A stuffer assembly includes a stuffer chute and a stuffer for transferring crop material from the stuffer chute into a baling chamber. The stuffer includes a tine bar having a plurality of tines. Each tine is slidably connected to the tine bar to be linearly movable with respect to the tine bar between an extended position and a retracted position parallel to a radial direction of the tine bar. A method accordingly includes retracting a tine from the extended position into the retracted position in case of an overload.

A rotor assembly for an agricultural baler. The rotor assembly has a rotor shaft having a central portion and first and second end portions either side of the central portion. The rotor assembly further has a number of tine plates to be arranged axially along the rotor shaft, each of the tine plates having one or more tines. The tine plates are arranged such that there is an angular spacing between the tines of adjacent ones of the tine plates. A magnitude of the angular spacing is greater or smaller at the central portion than at the first and second end portions of the rotor shaft.

A rotor assembly for an agricultural baler. The rotor assembly has a rotor shaft having a central portion and first and second end portions either side of the central portion. The rotor assembly further has a number of tine plates to be arranged axially along the rotor shaft, each of the tine plates having one or more tines. The tine plates are arranged such that there is an angular spacing between the tines of adjacent ones of the tine plates. A magnitude of the angular spacing is greater or smaller at the central portion than at the first and second end portions of the rotor shaft.

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 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 method for determining parameters associated with bale charges formed within agricultural balers includes transmitting microwave signals through a charge of crop material located within a pre-compression chamber of an agricultural baler or into a wall of the pre-compression chamber. Additionally, the method includes determining at least one wave-related property associated with the microwave signals as transmitted through the charge of crop material or into the wall of the pre-compression chamber, and estimating a filling degree of at least a portion of the pre-compression chamber based at least in part on the at least one wave-related property associated with the microwave signals.

A method for determining parameters associated with bale charges formed within agricultural balers includes transmitting microwave signals through a charge of crop material located within a pre-compression chamber of an agricultural baler or into a wall of the pre-compression chamber. Additionally, the method includes determining at least one wave-related property associated with the microwave signals as transmitted through the charge of crop material or into the wall of the pre-compression chamber, and estimating a filling degree of at least a portion of the pre-compression chamber based at least in part on the at least one wave-related property associated with the microwave signals.

An agricultural baler includes a feeder duct communicating with a bale chamber for charges of crop material to be transferred into a bale chamber. The baler also includes a door that defines at least a portion of a bottom wall of the feeder duct. The door is movable between: (i) a door-open-position, in which an opening in the bottom wall is provided; and (ii) a door-closed-position in which the opening is closed. The baler further includes a pick-up device that is movable between: (i) a lowered-position in which it is operable to convey crop material into the feeder duct; and (ii) a raised-position in which it is spaced further away from the ground than in the lowered-position. The pick-up device is mechanically coupled to the door of the bottom wall such that movement of the pick-up device causes the door to move from the door-open-position to the door-closed-position.

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.

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.