A computer-implemented method and control system for gathering material is described. One or more vehicles may include an intake mechanism for material and a location-tracking system. A current orientation of the intake mechanism is identified based upon location information from the tracking system. A current orientation of the material is determined based upon historical location information for the material. A target orientation of the intake mechanisms is determined based upon the current orientation of the material. Movement of the intake mechanism is thus directed toward the determined target orientation.

A method and adapted electronic systems for determining a value representative for or an estimate of the load on a plunger of a baler for harvested agricultural material includes obtaining the speed of movement of a drive element for the plunger, followed by determining the estimate of or value representative for the load on the plunger based upon the obtained speed of movement of the drive element.

A system for determining an amount of and applying a preservative to an individual charge of crop material, wherein the charge is combined with other charges to form a bale. Loose crop material is collected and packed into a feeder chute in such a manner as to pre-compress the material to form the charge. A moisture content of the charge is measured by a sensor while the charge is still in the feeder chute. The charge is moved into a forming chamber, and a control unit determines a correct amount of a preservative to apply to the charge based on the moisture content. The correct amount of the preservative is applied to the charge either before or after the charge is incorporated into the bale. Thus, the system measures the moisture content of each charge, and measures the moisture content of the same charge to which the preservative is applied.

The present invention provides an improved mechanism for centering implements in agricultural fields by providing a laser guidance system with a laser attached to the implement. The laser may operate to emit a beam in order to produce a spot or beam onto the field which an equipment operator may visually target to improve steering of the implement. The laser may be centered on the implement, and the beam produced by the laser may be directed forward within a steering range of the implement and within a field of view of the equipment operator.

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.

Yield monitoring systems for round baling machines and methods that can provide weight estimations for round bales at the time of formation are described. Balers can include those that incorporate hydraulically actuated bale kicking or pushing assemblies as well as those that incorporate spring-loaded off ramps. Farm implements including baling machines and cotton module builders are encompassed. The system includes a sensor that can ascertain a physical parameter associated with ejection of a round bale from the farm implement. Physical parameters as may be ascertained can include pressures, velocities, accelerations, etc. associated with bale ejection.

A square baler including a baling chamber having a floor formed of spaced profiles, side walls and a top wall, and a density belt surrounding the baling chamber. The density belt is formed of a U-shaped frame having three beams welded to one another to define a floor beam for supporting the floor of the baling chamber and two upright beams for supporting the side walls of the baling chamber and a tensioning rod releasably secured to the upper ends of the two upright beams to prevent the upright beams from splaying apart.

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 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).

An agricultural baler including a baling chamber and a pre-compression chamber, the baling chamber including at least one movable wall. The agricultural baler further includes multiple sensors and a controller adapted for controlling operation of the agricultural baler based on inputs of the multiple sensors, wherein a first subset of the multiple sensors is related to a first feature and a second subset of the multiple sensors is related to a second feature. The controller is configured to control the operation of the agricultural baler in a first time period until the first feature is within a first predetermined range, and to control the operation of the agricultural baler in a subsequent time period, until the second feature is within a second predetermined range.