A bale drop detection mechanism for use with a baler having a rear aperture. The bale drop detection mechanism including a bale chute coupled to the rear aperture of the baler, where the bale chute includes an upper surface configured to support a bale ejected from the rear aperture thereon. The bale drop detection mechanism also including a bracket coupled to the rear aperture of the baler, a support member extending between and coupled to both the bale chute and the bracket, and a controller in operable communication with the bale chute and configured to detect a bale drop event based at least in part on the level of force being applied to the upper surface of the bale chute.

Systems and methods for controlling a configuration of a bale chute of a baler and, particularly, a square baler are disclosed. In some implementations, methods include determining a condition of a baler to determine whether a bale chute of the baler is to be extended or retracted.

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.

A bale wrap mechanism for use with a roll of wrap material, the bale wrap mechanism including a frame including a wrap chute formed from one or more perimeter walls, where the wrap chute defines a wrap axis extending longitudinally therethrough, and where the one or more perimeter walls at least partially define a passageway, a wrap arm coupled to the frame, the wrap arm having a mounting point movable with respect to the frame, and a shaft coupled to the mounting point and configured to support the roll of wrap material thereon, where the shaft is configured to travel along a wrap path during a wrapping process, where the wrap path surrounds the passageway, and where the wrap path is non-circular in shape.

An accumulator system for a bale recompression system that recompresses a round bale into a square bale includes a bottom platen to receive the round bale and a movable platen translatable relative to the bottom platen. The accumulator system includes a source of a bale diameter that indicates a diameter of the round bale to be received and a controller, having a processor, configured to: receive as input the bale diameter and output one or more control signals to move the movable platen based on the bale diameter.

An agricultural baler includes a main bale chamber, a bale ejection system and a partial bale ejection system. The partial bale ejection system, incorporated in the floor of the main bale chamber, is arranged to move and eject a rearward bale proximate to the outlet of the main bale chamber. The partial bale ejection system having an actuator for moving the rearward bale and at least one tine that is pushed into the rearward bale prior to the actuator pushing the rearward bale alone toward and out the outlet.

A square baler comprising a gear box configured to receive power from a rotating power source. The baler additionally comprises first and second drive shaft sections extending outwardly from generally opposite sides of the gear box. The gear box is configured to rotate said first and second drive shaft sections using power from the rotating power source. The baler further comprises first and second reciprocating plungers respectively coupled to the first and second drive shaft sections in a manner such that rotation of the first drive shaft section causes reciprocation of the first plunger and rotation of the second drive shaft section causes reciprocation of the second plunger.

A high capacity square baler comprising a pickup mechanism configured to pick up a single windrow of crop material off the ground. The baler additionally comprises one or more stuffer chutes each configured to receive at least a portion of the crop material picked up by the pickup mechanism. The baler additionally comprises one or more stuffer assemblies each configured to push crop generally upward through one of the stuffer chutes. The baler further comprises a plurality of separate bale-forming chambers each configured to receive crop material from one or more of the stuffer chutes and to form a bale of crop material therein.

A square baler comprising a first bale-forming area in which are formed a first series of first individual bales, and a second bale-forming area in which are formed a second series of second individual bales. The square baler additionally comprises a singulator configured to receive the first and second individual bales from the first and second bale-forming areas and to form a single row of the first and second individual bales.

A high capacity square baler comprising a pickup mechanism configured to pick up a single windrow of crop material off the ground. The baler additionally comprising one or more stuffer chutes each configured to receive at least a portion of the crop material picked up by the pickup mechanism. The baler additionally comprising one or more stuffer assemblies each configured to push crop material generally upward through one or more of the stuffer chutes. The baler additionally comprising a plurality of bale-forming chambers each configured to receive crop material from one or more of the stuffer chutes. The baler further comprising a plurality of knotter assemblies each associated with one of the bales forming chambers and each configured to wrap and tie securement lines around each formed bale. The knotter assemblies are configured to operate independently of one another, such that formed bales can be tied at different times.