The present invention relates to a no-till stem and root extractor system that has directionality, the ability to fit into tight clearance areas, which not only pushes the stalks down and splinters them, but extracts the root ball from the soil as well, enhances decomposition of remaining cellulose residue, and minimizes root ball interference with seedlings properly engaging the soil. A conveyor chain crop remnant extractor assembly has a pair of flexible conveyor chains, a pair of coupling conveyor arms, two pairs of rotatable wheels, a pinch cylinder, and a plurality of cross-slat bars. As the device moves along the crop remnants, the pair of flexible conveyor chains, guided and retained by the two pairs of rotatable wheels, pull the stalks and root balls from the earth, pinch, and pulverize the complete crop remnants.

An attachment of a harvesting head of a combine is disclosed. The attachment includes a main body and a flange fixedly connected to the main body. The flange is connected to the main body at an angle and the flange has at least one mounting aperture. The flange is configured to be attached to the harvesting head of a combine by the at least one mounting aperture. When the flange is attached to the harvesting head of the combine and the combine is performing a harvesting operation, a furthest portion of the main body away from the flange is positioned above a lowest portion of the harvesting head from a ground surface.

An agricultural device associated with reduced tillage techniques in a field includes a frame and at least one mower module supported by the frame, the at least one mower module positionable to cut plant matter between adjacent crop rows in the field. The plant matter has penetrated a previously formed mat of at least partially crushed residual plant matter.

A verge-cutting mower device (20, 30), for example for maintaining roadside verges, has at least one frame (16) intended to be mounted on an automotive agricultural machine (10) and on which there is mounted a piece of cutting/grinding equipment (20) intended to mow or grind plants. The cutting/grinding equipment (20) is actuated using an electric motor (33).

A unique method of harvesting hemp plants is useful to isolate the leafy/flower-budded crop canopy from lower stalks of the plants to enable separate collection thereof, whereby CBD rich leaves/buds of the canopy can be processed more efficiently at an off-site facility. The harvesting method includes performing a first cutting operation at an elevated cutting height, during which the tops of the plants are detached from remnant lower stalks left standing in the field, and the detached plant tops are laid in a windrow or collected in an accompanying collection receptacle. A second cutting operation performed over the same field area at a lower cutting height serves to cut the lower stalks from the field and lay these cuttings into a separate windrow that is entirety isolated from the cut plant tops. This enables separate storage, transport and post-harvest processing of the different materials.

A row crop harvesting header (24) operable to be advanced along a forward travel direction to harvest a series of plants in a crop row. The row crop harvesting header broadly includes a row crop toolbar (48), a crop-gathering row unit assembly, and a plant stalk stomper (42). The row crop toolbar (48) extends laterally relative to the forward travel direction. The row unit assembly is supported by the toolbar (48) to define a forwardly extending row path, with the row unit assembly being operable to collect the crop row along the row path and sever crop stalks as the header (24) moves forwardly. The row unit housing (54) is attached to the row crop toolbar (48) with forward and aft fasteners (44). The plant stalk stomper (42) is attached to the toolbar (48) with at least one of the fasteners (44).

An agricultural working apparatus, for the separation of ground vegetation, in particular a mulching, mowing or a milling apparatus, includes at least one cutting device, having a cutting rail, and at least one adjusting device for the adjustment of the cutting rail. The cutting device has at least one connecting piece, which is arranged laterally in the transverse direction and by means of which the cutting rail is connected to the adjusting device.

A cutting system for a combine harvester has a three-part frame with frame parts articulately joined with each other. A cutter bar, a reel, a central belt conveyor system, and lateral belt conveyor systems for discharging the cut stalk material are supported by the frame. The lateral belt conveyor systems move transversely to the travel direction towards the central belt conveyor system. The central belt conveyor system moves contrary to the travel direction. To prevent accumulation of crop material near the rear wall of the lateral belt conveyor systems, a three-part screw conveyor is arranged near the rear wall and extends across the operating width of the cutting system such that the length of the screw conveyor parts corresponds at least approximately to the width of the frame parts. The screw conveyor parts are powered by a joint drive. Adjacent screw conveyor parts are mutually connected by universal joints.

A header for a combine harvester, the header including a frame mountable to a forward end of the combine harvester, at least one row unit mounted to the frame to receive and process stalks of corn, a stomping shoe mounted to the frame behind the row unit to flatten stalks of corn, and a stalk splitter mounted to frame behind the row unit to split stalks of corn. The face of the stomping shoe is provided with a plurality of structures to guide each stalk of corn along a predefined path on the face while the stalks of corn are flattened. The stalk splitter includes a disk blade biased against the ground for splitting stalks of corn after they are processed by row units of the corn header.

A system for post-harvest or at-harvest determination of pre-harvest strength of a corn stalk wherein the system comprises a stalk stump cutter structured and operable to cut a discarded post-harvest stalk stump to provide a substantially flat and even cross-sectional surface of the stalk stump, an imaging device structured and operable to acquire image data of the stalk stump cross-section, and a computer based data processing system structured and operable to analyze the image data and determine a pre-harvest stalk strength of the corresponding stalk.