An agricultural harvesting machine having a multiple stage compression system includes first and second compression systems. The first compression system includes a first compression mechanism which partially compresses the crop material in a compression chamber. The second compression system includes first and second compartments each having at least one open end and positioned rearward of the compression chamber. The second compression system has a first position in which the second compartment is aligned with the compression chamber and the first compartment is operatively positioned with a second compression mechanism. The second compression system has a second position in which the second compartment is operatively positioned with a third compression mechanism and the first compartment is aligned with the compression chamber. The second compression system includes a binding system operatively associated with the second compression mechanism.

A yield calculation system comprises a position sensor configured to detect a position. A baler comprises a bale chamber in which crop material is to be formed into a bale, a volume measurement sensor provided in the bale chamber and configured to measure a volume of the bale in the bale chamber, the volume corresponding to the position detected by the position sensor, and a moisture measurement sensor provided in the bale chamber and configured to measure a moisture amount in the bale, the moisture amount corresponding to the position detected by the position sensor. Circuitry is configured to calculate, based on the volume of the bale and the moisture amount corresponding to the position, a yield corresponding to the position by excluding the moisture amount from an amount of the bale.

A bale composition determination system comprising a baler configured to pick up crop material cut and lying on the ground in the form of a windrow and to form bales of the crop material. The system additionally includes one or more sensors configured to obtain electromagnetic reflectance information for the crop material. The system further includes a control system configured to receive the electromagnetic reflectance information for the crop material and to generate vegetation index values for the bales of crop material based on the electromagnetic reflectance information.

A bale identification assembly for use with an agricultural baler (18) includes a first supply roll mounted on the baler providing a binding material (52) used by the knotter system to bind the formed bale, the binding material (52) on the first supply roll comprising identification tags (62) at spaced intervals along the binding material. The bale identification assembly includes a second supply roll mounted on the baler (18) providing a binding material without identification tags, wherein the knotter system combines the binding material with identification tags (62) from the first supply roll with the binding material without identification tags from the second supply roll to bind the formed bale. The bale identification assembly includes a read module with one or more antennas configured to transmit interrogator signals and also receive authentication replies from the identification tags (62).

A bale identification assembly includes binding material used by a knotter system to bind a formed bale, the binding material including identification tags at spaced intervals along the binding material. A read module transmits interrogator signals and also receives authentication replies from the identification tags. A position sensor is used to predict passage of identification tags through the knotter mechanism and a bale length sensor provides a signal representing bale length. A controller receives signals from the bale length sensor and the position sensor and generates a signal to alter the length of the bale by causing an additional flake to be added to the bale by the plunger or the bale to be finished with fewer flakes to prevent the knotter system from tying a knot in the binding material such that the identification tag is positioned in a portion of the binding material used to form the knot.

A bale compression device for receiving and compressing a bale of material. The device includes a press configured to compress the bale of material to a required compressed dimension, a binding applicator configured to apply a plurality of bindings around the bale of material prior to the bale being compressed, and a connector for connecting ends of each of the bindings to form a plurality of complete loops around the perimeter of the bale so that the plurality of loops act to hold the bale in a compressed state. The binding applicator acts to withdraw excess binding as the press compresses the bale, prior to the connector connecting the ends of each of the bindings, such that the complete loops are formed when the bale reaches its required compressed dimension.

In one embodiment, an agricultural crop baler comprising: a supporting frame; a pressing chamber configured to receive a stuffer, the stuffer compressing the crop into the pressing chamber; and at least one positionally adjustable side wall forming part of the pressing chamber, the side wall being supported by the supporting frame and configured to vibrate upon movement of the stuffer.

A baler includes a frame and a bale chamber structure that is supported by the frame. The bale chamber structure includes a plurality of walls that cooperate to define a baling chamber that extends along a longitudinal axis. The plurality of walls shape different sides of the bale. At least one of the plurality of walls includes a first segment panel that is moveably attached to the frame and a second segment panel that is arranged in a downstream direction from the first segment panel with respect to the longitudinal axis. The second segment panel is moveably attached to the frame independent of the first segment panel.

A roll for an agricultural baler includes an interior tube and an exterior tube surrounding and connected to the interior tube. The exterior tube has an exterior surface and a plurality of loops extending from the exterior surface of the exterior tube.

An agricultural baler including a movable density door; a fluid cylinder for moving the density door and including a fluid chamber and a piston disposed in the fluid chamber having piston and rod sides, and a cylinder rod coupled to the piston on the rod side; a fluid supply circuit for suppling working fluid to the fluid cylinder, the fluid supply circuit selectively connectable to the fluid cylinder such that, in a first fluid supply mode, the fluid supply circuit is connected to the fluid cylinder to supply working fluid to only one side of the fluid chamber and that, in a second fluid supply mode, the fluid supply circuit is connected to the fluid cylinder to supply working fluid to both the piston and rod sides of the fluid chamber. A control unit configured to: receive density-data; determine a supply-mode-control-signal; and provide the supply-mode-control-signal to the fluid supply circuit.