Disclosed is a pelleting device which is designed as a field-guided stalk-crop harvesting machine and, when connected to a tractor with a chopper, includes a diesel engine that drives a current generator and also an annular die press. The chopped stalk material passes into a dry chamber and via a screw conveyor into the annular die press. The annular die of the annular die press is mounted in ring bearings on a base, on which a pair of pivot levers for a pan grinder roller is also hinged. An electric drive motor fed by the current generator drives the screw conveyor by a controller, and servomotors, which engage on the pivot levers, regulate the roller gap. The controller is governed as a function of the injection requirement of the diesel engine and/or the pressure applied by the press.

Disclosed is a pelleting device which is designed as a field-guided stalk-crop harvesting machine and, when connected to a tractor with a chopper, includes a diesel engine that drives a current generator and also an annular die press. The chopped stalk material passes into a dry chamber and via a screw conveyor into the annular die press. The annular die of the annular die press is mounted in ring bearings on a base, on which a pair of pivot levers for a pan grinder roller is also hinged. An electric drive motor fed by the current generator drives the screw conveyor by a controller, and servomotors, which engage on the pivot levers, regulate the roller gap. The controller is governed as a function of the injection requirement of the diesel engine and/or the pressure applied by the press.

A harvesting machine is disclosed along with a method of operation. The harvesting machine includes a frame having a flail cutter mounted on a first end of the frame. The flail cutter can cut the stems of growing plants. A housing surrounding a portion of the flail cutter for directing the cut plants rearward. An idler roller is positioned rearward of the flail cutter. First and second moisture removal mechanisms are positioned downstream of the cutting mechanism, and each includes a suction roll and a press roll. A moving belt forms a closed loop around the idler roller and the pair of suction and press rolls, and has a plurality of apertures formed therethrough. The moving belt forms first and second nips between each pair of suction and press rolls for squeezing moisture out of the cut stems as the stems are routed therebetween.

A harvesting machine is disclosed along with a method of operation. The harvesting machine includes a frame having a flail cutter mounted on a first end of the frame. The flail cutter can cut the stems of growing plants. A housing surrounding a portion of the flail cutter for directing the cut plants rearward. An idler roller is positioned rearward of the flail cutter. First and second moisture removal mechanisms are positioned downstream of the cutting mechanism, and each includes a suction roll and a press roll. A moving belt forms a closed loop around the idler roller and the pair of suction and press rolls, and has a plurality of apertures formed therethrough. The moving belt forms first and second nips between each pair of suction and press rolls for squeezing moisture out of the cut stems as the stems are routed therebetween.

An agricultural harvesting machine has a header designed as a front attachment for cutting and picking up crop and a driver assistance system for controlling the header. The driver assistance system has a memory for storing data and a computing unit for processing the data stored in the memory. The header together with the driver assistance system forms an automated header, in that a plurality of selectable harvesting-process strategies is stored in the memory and in order to implement a selected harvesting-process strategy or the selected harvesting-process strategies, the computing device autonomously determines at least one machine parameter, a header parameter and specifies this to the header.

An agricultural harvesting machine has a header designed as a front attachment for cutting and picking up crop and a driver assistance system for controlling the header. The driver assistance system has a memory for storing data and a computing unit for processing the data stored in the memory. The header together with the driver assistance system forms an automated header, in that a plurality of selectable harvesting-process strategies is stored in the memory and in order to implement a selected harvesting-process strategy or the selected harvesting-process strategies, the computing device autonomously determines at least one machine parameter, a header parameter and specifies this to the header.

A system and method for producing a feed product, and the product, are disclosed. A processor apparatus may comprise a housing and at least two generally cylindrical rolls rotatably mounted on the housing, with a gap being formed between the rolls through which the path of the crop materials passes. At least one roll may have alternating longitudinal ridges and grooves forming teeth on the surface of the roll. A rotating assembly may be configured to rotate the rolls with respect to the housing, the rotating assembly being configured to rotate the pair of rolls at different rotational speeds. A method may comprise cutting plants growing in a field, chopping the plants of the crop materials in a manner to produce pieces of the plants that have lengths of approximately 1 inch to approximately 2.5 inches long, and processing the plant pieces between the rolls rotating at a speed differential of at least 10 percent.

A pull-type mower conditioner includes a crop cutting assembly that severs crop material from the ground and a lift mechanism configured to raise and lower the crop cutting assembly to a desired height having at least one lift cylinder and a hydraulic lift circuit supplying hydraulic fluid to the at least one lift cylinder. The mower conditioner also includes a conditioning mechanism receiving the severed crop material from the crop cutting assembly. The conditioning mechanism includes a pair of counter-rotating conditioning rolls to condition the crop material and a tensioning assembly that urges the conditioning rolls relatively toward one another and resists their separation. The tensioning assembly includes a pair of hydraulic tension cylinders and a hydraulic conditioner circuit configured to supply hydraulic fluid to the tension cylinders. The hydraulic tension circuit has a supply line leading to a supply valve, wherein the supply line connects to the lift circuit.

A pull-type mower conditioner includes a crop cutting assembly that severs crop material from the ground and a lift mechanism configured to raise and lower the crop cutting assembly to a desired height having at least one lift cylinder and a hydraulic lift circuit supplying hydraulic fluid to the at least one lift cylinder. The mower conditioner also includes a conditioning mechanism receiving the severed crop material from the crop cutting assembly. The conditioning mechanism includes a pair of counter-rotating conditioning rolls to condition the crop material and a tensioning assembly that urges the conditioning rolls relatively toward one another and resists their separation. The tensioning assembly includes a pair of hydraulic tension cylinders and a hydraulic conditioner circuit configured to supply hydraulic fluid to the tension cylinders. The hydraulic tension circuit has a supply line leading to a supply valve, wherein the supply line connects to the lift circuit.

A toothed crushing disk for a grain processor includes teeth having a trailing tooth flank, which is a so-called tooth back, and a leading tooth flank, which is a so-called tooth face, on the surface of the teeth. The teeth have a wear protection zone in the region of the tooth back which is continuous or is divided into partial zones and has a wear resistance which is greater than that of the material of a base member of the toothed crushing disk. The base member has a tooth structure which determines the shape of the teeth and the wear protection zone is produced by using a high-energy beam method with the geometry of the tooth structure being substantially maintained. A method for producing a toothed crushing disk for a grain processor having teeth on the surface thereof is also provided.