A bale ejection system includes a pawl having a planar structure. The pawl includes a mounting bore extending therethrough. A center of the mounting bore defines a rotation axis. The planar structure of the pawl includes a cam surface and a material engaging surface disposed opposite the cam surface. The cam surface and the material engaging surface extend away from the rotation axis, and converge to define a distal end that is spaced from the rotation axis. The material engaging surface defines a crop engaging tooth positioned between the rotation axis and the distal end of the planar structure. The crop engaging tooth and the distal end of the planar structure are operable to engage crop material of a bale when the planar structure is rotated into engagement with the bale for moving the bale along a longitudinal axis of a baler implement.

A woody biomass baler having a baling chamber adapted to receive woody biomass material and a compression system adapted to compact the material into a parallelepiped bale in the baling chamber, wherein the baling chamber has a front wall that acts as a reciprocating compression platen corresponding in dimensions to the width W and height H of the bale, opposing upper and lower walls corresponding in dimensions to the length L and either of the W and H of the bale, and opposing sidewalls corresponding in dimensions to the L and the other of the W and H of the bale, and wherein each chamber wall selected from among the upper wall, the lower wall, and each of the sidewalls can withstand a distributed force perpendicular to the selected chamber wall of between (0.11Pp psiAw) pounds and (0.3Pp psiAw) pounds, wherein 0.11 and 0.3 are Poisson's ratio values, Pp is the maximum pressure that the compression system can apply to woody biomass material in the chamber, and Aw is the area of the selected chamber wall expressed in square inches.

A bale ejection device for a baler for forming a bale includes a square bale chamber, a plunger having a packing face turned toward the bale accommodated within the chamber for movement, and at least one ejection ram selectively disposed at a position in which it projects beyond the packing face.

An accumulator is coupled to an agricultural baler and is configured to support a crop package exiting the baler. The accumulator includes an accumulator frame coupled to a wheel supported on a surface and a carriage pivotably coupled to the accumulator frame about a first rotational axis for movement between a first position and a second position. The carriage is configured to support the crop package when the carriage is in the first position. The carriage is also configured to discharge the crop package from the accumulator when the carriage is in the second position. The accumulator also includes an over-center linkage system coupled between the accumulator frame and the carriage. The over-center linkage system is configured to lock the carriage in the first position.

A baler system includes a baler controller includes a processor operable to execute a bale ejection algorithm to receive a command input to initiate a last bale ejection sequence. Upon receiving the command input, the baler controller automatically engages a knotter system to wrap and bind crop material currently disposed within a baling chamber to form a final bale. Upon forming the final bale, the baler controller automatically determines if a discharge location disposed proximate a discharge end of the baling chamber is clear of obstructions. Upon determining that the discharge end of the baling chamber is clear of obstructions, the baler controller automatically engages a bale ejection system to eject the final bale from the baling chamber and onto the discharge location.

A bale information system includes a baling machine configured to process a material into a bale, the baling machine including a sensor configured to measure a release of the bale from the baling machine, a global positioning system receiver in operable communication with the baling machine, and a data storage system operable to receive and store data from the global positioning system receiver.

A harvester and a crop accumulator combination. The harvester is configured to transfer a harvested crop to the crop accumulator. The crop accumulator comprises at least one actuator to selectively discharge the harvested crops onto a field. A GPS unit is configured with at least one virtual trip line. An ECU is in communication with the GPS unit. The ECU is configured to selectively command the actuator of the crop accumulator to discharge harvested crop onto the field when the ECU receives a signal from the GPS unit when at least one of the virtual trip line is being approached, the virtual trip line is being crossed, and the virtual trip line has been crossed.

The round baler includes a frame and a tailgate pivotally mounted to the frame via a tailgate pivot axis. The tailgate is movable along a path of travel range between an open position and a closed position. When in the open position, a bale can be discharged from the baler and, when in the closed position, a bale is prevented from being discharged from the baler. The baler also includes a sensor that has a sensor axis. This sensor is mounted to the baler with the sensor axis approximately coaxial with the tailgate pivot axis. An operating portion of the sensor is operatively directly movable with the tailgate. The sensor has a mechanical rotary range that is at least the travel range of the tailgate; and an electrical sensing range. The electrical sensing range is less than both the mechanical rotary range and the travel range of the tailgate.

A method of harvesting crop material includes capturing an image of a plurality of regions 28 of a field 50. The respective image of the regions 28 is analyzed to determine data related to constituent species of the crop material located within each of the regions 28. The data is associated with a region identifier 48 assigned to the respective one of the regions 28, and saved in a memory 42 of a computing device 30. The crop material in the field 50 is then harvested and formed into a bale. The harvested crop material formed into the bale is gathered from a subset 46 of the regions 28. A region identifier 48 of each of the regions 28 included in the subset 46 of the regions 28 is associated with the bale identifier 38, such that the data related to constituent species of the crop material included in the bale is associated with the bale and may be obtained by querying the computing device 30.

The present disclosure refers to a method of operating an agricultural system for forming and/or wrapping a bale of crop, the method comprising moving an agricultural apparatus over a field, the agricultural apparatus configured for at least one of forming and wrapping a bale of crop; preparing, by the agricultural apparatus, a bale of crop; observing surroundings in a vicinity of the agricultural apparatus by an observation system (14) while the agricultural apparatus is moving over the field; generating, by the observation system (14), observation data indicating a first bale dropped before to the field being located in the vicinity of the agricultural apparatus; processing the observation data by a data processing unit (15); determining, by the data processing unit (15), the first bale dropped before; and dropping the bale in response to the determining from the baling apparatus to the field. Further, an agricultural system is disclosed.