A method, using an autonomous, unmanned device and a control device, includes the steps of automatically harvesting feed crop in a part of a crop field by means of the autonomous, unmanned device; automatically loading the harvested feed crop directly into a storage space provided on the autonomous, unmanned device without said harvested feed crop contacting the soil; choosing a destination location from a feeding location and a stationary crop processing location; automatically transporting the harvested feed crop from the crop field to the chosen destination location by means of the autonomous, unmanned device; and automatically unloading harvested feed from the storage space of the autonomous, unmanned device at the chosen destination location.

A method, using an autonomous, unmanned device and a control device, includes the steps of automatically harvesting feed crop in a part of a crop field by means of the autonomous, unmanned device; automatically loading the harvested feed crop directly into a storage space provided on the autonomous, unmanned device without said harvested feed crop contacting the soil; choosing a destination location from a feeding location and a stationary crop processing location; automatically transporting the harvested feed crop from the crop field to the chosen destination location by means of the autonomous, unmanned device; and automatically unloading harvested feed from the storage space of the autonomous, unmanned device at the chosen destination location.

A harvester high efficiency heat utilization device to be used in a harvester, includes: a drying chamber that dries grains of crops; a pipe that communicates with the drying chamber; a first heat exchanger provided in the pipe so as to communicate with an exhaust gas discharge port of an engine of the harvester; a combustion chamber that burns foliage of the crops; a second heat exchanger provided in the pipe so as to communicate with a high temperature gas discharge port of the combustion chamber; and a first blower that guides gas heat-exchanged by the first heat exchanger and the second heat exchanger to the drying chamber through the pipe.

A harvester high efficiency heat utilization device to be used in a harvester, includes: a drying chamber that dries grains of crops; a pipe that communicates with the drying chamber; a first heat exchanger provided in the pipe so as to communicate with an exhaust gas discharge port of an engine of the harvester; a combustion chamber that burns foliage of the crops; a second heat exchanger provided in the pipe so as to communicate with a high temperature gas discharge port of the combustion chamber; and a first blower that guides gas heat-exchanged by the first heat exchanger and the second heat exchanger to the drying chamber through the pipe.

A cooling system for a crop harvester. The cooling system includes a thermal transfer system configured to transfer heat from an engine of the crop harvester to air and crops passing through a crop chute of the crop harvester to cool the engine and dry crops passing through the crop chute.

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 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 dual-purpose agricultural cart for transporting and conditioning grain or other particulate material. The cart features a transportable frame, a holding container for receiving and holding the particulate material, a fan, and one or more airflow channels each having an inlet fed by the fan and at least one outlet positioned to open into the holding container at an elevation at or proximate a lower end of the holding container. The particulate material is aerated via upward fan-driven airflow from the outlet(s) of the one or more airflow channels. The same cart used to transport grain between a combine harvester and road transport vehicle during harvest can be used after harvest, or during harvest delays, the dry harvested grain before long term storage or long-distance transport.

A dual-purpose agricultural cart for transporting and conditioning grain or other particulate material. The cart features a transportable frame, a holding container for receiving and holding the particulate material, a fan, and one or more airflow channels each having an inlet fed by the fan and at least one outlet positioned to open into the holding container at an elevation at or proximate a lower end of the holding container. The particulate material is aerated via upward fan-driven airflow from the outlet(s) of the one or more airflow channels. The same cart used to transport grain between a combine harvester and road transport vehicle during harvest can be used after harvest, or during harvest delays, the dry harvested grain before long term storage or long-distance transport.

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.