A harvesting system includes at least one modular unit coupled to a harvester includes a drying unit to dry a harvested material introduced into the harvester including at least one rotating drum, a number of appendages extending from the at least one rotating drum, at least one sensor to determine at least one environmental state within the drying unit, and at least one environmental state adjustment device to adjust at least one environmental attribute within the drying unit. The modular unit also includes a collection unit to collect the harvested material into a unit, a first conveyor mechanism to convey the harvested material from the drying unit to the collection unit, and a control system to control at least the harvester, the drying unit, the collection unit, the first conveyor mechanism, the sensor, and the environmental state adjustment device based on a signal received from the at least one sensor.

A system and computer-implemented method for sensing an amount of free water in cut crop material and automatically adjusting an operating parameter of a mower conditioner to optimize the amount of free water. A sensor located at the exit of a conditioning mechanism measures an actual free water content value of the material as it exits the conditioning mechanism, a processor compares the actual value to maximum and minimum values, and if the actual value is outside this range, automatically adjusts an operating parameter, such as a gap between pairs of conditioning rollers, a pressure exerted by the rollers, or a speed of the mower conditioner, to optimize the actual value. Another sensor may be located at the entrance of the conditioning mechanism. The processor may take into account an operator-selectable value weighting the actual free water content versus a dry down time when adjusting the operating parameter.

A harvesting machine is disclosed along with a method of operating the harvesting machine. The harvesting machine includes a frame having a first end and a second end. A rotatable pick-up head is pivotally mounted on the first end and is capable of urging a crop into the machine. A cutting mechanism is mounted on a bottom plate of the frame for cutting the stems of the plants and forming a movable web. 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 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 said stems as the movable web is routed through the first and second nips.

A harvesting machine along with a method of operating the harvesting machine. The harvesting machine includes a frame having a first end and a second end. A rotatable pick-up head is pivotally mounted on the first end and is capable of urging a crop into the machine. A cutting mechanism is mounted on a bottom plate for cutting the stems of the plants. A crimper mechanism is positioned downstream of the bottom plate and is capable of compacting the cut stems into a moving web. A moisture removal mechanism is positioned after the crimper mechanism to lower the moisture in the cut stems. A crop converging mechanism is located downstream of the moisture removal mechanism and reduces the width of the moving web into a ribbon. A chopper then chops the ribbon into small pieces so that they can be blown into a storage wagon for transport.

A harvesting machine is disclosed along with a method of operating the harvesting machine. The harvesting machine includes a frame having a first end and a second end. A rotatable pick-up head is pivotally mounted on the first end and is capable of urging a crop into the machine. A cutting mechanism is mounted on a bottom plate for cutting the stems of the plants. A crimper mechanism is positioned downstream of the bottom plate and is capable of compacting the cut stems into a moving web. A moisture removal mechanism is positioned after the crimper mechanism to lower the moisture in the cut stems. A crop converging mechanism is located downstream of the moisture removal mechanism and reduces the width of the moving web into a ribbon. A chopper then chops the ribbon into small pieces so that they can be blown into a storage wagon for transport.

A system and computer-implemented method for sensing an amount of free water in cut crop material and automatically adjusting an operating parameter of a mower conditioner to optimize the amount of free water. A sensor located at the exit of a conditioning mechanism measures an actual free water content value of the material as it exits the conditioning mechanism, a processor compares the actual value to maximum and minimum values, and if the actual value is outside this range, automatically adjusts an operating parameter, such as a gap between pairs of conditioning rollers, a pressure exerted by the rollers, or a speed of the mower conditioner, to optimize the actual value. Another sensor may be located at the entrance of the conditioning mechanism. The processor may take into account an operator-selectable value weighting the actual free water content versus a dry down time when adjusting the operating parameter.

A mower-conditioner machine which includes a frame, a cutter bar connected to the frame, the cutter bar is configured to cut a crop material from a field, and a crop-engaging member connected to the frame. The crop-engaging member is configured to contact the crop material. The mower-conditioner machine also includes at least one moisture sensor connected to the crop-engaging member. The at least one moisture sensor is configured to sense a moisture content of the crop material.

A plain mower includes a plurality of rotary cutters for cutting a crop and a swathing unit for forming the cut crop material into a swath. The swathing unit includes an auger that rotates about an axis to transport crop material axially through the swathing unit. The swathing unit can be configured in a first configuration in which the crop material is ejected axially from the auger, and can be reconfigured in a second configuration in which the crop material is ejected radially from the auger.

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 mobile platform comprises a header, a biomass processor, and a guidance system. The header is configured to harvest biomass. The biomass processor is configured to compact the biomass into a multitude of compressed biomass pieces. The guidance system is configured to guide the mobile platform at a speed determined by the operating capacity of the mobile platform.