A conveying system for an agricultural harvester includes a leveling drum assembly configured to be positioned upstream of a belt configured to move agricultural product from an accumulator to a bale formation cavity of a baler. The leveling drum assembly is configured to rotate in an opposite direction relative to a direction of rotation of the belt, and the leveling drum assembly is configured to level a surface of the agricultural product before the surface of the agricultural product engages the belt. The leveling drum assembly includes a drum configured to rotate about a first axis of rotation. The leveling drum assembly includes a shaft disposed within the drum and configured to rotate about a second axis of rotation offset from the first axis of rotation. The leveling drum assembly also includes multiple tines pivotally coupled to the shaft and configured to extend through respective apertures in the drum.

A belt (1) with a first belt end (11) and a second belt end (12), both belt ends (11, 12) being connected together. The first belt end (11) has at least one first segment (13) and a second segment (14), and the second belt end (12) has at least one first segment (15) and a second segment (16). The first segment (13) of the first belt end (11) is connected to the first segment (15) of the second belt end (12) at least one connection element (17), and the second segment (14) of the first belt end (11) is connected to the second segment (16) of the second belt end (12) at least one other connection element (17). The first segment (13) of the first belt end (11) is offset in the longitudinal direction (X) in some sections relative to the second segment (14) of the first belt end (11), and the first segment (15) of the second belt end (12) is offset in the longitudinal direction (X) in some sections relative to the second segment (16) of the second belt end (12).

A belt (1) with a first belt end (11) and a second belt end (12), both belt ends (11, 12) being connected together. The first belt end (11) has at least one first segment (13) and a second segment (14), and the second belt end (12) has at least one first segment (15) and a second segment (16). The first segment (13) of the first belt end (11) is connected to the first segment (15) of the second belt end (12) at least one connection element (17), and the second segment (14) of the first belt end (11) is connected to the second segment (16) of the second belt end (12) at least one other connection element (17). The first segment (13) of the first belt end (11) is offset in the longitudinal direction (X) in some sections relative to the second segment (14) of the first belt end (11), and the first segment (15) of the second belt end (12) is offset in the longitudinal direction (X) in some sections relative to the second segment (16) of the second belt end (12).

The transmission unit for a round baler includes a drive part having a drive shaft, a press roller driven part coupled to the drive part which to at least indirectly drives a pressing roller to act on a crop material, a cutting rotor driven part which at least indirectly drives a cutting rotor to convey the crop material towards a pressing chamber, and a coupling mechanism which selectively couples and decouples the drive part and the cutting rotor driven part. The coupling mechanism has a coupling gearwheel which is non-rotatably connected to the drive shaft and which is adjustable axially with respect thereto. The first coupling gearwheel is selectively drivingly coupled to the cutting rotor driven part in a coupling position and is decoupled therefrom in a release position, and is drivingly coupled to the press roller driven part both in the coupling and in the release position.

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.

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.

The disclosure relates to a harvester capable of continuous bailing of crop material, particularly to a harvester comprising a crop supply chamber positioned in front of a bale chamber, capable of storing crop material during the wrapping of a bale of harvested crop material, and a deflection system, capable of allowing crop material to enter into the bale chamber. The crop supply chamber further comprises a supply inlet at the bottom of the crop supply chamber and a movable control plate positioned within the crop supply chamber.

The disclosure relates to a harvester capable of continuous bailing of crop material, particularly to a harvester comprising a crop supply chamber positioned in front of a bale chamber, capable of storing crop material during the wrapping of a bale of harvested crop material, and a deflection system, capable of allowing crop material to enter into the bale chamber. The crop supply chamber further comprises a supply inlet at the bottom of the crop supply chamber and a movable control plate positioned within the crop supply chamber.

A round baler is provided with a bale-forming chamber and boundary apparatus of the bale-forming chamber that can be moved into an open position for ejecting a completed bale. The boundary apparatus includes a pivoting part rotatable between a first position, a second position and a third position. The axial dimensions of the bale-forming chamber can be changed by at least one side wall that can be moved by an adjustment drive. The adjustment drive is configured such that the axial dimensions of the bale-forming chamber increases when the pivoting part rotates to the second position and then reduces when the pivoting part rotates to the third position.

A round baler is provided with a bale-forming chamber and boundary apparatus of the bale-forming chamber that can be moved into an open position for ejecting a completed bale. The boundary apparatus includes a pivoting part rotatable between a first position, a second position and a third position. The axial dimensions of the bale-forming chamber can be changed by at least one side wall that can be moved by an adjustment drive. The adjustment drive is configured such that the axial dimensions of the bale-forming chamber increases when the pivoting part rotates to the second position and then reduces when the pivoting part rotates to the third position.