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 including a bale case having a wall portion with an opening for introducing crop material; a plunger disposed moving in the bale case to compact the crop material into bales; a duct for transporting the crop material to the entrance opening; and a stuffer unit operably associated with the duct and including a fork assembly. The stuffer unit includes tines and a drive mechanism acting on the fork assembly. The drive mechanism includes a first drive member configured for a reciprocating motion along a path of movement; a second drive member configured for a reciprocating motion along the path of movement of the first drive member and operatively connected to the fork assembly; and a selectively operable coupling arrangement configured for selectively coupling the second drive member either to the first drive member or to a stationary part of the baler.

A baler for forming a bale of crop material includes a plurality of walls defining a bale chamber. A drive roller and a plurality of idler rollers are disposed in the bale chamber. At least one baling belt contacts the drive roller and the plurality of idler rollers. A bale engagement roller is rotatable about a bale engagement roller axis. The bale engagement roller is positioned to directly engage crop material in the bale chamber. An actuator is coupled to the bale engagement roller. The actuator translates the bale engagement roller in a direction perpendicular to the bale engagement roller axis.

An agricultural baler including a flywheel and a drivetrain for coupling the flywheel to a connector that is arranged to be connected to a power take-off (PTO) of a tractor. The drivetrain includes a decoupling mechanism for decoupling the flywheel from the connector in case of an overload. The decoupling mechanism includes a controllable member that is movable between an engaged state in which the flywheel is coupled to the connector and a disengaged state in which the flywheel is decoupled from the connector. The decoupling mechanism further includes a detector configured for detecting the overload. The detector is configured for providing an overload signal to the controllable member triggering the controllable member into the disengaged state.

An agricultural baler includes a baler chassis and a stuffer mechanism. The stuffer mechanism includes a fork and a motor. The fork is shiftably supported to move along a loading duct during each of a series of stuffing strokes. The fork is operable in a sweeping position, where the fork extends at least partly into the duct, to provide a full stuffing stroke by loading a charge of crop material from the loading duct into a baling chamber. The fork is shiftable by the motor from the sweeping position to a retracted position, where the fork is moved out of the duct. The fork is shiftable into the retracted position for at least part of a respective stuffing stroke where at least some of the charge of crop material in the loading duct is not loaded into the baling chamber.

A crop baler with a stuffer flywheel mass for baling a crop, the baler comprising: a supporting frame that can be moved across a field; a crop pick-up configured to pick up the crop from a ground of the field; a conveyor configured to convey the crop picked up by the crop pick-up; a pressing chamber having a stuffer configured to compress the crop conveyed into the pressing chamber by the conveyor into a form of a bale; and a drive for producing a reciprocating movement of the stuffer, the drive further comprising a flywheel mass with a variable moment of inertia.

A baling system operable to receive loose material, form the loose material into an individual charge, and compress the individual charge with one or more other charges to form a bale. The baling system includes a forming chamber and a plunger operable to move in a reciprocating manner within the forming chamber from a front-dead-center position in which a plunger face is furthest re) from the bale to a rear-dead-center position in which the plunger face contacts and compresses the bale. The system includes a feeder el component operable to pre-compress the loose material to form the individual charge and then move the individual charge into the forming chamber, the feeder component including a feeder chute having a feeder chute outlet connected to the forming chamber. The feeder component is operable to pre-compress the loose material into the individual charge and then move the individual charge into the forming chamber for compression by the plunger into the bale. The system includes a moisture sensor operable to determine a moisture content of the individual charge in the feeder chute, wherein at least a portion of the moisture sensor is positioned in the plunger face. In one embodiment, the moisture sensor is a near infra-red sensor operable to use near infra-red radiation to determine the moisture content.

An agricultural system includes a baler with a plunger and a sensor for sensing a plunger-related value; a vehicle including a power source operable to convey power to the plunger; and a CVT arranged to drive the plunger. In order to balance a fluctuating load of the plunger over the working cycle, an electronic control unit (ECU) is coupled to the sensor and to the CVT and is configured to receive the signal from the sensor and to cause the CVT to modify a gear ratio of the CVT based on the signal from the sensor and on a mathematical model defining a CVT gear ratio variation profile derived from an expected load applied by crop on the plunger over its operating cycle.

A square baler (30) includes a chassis (32), a plunger (36), and a variable speed transmission (42). The plunger assembly (36) includes a reciprocating plunger head (76) slidably mounted relative to the chassis (32) and operable to reciprocate within a chamber (54) to apply a compressive force against the material. The transmission (42) includes drive (86) and driven components (90) and an endless drive element (98) that drivingly interconnects the components. The driven component is drivingly connected to the plunger head. The drive component is operable to be driven by a prime mover at a drive input speed. At least one of the components has an adjustable operating diameter so that the driven component has a variable output speed.

Systems and methods for recompressing a round bale into a square bale. The system includes a bottom platen to receive the round bale and an upper platen rotatably coupled to the bottom platen. The upper platen is rotatable between a first position to receive the round bale between the bottom platen and the upper platen, and a second position in which the upper platen cooperates with the bottom platen to recompress the round bale into the square bale.