Method for imaging a corn ear having an outer surface, the method implementing an imaging module having a field of view that enables an image of the outer surface of the corn ear to be acquired, the method comprising the step consisting in dropping the corn ear within the field of view of the imaging module and acquiring an image of the outer surface of the corn ear while the corn ear drops within the field of view of the imaging module.

The present invention relates to a device (2) for harvesting stalk-like stem crops, having a number of picking units (4) which are arranged alongside one another on the frame (6) of the device (2) and each have picking plates (12), laterally delimiting a picking gap (14), and picking rotors (16) located therebeneath, conveying units which are assigned to the respective picking units (4), are configured as continuous conveyors (22) that are driven in circulation, are arranged on opposite sides above a picking gap (14) and are configured with drivers (18) fastened to the circulating elements, and a transverse conveying device (8) arranged downstream of the conveying units. In order to find an arrangement for the continuous conveyors which results in a reduced overall width without the intake of laid maize being substantially impaired, it is proposed that the axes of rotation (24) of front deflection wheels (26) of the continuous conveyors (22) be positioned obliquely at an angle (32) transversely to the working width of the device (2) and to the picking plane (28), which is defined by the mutually facing front edges of the picking plates (12) assigned to a picking gap (14), such that the axes of rotation (24), considered to be lengthened, intersect above the picking plates (12) at a distance from the picking plane (28), and the drivers (18) formed on the continuous conveyors (22) are for their part positioned upwardly at an angle (30) to the axis of rotation (24) of the deflection wheels (26).

The present disclosure is related to agricultural devices, system, and methods, particularly for detecting and measuring plant stalks during harvest. The system may comprise a harvesting row unit, with a camera, a processing unit, and an in-cab display. The system may additionally include a stalk alignment guide, a leaf shield, an artificial light source, and/or a lens cleaning apparatus.

A combine harvesting head includes harvesting snouts, gathering chains to pull crop stalks into the space between adjacent snouts, roller mechanisms to pull crop stalks downward away from the harvesting head, and stripper plates to strip the crop from its stalks. Each stripper plate assembly has two halves, with the first half having a stalk-contacting edge and a surface extending upward and away from that edge in a first direction, and the second half having a stalk-contacting edge and a surface extending downward and away from that edge in a second direction. The first stripper plate half is positioned at a level that is higher from the ground than the level of the corresponding second stripper plate half, and overlaps or is directly adjacent the second stripper plate half so that there is little or no horizontal gap between the two halves.

A self-propelled forage harvester corn head adapter allows a self-propelled forage harvester to utilize a corn head of the type used to harvest corn with a combine. The adapter includes a frame configured for coupling to a self-propelled forage harvester. A central panel is coupled to the frame and has an opening extending through the central panel. A lower roller assembly has a lower roller positioned to extend along a lower edge of the opening. An upper roller assembly extends across the opening having an upper roller being parallel to the lower roller assembly. The upper roller assembly is movably coupled relative to the central panel such that spacing between the upper roller and the lower roller is adjustable.

A self-propelled forage harvester corn head adapter allows a self-propelled forage harvester to utilize a corn head of the type used to harvest corn with a combine. The adapter includes a frame configured for coupling to a self-propelled forage harvester. A central panel is coupled to the frame and has an opening extending through the central panel. A lower roller assembly has a lower roller positioned to extend along a lower edge of the opening. An upper roller assembly extends across the opening having an upper roller being parallel to the lower roller assembly. The upper roller assembly is movably coupled relative to the central panel such that spacing between the upper roller and the lower roller is adjustable.

A stalk roll having twelve flutes extending radially from the main cylinder along the length of the main cylinder. Within the row unit opposing stalk rolls cooperate to engage and capture the corn stalk, thereafter, controlling and processing the corn stalk. The flutes may be configured with differing edges to facilitate control and movement of the stalk to the point of ear separation within the row unit. The flutes may be configured such that opposing compressive forces acting on the exterior of the stalk at approximately 180 of separation operate to implode the stalk while sharp edges on the flutes operate to cut the stalk into small segments which are deposited on the ground for decomposition.

An attachment for connection to a harvester comprises a plurality of picking devices (2) arranged next to each other and in a distributed manner along the working width. Each picking device (2) has a picking gap (6), below which are disposed at least two picking rotors (10) which can be driven to rotate in opposite directions, the picking rotors (10) being provided with flutes (12), which project in a radial direction beyond the rotor casing (16) and the enveloping circles (20) of which mesh with each other. To propose a way of easily adapting the picking rotors to different harvesting conditions without having to replace them all, the invention proposes for one or more shear bars (18) which are releasably connected to the picking rotor (10) and/or to the flutes (12) to be inserted in the intermediate space (22) between adjacent flutes (12) of a picking rotor (10), the shear bars filling portions of said intermediate space during a rotating movement of the picking rotors (10).

An attachment for connection to a harvester comprises a plurality of picking devices (2) arranged next to each other and in a distributed manner along the working width. Each picking device (2) has a picking gap (6), below which are disposed at least two picking rotors (10) which can be driven to rotate in opposite directions, the picking rotors (10) being provided with flutes (12), which project in a radial direction beyond the rotor casing (16) and the enveloping circles (20) of which mesh with each other. To propose a way of easily adapting the picking rotors to different harvesting conditions without having to replace them all, the invention proposes for one or more shear bars (18) which are releasably connected to the picking rotor (10) and/or to the flutes (12) to be inserted in the intermediate space (22) between adjacent flutes (12) of a picking rotor (10), the shear bars filling portions of said intermediate space during a rotating movement of the picking rotors (10).

A row crop header for a harvester having a subframe removably coupleable to a feeder housing of the harvester. A pivot assembly is supported by the subframe permitting first and second header sections to pivotably move between raised and lowered positions together or independently of the other. A cross-auger center suspension assembly rotateably supports one end of the first cross-auger section and one end of the second cross-auger section as the first and second header sections pivotally move between the raised and lowered positions.