A windrower system includes: a windrower including: a chassis; a cutter carried by the chassis and configured to cut crop material; and an adjustable conditioner carried by the chassis behind the cutter and configured to condition crop material cut by the cutter; and a controller operably coupled to the conditioner and including a memory. The controller is configured to: receive a crop type signal corresponding to a crop type; recall at least one conditioner operating parameter from the memory based at least partially on the received crop type signal; and output a conditioner adjustment signal to the conditioner to adjust the conditioner to the recalled at least one conditioner operating parameter.

A conditioner unit (6) for conditioning crop material comprises a rotor (17) having a shaft (18) that carries a plurality of conditioning elements, a drive mechanism for driving rotation of the rotor (17) about an axis, and a deflector element having a working surface (26) that surrounds at least part of the circumference of the rotor (17) to define a conditioning passage through which crop material is transported by rotation of the rotor (17). An adjusting mechanism (30) is provided for adjusting the position of the deflector element relative to the rotor (17), the adjusting mechanism (30) including an actuator (50), a sensor for sensing an operational condition of the conditioning unit (6) and a control system (56) that receives a sensor signal from the sensor and controls actuation of the actuator (50) in response to said sensor signal to provide a desired level of conditioning during operation of the conditioner unit (6).

An image capture device captures an image of crop after it has been processed by a kernel processing unit on a forage harvester. A size distribution indicative of the distribution of kernel fragment sizes in the harvested crop is identified from the image captured by the image capture device. A control system generates control signals to control a speed differential in the speed of rotation of kernel processing rollers based on the size distribution. Control signals can also be generated to control a size of a gap between the kernel processing rollers.

A nozzle mount for a swather includes a mounting plate configured for attachment to the swather, a nozzle head extending from one side of the mounting plate, and a nozzle shield attached to the mounting plate and configured to at least partially enclose the nozzle head to protect the nozzle head from impact damage while allowing the nozzle head to direct preconditioner fluid flow into the swather. The nozzle head is configured for attachment to a fluid source, such as a hay preservative, that can be sourced from a locally mounted tank.

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 conditioner unit (6) for conditioning an agricultural crop material comprises a pair of rolls (20a, 20b) configured for rotation in opposite directions and providing a nip (22) through which crop material passes. An adjusting mechanism (31) is provided for adjusting a pressing force applied by the rolls (20a, 20b) to the crop material as it passes through the nip. The adjusting mechanism (31) includes at least one hydraulic actuator (30) connected to at least one of the rolls (20a, 20b) and a hydraulic circuit (33) that supplies hydraulic fluid to the actuator (30), the hydraulic circuit being configured so that in a first operational mode the rolls (20a, 20b) are pressed towards one another and in a second operational mode the rolls (20a, 20b) are pushed apart to provide a gap between the rolls.

An image capture device captures an image of crop after it has been processed by a kernel processing unit on a forage harvester. A size distribution indicative of the distribution of kernel fragment sizes in the harvested crop is identified from the image captured by the image capture device. A control system generates control signals to control a speed differential in the speed of rotation of kernel processing rollers based on the size distribution. Control signals can also be generated to control a size of a gap between the kernel processing rollers.

A harvesting header of an agricultural machine includes a frame, a cutting mechanism coupled to the frame and configured to cut crop, an auger rotatably coupled to the frame at a location rearward of the cutting mechanism, and an impeller rotatably coupled to the frame at a location rearward of the auger. The impeller is configured to receive crop from the auger and condition the cut crop. The crop is projected by the auger in a rearward and upward direction relative to the impeller.

A conditioner roller vibration sensing mechanism having first and second rotatable conditioner rollers spaced apart in close proximity to each other and between which cut crop can be directed as the rollers rotate during operation. The first roller is shiftable with respect to the second roller for adjusting the spacing between the rollers. The rollers vibrate when the rollers are spaced in such close proximity to each other that they contact each other as they rotate. An arm pivotally mounted to a frame supports the first roller, and the frame supports the second roller. The arm is movable to shift the first roller with respect to the second roller. An accelerometer is operatively coupled to the rollers for sensing the vibration created when the first and second rollers are positioned so close to each other to contact each other.

A harvesting apparatus includes a crop conditioning element coupled to a frame, and a hood moveable relative to the crop conditioning element. An actuating system moveably connects the hood to the frame. The actuating system includes a driven lever arm rotatably attached to the frame and including a first lever connection and a second lever connection positioned opposite each other across a lever rotation axis. A first pivot assembly is rotatably attached to the frame and includes a first pivot connection coupled to the first lever connection of the driven lever arm, and a second pivot connection coupled to a first lift location of the hood. A second pivot assembly is rotatably attached to the frame and includes a third pivot connection coupled to the second lever connection of the driven lever arm, and a fourth pivot connection coupled to a second lift location of the hood.