A cryogenic processing system includes a cryogenic fluid source, and an auger, which includes an auger vessel containing at least one screw assembly. The screw assembly includes a flighting and a hollow shaft radially inward of the flighting. The shaft is in fluid communication with the cryogenic fluid source and includes one or more nozzles for dispensing cryogenic fluid within the auger vessel.

A forage harvester configured to chop harvested material and including at least one conditioning unit for conditioning the chopped harvested material is disclosed. 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 configured to chop harvested material and including at least one conditioning unit for conditioning the chopped harvested material is disclosed. 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 header for a combine harvester, the header including a frame mountable to a forward end of the combine harvester, at least one row unit mounted to the frame to receive and process stalks of corn, a stomping shoe mounted to the frame behind the row unit to flatten stalks of corn, and a stalk splitter mounted to frame behind the row unit to split stalks of corn. The face of the stomping shoe is provided with a plurality of structures to guide each stalk of corn along a predefined path on the face while the stalks of corn are flattened. The stalk splitter includes a disk blade biased against the ground for splitting stalks of corn after they are processed by row units of the corn header.

A header for a combine harvester, the header including a frame mountable to a forward end of the combine harvester, at least one row unit mounted to the frame to receive and process stalks of corn, a stomping shoe mounted to the frame behind the row unit to flatten stalks of corn, and a stalk splitter mounted to frame behind the row unit to split stalks of corn. The face of the stomping shoe is provided with a plurality of structures to guide each stalk of corn along a predefined path on the face while the stalks of corn are flattened. The stalk splitter includes a disk blade biased against the ground for splitting stalks of corn after they are processed by row units of the corn header.

A work vehicle system includes at least one harvesting work vehicle with a harvesting arrangement. The harvesting arrangement is one of a conditioning arrangement configured to condition a crop material and a windrowing arrangement configured to form a windrow of the crop material. A method includes receiving, by a processor of a control system from a memory element, a stored setting for a variable parameter of the harvesting arrangement. The method also includes processing, by the processor, a control signal based, at least in part, on the stored setting. Furthermore, the method includes changing, with an actuator, the variable parameter of the harvesting arrangement according to the control signal.

A work vehicle system includes at least one harvesting work vehicle with a harvesting arrangement. The harvesting arrangement is one of a conditioning arrangement configured to condition a crop material and a windrowing arrangement configured to form a windrow of the crop material. A method includes receiving, by a processor of a control system from a memory element, a stored setting for a variable parameter of the harvesting arrangement. The method also includes processing, by the processor, a control signal based, at least in part, on the stored setting. Furthermore, the method includes changing, with an actuator, the variable parameter of the harvesting arrangement according to the control signal.

An agricultural vehicle includes a chassis; a header carried by the chassis and including a cutter mechanism, the header being adjustable in a vertical direction; a swath roller carried by the chassis behind the header; a roller actuator connected to the swath roller and configured to adjust the swath roller in the vertical direction; and a controller coupled to the roller actuator. The controller is configured for: detecting when the header raises in the vertical direction; recording a header raising point where the header raises; determining when the swath roller reaches the header raising point; and signaling the roller actuator to raise the swath roller when the swath roller reaches the header raising point.

An agricultural vehicle includes a chassis; a header carried by the chassis and including a cutter mechanism, the header being adjustable in a vertical direction; a swath roller carried by the chassis behind the header; a roller actuator connected to the swath roller and configured to adjust the swath roller in the vertical direction; and a controller coupled to the roller actuator. The controller is configured for: detecting when the header raises in the vertical direction; recording a header raising point where the header raises; determining when the swath roller reaches the header raising point; and signaling the roller actuator to raise the swath roller when the swath roller reaches the header raising point.

A system and method for detecting a malfunction in a harvesting machine includes a sensor for mounting to the harvesting machine. The sensor is configured to measure a magnitude of a mechanical wave produced in the harvesting machine, and output a signal based on the magnitude. A controller receives the signal from the sensor. The controller is configured to process the signal and generate an alarm signal when a threshold is exceeded. An alarm unit is configured to receive the alarm signal from the controller when the threshold value is exceeded, and output an alarm to alert the operator of the malfunction. The malfunction can be a slipped clutch caused by a jammed condition, or other anomaly that generates a mechanical wave. The mechanical wave can be a sound wave or mechanical vibration traveling through one or more parts of the harvesting machine.