An agricultural baler including a bale chamber; a feeder duct communicating with the bale chamber; and a feeder operable within the feeder duct to accumulate a charge of crop material therein and then stuff that accumulated charge into the bale chamber. The baler further includes a conveying channel and a conveyor operable in the conveying channel to convey the crop material along a bottom wall of the conveying channel toward the feeder duct. The bottom wall of the conveying channel is adapted to be moved away from the conveyor; and the lower end part of the bottom wall of the feeder duct is attached to the movable bottom wall of the conveying channel.

A feeding assembly for an agricultural vehicle includes: a pickup including a pickup reel carrying a plurality of tines; a rotor including a plurality of rotor fins disposed rearwardly from the pickup; a windguard assembly including a pair of movable support arms and a windguard coupled to the support arms, the windguard including a tube and a plurality of windguard tines coupled to the tube, the windguard being movable from a first position to a second position that is elevated relative to the first position; and a windguard retainer configured to engage the windguard when the windguard is in the second position and retain the windguard in the second position.

A conveying arrangement conveys loose material in a conveying direction, in particular agricultural material. Several knives of a cutting assembly are mounted below a cutting area guiding surface. The material is first conveyed along the cutting area guiding surface and afterwards along a further guiding surface. Both guiding surfaces are mechanically supported by a connecting assembly. A positioning mechanism can pivot the connecting assembly upwards and downwards. This pivotal movement causes both guiding surfaces to be moved upwards and downwards. The cutting area guiding surface together with the cutting assembly can be shifted laterally, i.e. perpendicular to the conveying direction, and is guided during this lateral movement.

A large square baler for performing a baling operation to form square bales includes a pickup unit for picking up crop lying on the ground, a cutter unit for cutting picked up crop into at least one predetermined cut length, a pre-compression chamber, a stuffer device, a bale chamber for forming a square bale from flakes of crop pre-compressed in the pre-compression chamber, and a tying system for binding the square bale. The stuffer device is configured to pre-compress the crop into the flakes in the pre-compression chamber and transport the flakes into the bale chamber. The cutter unit is controlled in dependence on a tying operation conducted by the tying system and on at least one parameter representing the square bale size.

A pre-cutter assembly includes at least one knife rotatable about a knife rotation axis between a retracted position and a deployed position, and an associated engagement arm rotatable about an arm rotation axis between a latch position securing the knife in the deployed position, and a release position allowing the knife to move into the retracted position. A magnet may be positioned for engagement with the engagement arm when the engagement arm is disposed in the latch position. The magnet is operable to apply a magnetic force to the engagement arm when engaged with the engagement arm to hold the engagement arm in the latch position thereby securing the knife in the deployed position. A cam shaft having a cam lobe may be rotated to selectively move the engagement arm between the release position and the latch position.

A pre-cutter assembly includes a first set and a second set of knives. A controller is coupled to a first actuator and a second actuator for moving the first set and the second set of knives between a retracted position and a deployed position respectively. The controller may determine a current baler operating parameter and a status of the first and second sets of knives. The controller may then define a desired positional setting for the first and second sets of knives based on the current baler operating parameter and the status of the first and second sets of knives. The controller may then communicate a control signal to the first and second actuators to control the first and second actuators to position the first and second sets of knives in the desired position setting for the first and second sets of knives.

A cutting assembly is described that comprises two oppositely facing sidewalls and two loading systems, each loading system comprising a transverse member that extends between and through the sidewalls, and two trays of knives. Rotation of a transverse member causes the associated tray of knives to move between a loaded and an unloaded position, wherein the loaded position the knives protrude into a crop collection channel of a harvester for the cutting of crop material.

A method for preventing or removing a plugging of a feeder duct of a baler. The baler includes a bale chamber including bottom wall in which an inlet opening is formed therein, and a feeder duct including a top wall and a bottom wall extending between a lower end and a upper end of the feeder duct, the top wall providing an upper boundary of the feeder duct and the bottom wall providing a lower boundary of the feeder duct. The method includes steps of increasing a distance between the top wall and the bottom wall of the feeder duct in at least a part of the feeder duct, while leaving an upper boundary provided by the top wall of the feeder duct and a lower boundary provided by the bottom wall of the feeder duct intact, and operating a feeder in the feeder duct.

A harvesting machine may include a main frame, a rotor assembly rotatably coupled to the main frame, a top frame movably attached to the main frame forming a passageway for crop material between the top frame and the rotor assembly, a bottom frame movably attached to the top frame, a plurality of knives movably attached to the top and bottom frames, and an actuator operatively connected to one of the top frame and the bottom frames. The plurality of knives extends through slots in the top frame. The top and bottom frames and the plurality of knives are in a raised position when the actuator is in a first position. The top and bottom frames and the plurality of knives are in a lowered position when the actuator is in a second position, which enlarges the passageway and partially retracts the knives through the slots in the top frame.

The disclosure relates to a harvester control system that allows for the operation and control of a bottom floor assembly by an operator of a harvester, such as a round baler. The harvester control system generally comprises at least one rotation sensor configured to measure the rotation angle of the bottom floor assembly during the harvesting process, a controller that receives information from the rotation sensor(s), and an operator interface configured to display warning information to the operator if the bottom floor assembly meets certain rotation and time parameters.