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 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.

An agricultural baler towable by a vehicle that includes a frame and a baler hydraulic system. The baler hydraulic system includes a plurality of hydraulically operated subsystems, a plurality of hydraulic subsystem lines being fluidly connected to the plurality of hydraulically operated subsystems, and a hydraulic manifold fluidly connected to the plurality of hydraulic subsystem lines and configured for connecting to the vehicle hydraulic system. The agricultural baler also includes an electrical processing circuit operably connected to the hydraulic manifold and configured for switching the hydraulic manifold for connecting at least one hydraulic subsystem line of the plurality of hydraulic subsystem lines to the vehicle hydraulic system.

A drive system for an agricultural baler that includes a power take off (PTO) shaft configured for being operably connected in between an agricultural vehicle and the agricultural baler and for supplying motive power to the agricultural baler, a gearbox configured for being mounted on the agricultural baler and connected to the PTO shaft for receiving motive power from the PTO shaft, a pickup drive shaft operably connected to the gearbox and configured for being operably connected to a reel of a pickup unit of the agricultural baler, at least one sensor associated with the pickup drive shaft and configured for sensing a rotational movement of the pickup drive shaft, and an electrical processing circuit operably connected to the at least one sensor. The electrical processing circuit is configured for disconnecting motive power to the reel.

A method of controlling a tractor/baler combination is disclosed including the steps of: (i) advancing a tractor/baler combination through a swath or windrow of a harvested crop material with a tractor PTO operating at a generally constant speed to power a drive of a baling chamber of the baler and the baler operating to pick up harvested crop material; (ii) during step (i) assessing the flowrate of the harvested crop material in the baler and the torque of the baling chamber drive (iii) comparing the assessed flowrate with an optimal flowrate and the torque of the baler chamber drive with an optimal baler chamber drive; and (iv) if the assessed flowrate differs from the optimal flowrate by more than a predetermined amount or the assessed torque of the baler chamber drive differs from the optimal torque by more than a predetermined amount, changing the speed of advancement of the tractor/baler combination, and hence changing the flowrate of biological matter in the baler and the torque of the baler chamber drive.

A round baler includes a housing which has a housing part and an ejection flap which is pivotably mounted on this housing part about a bearing axis, and drivable pressing means which are allocated to the housing part and the ejection flap and which define a pressing chamber on the peripheral side, wherein the ejection flap is adjustable by means of a first adjusting apparatus such that when the ejection flap is opened an ejection opening is able to be formed between the housing part and the ejection flap and a dimension of the ejection flap is adjustable. The housing part comprises a retaining roller. The retaining roller is arranged so as to be adjustable between a resting position and a working position in which the retaining roller adopts a position disposed within the ejection opening.

A self-adaptive control system comprises a feeding device, a rotary coder, a displacement sensor, a hydraulic regulation system and a controller, wherein, the input end of the controller is electrically connected with the rotary coder, the displacement sensor, a first oil pressure sensor and a second oil pressure sensor respectively, and the output end of the controller is electrically connected with a solenoid directional valve via an interlocking controller; the controller takes the bearing force of piston rods and the rotation speed and the rotation speed change rate of a feeding knife roller as input variables and takes the positions of the piston rods as an output variable, to establish a fuzzy control model of the feeding mouth opening of the feeding device, the extension and retraction of the piston rods in a left oil cylinder and a right oil cylinder under hydraulic driving are regulated actively by controlling a three-position four-way solenoid directional valve, and thereby self-adaptive control of the feeding mouth opening is achieved.

An agricultural baler includes: a chassis; a plurality of wheels carried by the chassis; at least one electric wheel motor coupled to at least one of the plurality of wheels and configured to drive the at least one coupled wheel; an apron assembly including a plurality of chains driven by a plurality of rolls and configured to form a bale, the plurality of rolls including a starter roll; an electric drive motor coupled to the starter roll and configured to drive the starter roll; and an electrical power system carried by the chassis and having at least one battery electrically coupled to the at least one electric wheel motor and the electric drive motor.

A press for producing bales of forage and the like includes a supporting structure provided with wheels, the supporting structure being adapted to support rollers and a collection and feeding device, at least one roller of the set of rollers being actuated by a hydraulic motor, the at least one hydraulic motor being actuated by at least one hydraulic pump.

An electrohydraulic system for a work machine includes a pump, a motor fluidly coupled to the pump, a subassembly driven by the motor, and a rate-control valve fluidly coupled to the pump and the motor. The rate-control valve is movable through a range of positions. A present speed of the motor is proportional to a present position of the rate-control valve. The present position of the rate-control valve is adjustable by varying a current supplied to the rate-control valve. The supply of current to the rate-control valve is adjusted based on the difference between the present speed of the motor and a target speed of the motor.