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 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 method for determining parameters associated with bale charges formed within agricultural balers includes transmitting microwave signals through a charge of crop material located within a pre-compression chamber of an agricultural baler or into a wall of the pre-compression chamber. Additionally, the method includes determining at least one wave-related property associated with the microwave signals as transmitted through the charge of crop material or into the wall of the pre-compression chamber, and estimating a filling degree of at least a portion of the pre-compression chamber based at least in part on the at least one wave-related property associated with the microwave signals.

A method of harvesting a crop material includes gathering the crop material with a harvesting implement as the harvesting implement moves along an initial path through a field. A location and a value of a characteristic of the gathered crop material is sensed at a plurality of intervals. A set of estimated values of the characteristic throughout the field is generated based on the sensed location and characteristic of the crop material at each of interval. A value of the characteristic of the crop material ahead of the harvesting implement is predicted as the harvesting implement moves along a harvest path, based on the set of estimated values of the characteristic of the crop material throughout the field. A function of the harvesting implement may be controlled based on the predicted value of the characteristic ahead of the pick-up.

A method and system for monitoring a bale shape. The method includes receiving a series of bale images from a camera, identifying the bale in the bale images, determining at least one bale shape parameter of the identified bale, and providing an electronic signal representative of the bale shape parameter. The bale images include a view of at least an outlet of a bale chamber of an agricultural baler, of a bale being ejected from the outlet, and of a field travelled by the agricultural baler during the ejection of the bale. The at least one bale shape parameter of the identified bale is then determined based on at least one of the bale images. The identifying of the bale may, at least partly, be performed using trained neural networks and other artificial intelligence algorithms.

A hay baler includes a compression stage having a first major wall conveying device, a support surface, a first sidewall conveying device and a second sidewall conveying device which are arranged to form a compression chamber and driven at compatible speeds to propel hay toward a downstream end of the compression stage. The first and second major wall conveying devices are in spaced relation to each other. The first and second sidewall conveying devices are transversely oriented and form first and second side walls of the compression chamber and are angled so that the compression chamber tapers from an initial width at the upstream end to a smaller final width at the downstream end.

Method and device for tagging round bales during wrapping in plastic foil, using a stationary or mobile baler-wrapper. Each round bale is oriented with the circular end surfaces mainly vertically and layers of plastic foil is wrapped around the round bale by foil wrapping arms. At a point in time where at least one layer of plastic film remains to be wrapped, each round bale is tagged with an ID tag having an adhesive back-side surface, using a time controlled, pivotal tagging arm provided with a tag transferring member. The movement of said tagging arm is controlled by a computer, which synchronizes the movement of the tagging arm with the movement of the foil supplying arms. After tagging, at least one additional layer of plastic is wrapped around each round bale to protect the ID tag.

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.

A system and method for preparing a sample area of a bale in order to more accurately evaluate the plant material incorporated into the bale. A baler receives, compresses, shapes, and secures material into the bale. A cutter mechanism cuts a portion of the material in the bale into similarly-sized particles. A mixer mechanism mixes the particles into a homogenous aggregate. A compression mechanism compresses the homogenous aggregate into the bale. An NIR testing system receives and analyzes near-infrared radiation reflected by the homogenous aggregate, and generates evaluation data reflecting properties of the material. The cutter may include knives mounted in a compression chamber of the baler. The mixer may be a relief feature on a center rail, the compressor may be a projecting feature on the center rail, and an NIR sensor may be mounted to the center rail so as to press against the surface of the bale.