A feed section for a multi-row sugarcane harvester comprises a first feed train configured to advance a first mat of sugarcane received from a first row of sugarcane, a second feed train configured to advance a second mat of sugarcane received from a second row of sugarcane, and a third feed train. The first and second feed trains merge into the third feed train. Each of the first feed train and the second feed train comprises a first feed roller and a second feed roller, each of which has an axis of rotation. With respect to the first feed train, the axes of rotation of the first and second feed rollers are positioned at different acute angles relative to a fore-aft axis of the feed section.

A feed section for a multi-row sugarcane harvester comprises a first feed train configured to advance a first mat of sugarcane received from a first row of sugarcane, a second feed train configured to advance a second mat of sugarcane received from a second row of sugarcane, and a third feed train. The first and second feed trains merge into the third feed train. Each of the first feed train and the second feed train comprises a first feed roller and a second feed roller, each of which has an axis of rotation. With respect to the first feed train, the axes of rotation of the first and second feed rollers are positioned at different acute angles relative to a fore-aft axis of the feed section.

An agricultural machine with a mechanism involving rotating fingers for gathering crops towards an entry port, such as a rotating auger tube, has fingers mounted to be rotatable about a shaft that is itself movable inside the rotating tube, as the ends of the shaft are supported by a pair of cams. The ends of the shaft are movable along cam tracks which impose movement of the shaft along a pre-defined trajectory. Through a suitable coupling mechanism, the rotation of the tube drives the movement of the shaft ends in the cam tracks and hence the movement of the shaft itself, while the shaft remains parallel to the tube's rotation axis.

An agricultural machine with a mechanism involving rotating fingers for gathering crops towards an entry port, such as a rotating auger tube, has fingers mounted to be rotatable about a shaft that is itself movable inside the rotating tube, as the ends of the shaft are supported by a pair of cams. The ends of the shaft are movable along cam tracks which impose movement of the shaft along a pre-defined trajectory. Through a suitable coupling mechanism, the rotation of the tube drives the movement of the shaft ends in the cam tracks and hence the movement of the shaft itself, while the shaft remains parallel to the tube's rotation axis.

A combine unload control system having a grain tank for storing grain and at least one auger for unloading grain from the grain tank. The control system also includes a first auger cover proximate to the at least one auger, having one or more first auger cutouts disposed on a portion of the first auger cover and a second auger cover proximate to the at least one auger and having one or more second auger cutouts disposed on a portion of the second auger cover. The control system further includes a controller configured to control amounts of grain to pass through the one or more first auger cutouts and the one or more second auger cutouts and flow to the at least one auger by causing the first auger cover and the second auger cover to move relative to each other.

A combine unload control system having a grain tank for storing grain and at least one auger for unloading grain from the grain tank. The control system also includes a first auger cover proximate to the at least one auger, having one or more first auger cutouts disposed on a portion of the first auger cover and a second auger cover proximate to the at least one auger and having one or more second auger cutouts disposed on a portion of the second auger cover. The control system further includes a controller configured to control amounts of grain to pass through the one or more first auger cutouts and the one or more second auger cutouts and flow to the at least one auger by causing the first auger cover and the second auger cover to move relative to each other.

A picking apparatus having at least one holder movable in a working direction. The holder has at least one conveying device with a front gathering region. The produce bearing plants come in contact with the conveying device in the front gathering region. The conveying device is operable to gather and transport plants in at least one conveying direction. The conveying direction extend in a straight or substantially straight line and transverse or substantially transverse to the working direction. The picking apparatus also has a picking gap defined behind the conveying device, wherein the plants are guided through the picking gap while separating the produce.

A picking apparatus having at least one holder movable in a working direction. The holder has at least one conveying device with a front gathering region. The produce bearing plants come in contact with the conveying device in the front gathering region. The conveying device is operable to gather and transport plants in at least one conveying direction. The conveying direction extend in a straight or substantially straight line and transverse or substantially transverse to the working direction. The picking apparatus also has a picking gap defined behind the conveying device, wherein the plants are guided through the picking gap while separating the produce.

A reel for a harvester, such as for a combine harvester. The reel includes a reel supporting pipe and star-shaped supports at the ends of the reel, the star arms being connected to each other by means of tine rods which run parallel to the supporting pipe, wherein the star-shaped supports are specifically at least partially reinforced as a result of which at least one of the tensile and compression forces acting on the supporting pipe can be absorbed by one or more tine rods.

A mower implement comprising may include a main frame, a cutter assembly, a hyperspectral sensor, and a controller. The hyperspectral sensor is coupled to the main frame, receives reflectance from a target area disposed rearward of the cutter assembly and including the windrow, and generates a signal indicative of light spectrums of the target area. The controller has a processor and a memory having a windrow distribution algorithm stored therein. The processor is operable to execute the windrow distribution algorithm to: receive the signal indicative of the light spectrums of the target area from the hyperspectral sensor; calculate a normalized difference index based on the signal indicative of the light spectrums of the target area; estimate a volumetric spread of the windrow; and control a machine system based on the volumetric spread. The machine system includes one of a display, an actuator, and a drivetrain component.