A conditioning roller assembly includes two conditioning rollers which are rotatably mounted on associated bearing arrangements, and a holder which includes a first holder component and a second holder component that are connected together by a hinge and a spring arrangement for providing a pre-tensioning of the conditioning rollers. The first holder component is releasably connected to the first bearing arrangement, the second holder component is releasably connected to the second bearing arrangement, and the conditioning rollers, with the bearing arrangements, are detachable in each case from the components without the holder being disassembled.

A forage harvester is configured to chop harvested material and includes at least one conditioning unit for conditioning the chopped harvested material. The conditioning unit may transfer from its active position (in which operatively connected with other working units) to its passive position (in which the conditioning unit is released from the operational connection). In the passive position, the condition unit may be removed from the entirety of the forage harvester. The forage harvester further includes at least two track drives arranged on opposing ends of a front axle of the forage harvester. The forage harvester includes a free cross-section positioned on a removal side of the forage harvester through which the conditioning unit, in its passive position, can be removed laterally from the rest of the forage harvester, as well as removed above the track drive assigned to the removal side.

A forage harvester is configured to chop harvested material and includes at least one conditioning unit for conditioning the chopped harvested material. The conditioning unit may transfer from its active position (in which operatively connected with other working units) to its passive position (in which the conditioning unit is released from the operational connection). In the passive position, the condition unit may be removed from the entirety of the forage harvester. The forage harvester further includes at least two track drives arranged on opposing ends of a front axle of the forage harvester. The forage harvester includes a free cross-section positioned on a removal side of the forage harvester through which the conditioning unit, in its passive position, can be removed laterally from the rest of the forage harvester, as well as removed above the track drive assigned to the removal side.

A mower conditioner implement includes a cutting system for cutting crop material, and a crop conditioning system for receiving the cut crop material from the cutting system and conditioning the cut crop material to facilitate drying. An image sensor senses an image of the cut crop material. The image includes a color spectrum of the cut crop material from reflected light emitted from a light source. A computing device compares the color spectrum of the image to a calibrated color measurement to determine an ash content in the cut crop material, and/or a degree of stem conditioning of the cut crop material. The computing device may then communicate the results to an operator, and/or adjust the cutting system or the crop conditioning system based on the ash content or the degree of stem conditioning.

A crop stripper rotor includes a plurality of stripper teeth sections and backer plates secured to a central core by threaded fasteners. The stripper teeth sections have stripper teeth that project radially outwardly from a mounting base, and the backer plates have teeth that fit behind the stripper teeth. The stripper teeth sections and backer plates are sandwiched between opposing flanges of adjacent bent sheet metal sections of the central core. An alignment and mounting system includes a pair of alignment slots in each stripper teeth section and backer plate that open radially inwardly. A first pair of threaded fasteners mate with the alignment slots to set the depth and alignment of the stripper teeth sections and backer plates relative to the central core. A second pair of threaded fasteners are inserted through the aligned mounting bores of the stripper teeth sections and the backer plates to complete the assembly.

A crop stripper rotor includes a plurality of stripper teeth sections and backer plates secured to a central core by threaded fasteners. The stripper teeth sections have stripper teeth that project radially outwardly from a mounting base, and the backer plates have teeth that fit behind the stripper teeth. The stripper teeth sections and backer plates are sandwiched between opposing flanges of adjacent bent sheet metal sections of the central core. An alignment and mounting system includes a pair of alignment slots in each stripper teeth section and backer plate that open radially inwardly. A first pair of threaded fasteners mate with the alignment slots to set the depth and alignment of the stripper teeth sections and backer plates relative to the central core. A second pair of threaded fasteners are inserted through the aligned mounting bores of the stripper teeth sections and the backer plates to complete the assembly.

A tine device for an impeller apparatus is disclosed. The tine device comprises at least one tine element having a first end configured to be rotatably coupled to a central rotor of the impeller apparatus. The tine element additionally comprises a second end positioned on a first side of a radial line extending through the first end, and a curved portion located on an opposite second side of the radial line between the first and second ends.

A tine device for an impeller apparatus is disclosed. The tine device comprises at least one tine element having a first end configured to be rotatably coupled to a central rotor of the impeller apparatus. The tine element additionally comprises a second end positioned on a first side of a radial line extending through the first end, and a curved portion located on an opposite second side of the radial line between the first and second ends.

A mower-conditioner (2, 6) for cutting and conditioning crop material, comprises a mower unit (2) for cutting crop material and a conditioner unit (6) that is configured to condition the cut crop material. A drive input (10) is configured to receive a rotational drive from an external drive unit, and a drive transmission system (30) is configured to transmit rotary drive from the drive input (10) to the mower unit (2) and the conditioner unit (6). The drive transmission system (30) includes a continuously variable transmission (CVT) (40) that transmits rotary drive between the mower unit (2) and the conditioner unit (6) with a variable speed ratio.

A mower-conditioner (2, 6) for cutting and conditioning crop material, comprises a mower unit (2) for cutting crop material and a conditioner unit (6) that is configured to condition the cut crop material. A drive input (10) is configured to receive a rotational drive from an external drive unit, and a drive transmission system (30) is configured to transmit rotary drive from the drive input (10) to the mower unit (2) and the conditioner unit (6). The drive transmission system (30) includes a continuously variable transmission (CVT) (40) that transmits rotary drive between the mower unit (2) and the conditioner unit (6) with a variable speed ratio.