, providing a stretching apparatus in contact with the binding material, thereby, applying a compressive force to the binding material for stretching the binding material; and in a second mode of operation, providing the stretching apparatus free of contact with the binding material. Furthermore, a round baler is disclosed.

An agricultural implement system includes an agricultural implement and a controller. The agricultural implement includes: a chassis; a pickup carried by the chassis and configured to rotate and convey crop material; a movable windguard carried by the chassis; and a windguard displacement sensor associated with the windguard and configured to output windguard displacement signals corresponding to a displacement of the windguard relative to a zero position. The controller is configured to: determine a plug condition exists when the displacement of the windguard exceeds a defined displacement; and output at least one plug condition mitigation signal to adjust at least one parameter of the agricultural implement system and mitigate the plug condition responsively to determining the plug condition exists.

A pickup unit of an agricultural baler that includes a reel with a plurality of tines configured for lifting a crop material from a field, the reel is rotatable in an operating direction and a reverse direction, and a drive system configured for driving the reel. The drive system includes a gearbox configured for receiving motive power from a power take off (PTO) shaft, a drive shaft operably connected to the gearbox, and a first clutch connected to the drive shaft. The first clutch is configured for operably disconnecting motive power to the reel so that the reel is manually rotatable as the PTO shaft remains operably engaged with the gearbox.

A harvesting machine comprises a crop conveying channel with a movable bottom flap coupled to a hydraulic actuator controlling the position of the flap and a crop throughput sensing arrangement with a pressure sensor adapted to sense a hydraulic pressure in the hydraulic actuator.

The present disclosure refers to a method for operating a round baler. The method comprises providing a nonstop baler type machine; controlling a feeding mechanism for feeding of crop into a prechamber and a main bale forming chamber by a control system of the baler; in a feeding operation, feeding the crop through a first feeding channel into the prechamber; and switching the feeding operation by the control system, thereby, stopping feeding the crop into the prechamber and starting feeding the crop through a second feeding channel into a main bale forming chamber of the baler. The control system is configured to switch the feeding operation in response to a binding material parameter reaching a predetermined parameter value, the binding material provided for wrapping a bale formed in the main bale forming chamber. Furthermore, a round baler is disclosed.