A baler configured to execute a baling cycle to form a bale of crop material, the baler including a gate configured to move between a closed position and an open position. The system includes an accumulator coupled to the baler and having a receiving area configured to receive the bale from the baler when the gate is in the open position, and an actuator configured to direct the bale received from the baler selectively toward a first accumulation area or a second accumulation area of the accumulator. The system also includes a hydraulic circuit operatively coupled to the actuator and configured to, in a first configuration, move the actuator toward the first accumulation area and, in a second configuration, move the actuator toward the second accumulation area. A hydraulic valve is moved during the baling cycle to alternate the hydraulic circuit between the first configuration and the second configuration.

Provided is a work vehicle capable of efficiently performing grass collecting work by decelerating a traveling machine body in a case where the size of a bale is large and a case where the pickup load of straw grass is large. The work vehicle includes a traveling machine body 1, a roll baler unit 2, a bale detection unit 31 configured to detect a size of the bale formed by the roll baler unit 2, a load detection unit 32 configured to detect a pickup load of straw grass in the roll baler unit 2, and a traveling control unit 17A capable of decelerating the traveling machine body 1 when a size of the bale is equal to or larger than a setting value B1 and when a pickup load is equal to or larger than a setting value L. A deceleration D2 is larger than a deceleration D1.

A baling machine includes an accumulator chamber at least partially defined by a housing. The baling machine includes an infeed assembly that is configured to deliver material to an inlet of the accumulator chamber. The baling machine includes a lower rake assembly that is positioned within the accumulator chamber and is operable to move material toward an outlet of the accumulator chamber. The baling machine includes an upper conveyor rake that is movable within the accumulator chamber. The upper conveyor rake has a first end, a second end, and a range of motion between a raised position and a lowered position. The second end of the upper conveyor rake has a greater range of motion than the first end. Through the majority of the range of motion of the upper conveyor rake, the first end is positioned closer to the lower rake assembly than the second end.

An agricultural baler system having a direction of travel and adapted to compile a windrow of crop into a bale, the agricultural baler system having a baler assembly coupled to the work machine and configured to consolidate crop from the underlying windrow into the bale, the baler assembly implementing a wrapping process to maintain the form of the bale and an eject process for ejecting the bale, and a windrow diverter selectively positionable between a divert position and a bypass position. Wherein, when the windrow diverter is in the divert position, the underlying windrow is repositioned as the baler assembly moves in the direction of travel.

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.

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 harvesting machine having a multiple stage compression system includes first and second compression systems. The first compression mechanism partially compresses the crop material in a compression chamber. The second compression system having first and second compartments each having at least one open end and positioned rearward of the compression chamber. The second compression system has a first position in which the first compartment is aligned with the compression chamber and the second compartment is operatively positioned with a second compression mechanism. The second compression system has a second position in which the second compartment is aligned with the compression chamber and the first compartment is operatively positioned with a second compression mechanism. The second compression system includes a binding system operatively associated with the second compression mechanism. At least one of the first and second compartments rotate between the first and second positions.

An agricultural harvesting machine having a multiple stage compression system includes first and second compression systems. The first compression system includes a first compression mechanism which partially compresses the crop material in a compression chamber. The second compression system includes first and second compartments each having at least one open end and positioned rearward of the compression chamber. The second compression system has a first position in which the second compartment is aligned with the compression chamber and the first compartment is operatively positioned with a second compression mechanism. The second compression system has a second position in which the second compartment is operatively positioned with a third compression mechanism and the first compartment is aligned with the compression chamber. The second compression system includes a binding system operatively associated with the second compression mechanism.

A bale forming device forms a bale in a bale forming chamber surrounded by a casing. A discharge gate actuator moves a discharge gate from a closed position into an opened position. The formed bale is ejected out of the casing and drops onto a ramp. A ramp sensor detects the bale dropping onto the ramp and triggers the discharge gate actuator to stop opening the discharge gate.

A continuous round baler forms a cylindrically-shaped bale by spiral, coiled layers created by a conical portion of a bale-forming chamber and protruded upwardly from a cylindrical portion of the bale-forming chamber. The bale is circumferentially supported by netting applied to the bale in the cylindrical portion. A rotary feed table receives crop from the field and feeds the crop into the conical portion. The bale forming process can be interrupted if an insufficient volume of crop is collected on the rotary feed table. The netting material is provided on short rolls to facilitate loading onto the machine. A cutoff mechanism is coupled to the growth of the bale from the cylindrical portion to sever the bale at a predetermined length with end surfaces that are perpendicular to the axis of the bale. A bale density mechanism supports the distal end of the bale as the bale protrudes upwardly.