A wrapping system includes: a material roll configured to hold a roll of wrapping material; a knife assembly comprising a movable knife that is configured to cut wrapping material that comes off the material roll; a sensor associated with the material roll and configured to output a drawn material signal; and a controller. The controller is configured to: receive the drawn material signal; determine a length of wrapping material that is drawn from the material roll; output a cut signal to the knife assembly when the drawn length of wrapping material reaches a defined length; determine a length of wrapping material that is drawn from the material roll after outputting the cut signal; and output an excessive wrap signal when the length of wrapping material drawn after outputting the cut signal exceeds a threshold length.

An agricultural crop baler (20) includes a baling chamber (44), a crop pickup (26), and an adjustable partition mechanism (28). The crop pickup (26) is upstream from the baling chamber (44) to collect severed crop material and direct a flow of crop material toward the baling chamber. The partition mechanism is located between the crop pickup and the baling chamber to control the flow of crop material from the crop pickup to the baling chamber. The partition mechanism (28) includes a wall assembly (68) that at least partly defines a crop passage (76) extending along a crop-flow direction between the crop pickup (26) and the baling chamber (44). The wall assembly (68) includes a shiftable wall (74a, b) that is shiftable transversely to the crop-flow direction to adjustably vary the crop passage and thereby the flow of crop material to the baling chamber (44).

An agricultural crop baler (20) includes a baling chamber (44), a crop pickup (26), and an adjustable partition mechanism (28). The crop pickup (26) is upstream from the baling chamber (44) to collect severed crop material and direct a flow of crop material toward the baling chamber. The partition mechanism is located between the crop pickup and the baling chamber to control the flow of crop material from the crop pickup to the baling chamber. The partition mechanism (28) includes a wall assembly (68) that at least partly defines a crop passage (76) extending along a crop-flow direction between the crop pickup (26) and the baling chamber (44). The wall assembly (68) includes a shiftable wall (74a, b) that is shiftable transversely to the crop-flow direction to adjustably vary the crop passage and thereby the flow of crop material to the baling chamber (44).

A shredding and baling apparatus provided includes a shredding assembly operatively connected to a baling assembly via a conveyor. A rotatable drum with cutting teeth spirally arranged along the drum is preferably centered within a lower portion of an intake hopper for cutting through material as it is fed into the hopper. Fixed cutting teeth are preferably arranged in a row or rows along each of the longitudinal sidewalls of the hopper, adjacent the cutting drum. A touch screen display and computer may be used in combination with sensors to monitor and control the shredding and baling operation, and a hydraulic system is used to drive the components. The shredding and baling assembly is preferably designed in an industrial size to handle high volumes of material and may be driven or transported from one location to another.

A shredding and baling apparatus provided includes a shredding assembly operatively connected to a baling assembly via a conveyor. A rotatable drum with cutting teeth spirally arranged along the drum is preferably centered within a lower portion of an intake hopper for cutting through material as it is fed into the hopper. Fixed cutting teeth are preferably arranged in a row or rows along each of the longitudinal sidewalls of the hopper, adjacent the cutting drum. A touch screen display and computer may be used in combination with sensors to monitor and control the shredding and baling operation, and a hydraulic system is used to drive the components. The shredding and baling assembly is preferably designed in an industrial size to handle high volumes of material and may be driven or transported from one location to another.

A crop baler implement includes a baling chamber sized to form crop material into a parallelepiped shape bale having longitudinal faces and transverse faces. The implement includes a carriage disposed rearward of the baling chamber. The carriage includes a tray positioned to receive the bale from the baling chamber in a first orientation, in which the longitudinal faces of the bale are parallel with a longitudinal frame axis. A longitudinal wrapping assembly may wrap the longitudinal faces of the bale when the bale is in the first orientation. The tray is rotatable relative to the carriage about a substantially vertical tray axis to move the bale from the first orientation to a second orientation, in which the transverse faces of the bale are parallel with the longitudinal frame axis. A transverse wrapping assembly may wrap the transverse faces of the bale when the bale is in the second orientation.

A method for assigning information to an identification tag on a bale includes receiving, compressing and shaping crop material into a plurality of formed bales. At least one sensor parameter for the formed bales is detected with at least one sensor. Each bale is wrapped with a binding material and an identification tag is attached to each of the formed bales. A bale ID is created for each of the formed bales. The identification tag on the bale for each bale is assigned to the bale ID. The operator selects to have either the sensor parameter for the tagged bale associated with the bale ID or have a semi-randomized code not containing the sensor parameter associated with the bale ID.

A method for forming a bale of crop material in an agricultural baler. The method includes rotating a baler power-take-off (PTO) shaft at a rotational speed, rotating a bale of crop material in a bale chamber, and sensing, by at least one sensor, at least one bale ejection condition. The at least one sensor is configured to provide at least one bale ejection condition value corresponding to the at least one sensed bale ejection condition. The method further includes receiving, by a controller, the at least one bale ejection condition value, and adjusting, by the controller, the rotational speed of the baler PTO shaft responsive to the at least one bale ejection condition value.

A cylindrical bale-wrapping apparatus includes a main frame having a vehicle mounting apparatus, a first sub-frame adjustably mounted on the main frame between a bale-loading position and a bale-wrapping position, and a second sub-frame adjustably mounted on the main frame between a transport position and a bale-wrapping position. A wrapping table adapted to rotate a cylindrical bale about a central axis is associated with the first sub-frame. A wrapping ring including at least one roll support adapted to rotate about the wrapping table is mounted on the second sub-frame. The second sub-frame has a bale-support element.

A baler for forming round bales includes a wrapping device for wrapping a pressed bale with a wrapping material, a pressing chamber where the pressed bale is formed, a guide apparatus for guiding wrapping material to the pressing chamber, and a guide means for guiding the wrapping material via a region from the wrapping device to the guide apparatus. The guide means is movable between a first position and a second position. In the first position, the guide means substantially bridges the region between the wrapping device and the guide apparatus. In the second position, the guide means at least partially opens up the region therebetween.