A crop forming assembly having a top plate with a first side and a second side, an arc-shaped cutout defined through the top plate, a forming shield pivotally coupled to the top plate and positioned on the second side, and a motor removably coupled to the top plate and configured to engage the forming shield. Wherein, the motor engages the forming shield to reposition the forming shield along the arc-shaped cutout.

A crop forming assembly having a top plate with a first side and a second side, an arc-shaped cutout defined through the top plate, a forming shield pivotally coupled to the top plate and positioned on the second side, and a motor removably coupled to the top plate and configured to engage the forming shield. Wherein, the motor engages the forming shield to reposition the forming shield along the arc-shaped cutout.

The disclosure describes a cutting system for a harvesting header, which includes a transversely extending cutter bar, a transversely extending knife back, a knife section mounted to the knife back having a knife edge extending generally in a forward direction, a knife guard component having a front guard portion and a rear portion interconnected by a medial portion having a recess, the medial portion for receiving a lengthwise portion of the knife back with the knife section being received into, the knife section operable to move transversely into and out of a cutting slot in the front guard portion, a hold down component located between an upper surface of the rear portion of the knife guard component and an underneath surface of the cutter bar, and an attachment mechanism operable to secure the knife guard component and the hold down component to the underneath surface of the cutter bar.

Self-propelled vehicles that adjust the pitch of the vehicle during use are disclosed. The vehicle may include a suspension system position sensor and a control unit that adjusts a suspension element based at least in part on a signal from the suspension system position sensor. In some embodiments, the self-propelled vehicle may include an inclinometer for measuring the pitch of the terrain.

An impeller conditioner for an agricultural mowing machine includes a rotor, an attachment device located on the rotor, a tine device pivotally attached to the rotor between a first end and a second end of the tine device via the attachment device, and a positioning device located on one of the rotor and the attachment device. The positioning device include a tapered portion which restricts the tine device in a first position to have less lateral movement than the tine device in a second position. The first position can be an operational position and the second position can be a non-operational position.

An impeller conditioner for an agricultural mowing machine includes a rotor, an attachment device located on the rotor, a tine device pivotally attached to the rotor between a first end and a second end of the tine device via the attachment device, and a positioning device located on one of the rotor and the attachment device. The positioning device include a tapered portion which restricts the tine device in a first position to have less lateral movement than the tine device in a second position. The first position can be an operational position and the second position can be a non-operational position.

A harvesting header has a set of centrally disposed conditioner rolls comprising conditioning structure to condition crop and a rotary cutter bed. The rotary cutter bed has a plurality of rotary cutters extending across the path of travel of the header to define a cutting plane, each cutter being rotatable about an upright axis, the conditioner rolls being behind the cutter bed to condition crop cut by the rotary cutter bed. The header has a crop-directing header windguard configured to direct the crop down towards the conditioning rolls after the plurality of cutters have severed the crop, the header windguard extending in a rearwardly direction from a position forward of the cutter bed to a position proximate the conditioner rolls, and the header windguard extending transversely at least a width of the rotary cutter bed.

A harvesting header has a set of centrally disposed conditioner rolls comprising conditioning structure to condition crop and a rotary cutter bed. The rotary cutter bed has a plurality of rotary cutters extending across the path of travel of the header to define a cutting plane, each cutter being rotatable about an upright axis, the conditioner rolls being behind the cutter bed to condition crop cut by the rotary cutter bed. The header has a crop-directing header windguard configured to direct the crop down towards the conditioning rolls after the plurality of cutters have severed the crop, the header windguard extending in a rearwardly direction from a position forward of the cutter bed to a position proximate the conditioner rolls, and the header windguard extending transversely at least a width of the rotary cutter bed.

A roller shell for a conditioning roller includes a number of teeth which are distributed over the periphery thereof and which extend in an axial direction. Each of the teeth includes a leading flank, a trailing flank and a radial outer surface region having an angulation defined therein. The angulation may include a recess or a step in the outer surface region.

A roller shell for a conditioning roller includes a number of teeth which are distributed over the periphery thereof and which extend in an axial direction. Each of the teeth includes a leading flank, a trailing flank and a radial outer surface region having an angulation defined therein. The angulation may include a recess or a step in the outer surface region.