A baffle float system for a baler is provided. The baffle float system includes a pair of first pivot arms configured to pivotally couple to a frame of the baler and to a cross-member. The first pivot arms pivot about a first pivot axis. The baffle float system includes a baffle coupled to the cross-member. The baffle float system includes a pair of second pivot arms having a first end coupled to the cross-member and a second end. The baffle float system includes a compressor rack coupled to the second end of each of the second pivot arms such that the compressor rack pivots relative to the second end along a second pivot axis. The second pivot axis is different than the first pivot axis. The baffle float system includes at least one biasing member coupled to the compressor rack so as to be offset from the second pivot axis.

A baffle float system for a baler is provided. The baffle float system includes a pair of first pivot arms configured to pivotally couple to a frame of the baler and to a cross-member. The first pivot arms pivot about a first pivot axis. The baffle float system includes a baffle coupled to the cross-member. The baffle float system includes a pair of second pivot arms having a first end coupled to the cross-member and a second end. The baffle float system includes a compressor rack coupled to the second end of each of the second pivot arms such that the compressor rack pivots relative to the second end along a second pivot axis. The second pivot axis is different than the first pivot axis. The baffle float system includes at least one biasing member coupled to the compressor rack so as to be offset from the second pivot axis.

A rotor feeder unit for an agricultural baler. The rotor feeder unit includes a rotor feeder carrying a set of tines, a rotor feeder unit bottom distant from the rotor feeder forming a lower boundary of a conveying channel through the rotor feeder unit, and scrapers placed in conveying direction behind the rotor feeder. The rotor feeder is rotatable about an axis of rotation. The scrapers extend in between the tines and have a leading face cooperating with the tines. The rotor feeder unit also includes a scraper position adjusting arrangement adapted for displacement of the leading face of the scrapers relative to the rotor feeder unit bottom. The scraper position adjusting arrangement is further adapted for rotating the scrapers about the axis of rotation of the rotor feeder for angularly displacing the leading face of the scrapers relative to the rotor feeder unit bottom.

An agricultural baler including a bale chamber; a feeder duct communicating with the bale chamber for charges of crop material to be transferred from the feeder duct into the bale chamber; a plunger reciprocally moveable within the bale chamber to compress successive charges of crop material received from the feeder duct to form a bale; and a feeder operable within the feeder duct to accumulate a charge of crop material therein and then stuff that accumulated charge into the bale chamber. The feeder includes at least one first tine and at least one second tine, each having a leading face for engaging the crop material. A width of a frontal area of the leading face of the second tine is smaller than a width of a frontal area of the leading face of the first tine.

The disclosure refers to an agricultural apparatus for forming from previously-cut agricultural crop, such as grass or the like, a windrow on a field, which may comprise: a frame, crop engaging elements supported on the frame and configured to form from previously-cut agricultural crop a windrow on a field, and a control unit configured to control operation of the crop engaging elements. The control unit is further configured to provide control signals to the crop engaging elements in such a way that, in a windrow forming mode of operation, the crop engaging elements are driven to engage with the previously-cut agricultural crop, and form from the previously-cut agricultural crop the windrow which may have a snake line form on the field. Further, a method for forming from previously-cut agricultural crop, such as grass or the like, a windrow on a field is also disclosed.

A control system for an agricultural harvester includes a crop inlet with infeed rollers for collecting crop from a pickup assembly connected to the harvester; and a lift assembly for moving the pickup assembly from an operational configuration, in which the pickup assembly is operable to pick up crop from the ground and to convey the picked-up crop to the crop inlet of the harvester, to a non-operational configuration. The control system includes a detector for detecting a foreign object in the collected crop; and one or more controllers configured to (i) receive a signal from the detector that is indicative of a foreign object in the collected crop while the pickup assembly is in the operational configuration; and (ii) control the lift assembly to raise the pickup assembly, away from the crop on the ground, to the non-operational condition, in dependence on the received signal.

A feeding assembly for an agricultural vehicle includes: a pickup including a pickup reel carrying a plurality of tines; a rotor including a plurality of rotor fins disposed rearwardly from the pickup; a windguard assembly including a pair of movable support arms and a windguard coupled to the support arms, the windguard including a tube and a plurality of windguard tines coupled to the tube, the windguard being movable from a first position to a second position that is elevated relative to the first position; and a windguard retainer configured to engage the windguard when the windguard is in the second position and retain the windguard in the second position.

The invention concerns improvement of a ground-traversing collection machine of a type having a laterally spanning pickup reel, a wind-guard residing overhead of the pickup reel and featuring a laterally lying support and a plurality of hold-down tines projecting from the support bar in a longitudinally rearward direction of opposing the machine's travel direction to hold down the material as it is fed rearwardly from the pickup reel, and a set of stub augers positioned adjacent opposing ends of the pickup reel to convey the material laterally inward toward a midplane of the machine. In the inventive improvement, a set of one or more tine braces are installed on the wind-guard in positions reinforcing one or more of said hold-down tines against potential deflection thereof by the material during laterally inward conveyance thereof by the stub augers.

An agricultural baler includes a main bale chamber, a plunger reciprocally movable within the main bale chamber, and a stuffer unit including a tine arm defining an axis of rotation and a plurality of tines coupled with and extending from the tine arm. The baler is characterized in that the tines are rotatable around the axis of rotation of the tine arm between a first position associated with a stuffing cycle and a second position associated with a loading cycle.

A baler including a frame, a feed assembly coupled to the frame, an auger housing defining a volume therein, where the volume of the auger housing is configured to receive crop material from the feed assembly during operation, and one or more augers at least partially positioned within the volume and rotatable with respect to the auger housing, where the one or more augers define an auger inlet plane. The baler also including a plurality of strippers coupled to the auger housing and configured to engage crop material, where each stripper includes a leading edge, and where the leading edge of at least one stripper is positioned upstream of the auger inlet plane.