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.

A stomping shoe assembly for an agricultural harvester header including a stomping shoe having a substantially planar proximal end for connecting to an agricultural harvester header, and a curved distal end for engaging crop. The assembly further includes a stalk cutter having an elongated body mounted to the stomping shoe and extending from the stomping shoe from the curved distal end to the substantially planar proximal end. Also provided is an agricultural harvester header including the stomping shoe assembly.

A row crop header for an agricultural machine harvesting a crop having stalks, such as corn. The row crop header includes a frame, a first crop row divider mounted to the frame, and a second crop row divider mounted to the frame and spaced from the first crop row divider to define a space therebetween. A row unit is disposed at the space, wherein the row unit includes a deck assembly defining a gap, the deck assembly including a compliant deck configured to adjust the gap based on contact with the stalks of the crop. The compliant deck includes a plurality of overlapping plates having edges defining the gap where the edges are configured to move responsively to varying diameters of stalks. Crops are separated from the stalks upon contact with the overlapping plates. A gathering chain moves the separated crops toward a collector.

An attachment system for an agricultural vehicle including a feeder housing and a header. The attachment system includes at least one feeder connecting member configured for being located on and movably connected to the feeder housing, and at least one header connecting member configured for being located on the header. The at least one feeder connecting member is automatically connectable and securable to the at least one header connecting member as the feeder housing lifts the header.

Differential speed stalk rolls mountable to a row unit of a row crop head. A first stalk roll body has an outer peripheral speed less than the outer peripheral speed of a second stalk roll body in lateral spaced relation. At least one of the first and second bodies includes a knife defining a knife plane normal to the axis of rotation of the first or second stalk roll. The stalk roll bodies may have modular and interchangeable body segments of different configurations.

A row crop header for an agricultural machine harvesting a crop having stalks, such as corn. The row crop header includes a frame, a first crop row divider mounted to the frame, and a second crop row divider mounted to the frame and spaced from the first crop row divider to define a space therebetween. A row unit is disposed at the space, wherein the row unit includes a deck assembly defining a gap, the deck assembly including a compliant deck configured to adjust the gap based on contact with the stalks of the crop. The compliant deck includes a plurality of overlapping plates having edges defining the gap where the edges are configured to move responsively to varying diameters of stalks. Crops are separated from the stalks upon contact with the overlapping plates. A gathering chain moves the separated crops toward a collector.

Disclosed herein are various devices, systems, and methods for use in agricultural, particularly for use in harvesting agricultural crop such as corn. Various implementations relate to methods and devices for measuring plant stalk cross-sectional area during harvest and providing additional methods of predicting and displaying yield on a row-by-row level in real time.

A row unit of a corn header includes a first deck plate, a second deck plate, and a gap between the first and second deck plates. A position of one or both of the deck plates may be adjusted by a linkage assembly including at least one arm pivotably coupled, at a first end, to one or both of the deck plates and, at a second end, to an actuator. The actuator may be controlled by a controller to move one or both of the deck plates based on signals received from an ear size sensor such as a camera that measures various parameters of corn and also based on a kernel depth of the type of corn to be harvested.

An agricultural header for use with an agricultural harvester includes a header frame, a first row unit having a first row unit frame coupled to the header frame, and a second row unit having a second row unit frame coupled to the header frame. The header also includes a casting body coupled to the first row unit frame, a sensing unit of a stalk-diameter sensing system including a frame portion and a stalk feeler deflectably coupled to the sensing unit, and a point assembly pivotally coupled to the header frame. The point assembly at least partially covers the sensing unit. A crossbar member includes a first portion and a second portion with the first portion being pivotally coupled to the casting body to pivot about a first pivot axis. The crossbar member is pivotable about the first pivot axis between a first position and a second position.

An agricultural system comprises a stalk-diameter sensing system associated with a row unit and configured to sense diameter-related data of respective stalks and generate signals based on the diameter-related data. Deck plates associated with the row unit are spaced apart to define a deck plate spacing. A deck plate positioning system is coupled to at least one of the deck plates to adjust the deck plate spacing. A control system is configured to communicate with the stalk-diameter sensing system and the deck plate positioning system. The control system is configured to receive the signals, determine a statistical representative stalk diameter for a sample of stalks based on the diameter-related data, determine a target deck plate spacing based on the statistical representative stalk diameter, and output a control signal to command the deck plate positioning system to set the deck plate spacing based on the target deck plate spacing.