A baling system comprising a high capacity baler, and an electronic display configured to display baling information to an operator of the baling high capacity baler. The baler additionally comprises a first bale-forming area in which a first series of first individual bales can be formed, and a second bale-forming area in which a second series of second individual bales can be formed. The baler further comprises one or more first sensors configured to sense one or more parameters related to at least one of the first bales, and one or more second sensors configured to sense one or more parameters related to at least one of the second bales. The electronic display is configured to simultaneously display data generated from at least one of the first sensors and at least one of the second sensors.

A baling system including a first bale-forming area configured to form a first series of first individual bales, and a second bale forming-area configured to from a second series of second individual bales. The baling system further includes a bale bundler configured to receive the first and second individual bales from the first and second bale forming-forming areas and to tie a group of at least six bales together to form a bale bundle.

A sensor assembly and method is described for determining the position of a reciprocating plunger of a baler. A first sensor may detect at least one location of a crank arm driving the plunger as the crank arm rotates. A second sensor may detect a rotation of a crank gear that drives the rotation of the crank arm. A controller may determine a position of the reciprocating plunger relative to a baling chamber based upon, at least in part, the detected crank arm location and the detected rotation of the crank gear.

A baling system comprising a first bale-forming area configured to form a first series of first individual bales, and a second bale forming-area configured to from a second series of second individual bales. The baling system additionally comprises a bale accumulator configured to receive the first and second individual bales from said first and second bale-forming areas and to manipulate the first and second individual bales into a group of four or more bales.

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.

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 including a pickup mechanism configured to pick up a single windrow of crop material off the ground. The baler additionally includes 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 includes one or more stuffer assemblies each configured to push crop generally upward through one of the stuffer chutes. The baler further includes 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 including a pickup mechanism configured to pick up crop material from a single windrow on the ground, and a rotor configured to receive crop material picked up by the pickup mechanism. The rotor includes a first toothed section, a second toothed section, and an interior auger flighted section located between the first toothed section and the section toothed section. The rotor is configured to separate crop material into two streams of crop material.

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 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.