The present disclosure provides a ratooning rice harvesting header and a harvester including the same. The ratooning rice harvesting header includes a multi-layer adjustable disc cutter, a header, and an ear cutter. The multi-layer adjustable disc cutter is mounted below the header and located below a rear portion of the ear cutter. The ear cutter is mounted at a front end of the header. The multi-layer adjustable disc cutter includes at least one group of multi-layer disc cutting assemblies. Each group of multi-layer disc cutting assemblies includes two multi-layer disc cutting assemblies. Each of the multi-layer disc cutting assemblies includes three layers of vertically arranged blades. The use of the multi-layer adjustable disc cutter in cooperation with the ear cutter can reduce the straw-grain ratio of the part cut from the crops to reduce the power consumption of the harvester.

The present disclosure provides a ratooning rice harvesting header and a harvester including the same. The ratooning rice harvesting header includes a multi-layer adjustable disc cutter, a header, and an ear cutter. The multi-layer adjustable disc cutter is mounted below the header and located below a rear portion of the ear cutter. The ear cutter is mounted at a front end of the header. The multi-layer adjustable disc cutter includes at least one group of multi-layer disc cutting assemblies. Each group of multi-layer disc cutting assemblies includes two multi-layer disc cutting assemblies. Each of the multi-layer disc cutting assemblies includes three layers of vertically arranged blades. The use of the multi-layer adjustable disc cutter in cooperation with the ear cutter can reduce the straw-grain ratio of the part cut from the crops to reduce the power consumption of the harvester.

Methods and systems are described for providing a local electrical power source at a header of a combine harvester. An alternator is mechanically coupled to a header backshaft. The header backshaft is mechanically coupled to a drive mechanism of the combine harvester to cause rotation of the header backshaft which, in turn, causes the alternator to generate electrical power. A power supply circuit transferred electrical power from the alternator to one or more electric devices mounted on the header. In some implementations, the header does not include any physical cables between the combine and the header.

Methods and systems are described for providing a local electrical power source at a header of a combine harvester. An alternator is mechanically coupled to a header backshaft. The header backshaft is mechanically coupled to a drive mechanism of the combine harvester to cause rotation of the header backshaft which, in turn, causes the alternator to generate electrical power. A power supply circuit transferred electrical power from the alternator to one or more electric devices mounted on the header. In some implementations, the header does not include any physical cables between the combine and the header.

The invention relates to a system for adjusting the height of an agricultural implement, including an arm that can be controlled to raise and lower the implement, a height measuring sensor, and a calculator configured to provide a control set point for the height of the arm on the basis of the measurements obtained by the height measuring sensor. The height measuring sensor is an imaging system including at least one camera mounted such that the sensor can form an image of a scene located in front of the agricultural implement in the direction of travel of the vehicle equipped with the arm. A computer processing unit is configured to produce, on the basis of the images delivered by the at least one camera, a 3D reconstruction representative of the depth of the aforementioned scene.

The invention relates to a system for adjusting the height of an agricultural implement, including an arm that can be controlled to raise and lower the implement, a height measuring sensor, and a calculator configured to provide a control set point for the height of the arm on the basis of the measurements obtained by the height measuring sensor. The height measuring sensor is an imaging system including at least one camera mounted such that the sensor can form an image of a scene located in front of the agricultural implement in the direction of travel of the vehicle equipped with the arm. A computer processing unit is configured to produce, on the basis of the images delivered by the at least one camera, a 3D reconstruction representative of the depth of the aforementioned scene.

Described is a processing machine for processing relatively short fibre plants such as flax and relatively long fibre plants such as hemp. The processing machine comprises a self-propelling vehicle comprising a vehicle chassis provided with a first conveyor for transporting at least parts of the fibre plants from a first end to an opposite second end, and a second conveyor for transporting at least parts of the fibre plants from the first end to the second end, first and second delivering units provided at or close to the second end for the purpose of delivering and placing on the ground surface the fibre plants coming from respectively the first and second conveyor, and wherein the vehicle chassis comprises first mounting means for mounting of, as desired, either a first exchangeable picking unit or a second exchangeable picking unit.

Described is a processing machine for processing relatively short fibre plants such as flax and relatively long fibre plants such as hemp. The processing machine comprises a self-propelling vehicle comprising a vehicle chassis provided with a first conveyor for transporting at least parts of the fibre plants from a first end to an opposite second end, and a second conveyor for transporting at least parts of the fibre plants from the first end to the second end, first and second delivering units provided at or close to the second end for the purpose of delivering and placing on the ground surface the fibre plants coming from respectively the first and second conveyor, and wherein the vehicle chassis comprises first mounting means for mounting of, as desired, either a first exchangeable picking unit or a second exchangeable picking unit.

A harvester has a main frame defining a front and a rear, and an inlet for receiving first portions of a crop. The inlet is disposed proximate the front of the main frame. The harvester also includes a separator for processing the first portions, at least one outlet downstream of the separator for ejecting the processed first portions, a boom extending proximate the front of the main frame for reaching un-processed crop, and a topper coupled to the boom for cutting second portions of the crop. The topper includes a cutter for cutting the second portions, a conveyor for receiving the second portions from the cutter, and an outlet disposed proximate the conveyor. The conveyor is configured to transport the second portions towards the outlet for ejecting the second portions towards the field.

A harvester has a main frame defining a front and a rear, and an inlet for receiving first portions of a crop. The inlet is disposed proximate the front of the main frame. The harvester also includes a separator for processing the first portions, at least one outlet downstream of the separator for ejecting the processed first portions, a boom extending proximate the front of the main frame for reaching un-processed crop, and a topper coupled to the boom for cutting second portions of the crop. The topper includes a cutter for cutting the second portions, a conveyor for receiving the second portions from the cutter, and an outlet disposed proximate the conveyor. The conveyor is configured to transport the second portions towards the outlet for ejecting the second portions towards the field.