A conveyor roller structural assembly for harvesters, such as those intended for harvesting tall and stalky plants, such as sugarcane and sweet sorghum, with this structural assembly being designed and developed to eliminate material losses through the displacement openings of the floating rollers. The conveyor roller structural assembly is formed by a conveyor roller whose bearings are mounted on support bases, and these support bases are anchored on a pivoting bar which is rotatable about its axis, said structural assembly also comprising at least one closing tab which is mounted in an articulated manner with the support base through a connector element, and it is configured to close a displacement opening provided in the side wall of the chassis of the harvester.

A conveyor roller structural assembly for harvesters, such as those intended for harvesting tall and stalky plants, such as sugarcane and sweet sorghum, with this structural assembly being designed and developed to eliminate material losses through the displacement openings of the floating rollers. The conveyor roller structural assembly is formed by a conveyor roller whose bearings are mounted on support bases, and these support bases are anchored on a pivoting bar which is rotatable about its axis, said structural assembly also comprising at least one closing tab which is mounted in an articulated manner with the support base through a connector element, and it is configured to close a displacement opening provided in the side wall of the chassis of the harvester.

A row unit for a header of an agricultural harvester is provided that includes a first longitudinally extending stripping plate and a second longitudinally extending stripping plate each mounted on a frame and each having opposed stripping edges which define a gap between the first stripping plate and the second stripping plate. The row unit includes both operator-selected macro adjustment of the gap and automatic micro adjustment of the gap. The micro adjustment occurs on both deck plates. The micro adjustment is achieved through resilient members positioned functionally between the deck plates and the row unit frame.

A row unit for a header of an agricultural harvester is provided that includes a first longitudinally extending stripping plate and a second longitudinally extending stripping plate each mounted on a frame and each having opposed stripping edges which define a gap between the first stripping plate and the second stripping plate. The row unit includes both operator-selected macro adjustment of the gap and automatic micro adjustment of the gap. The micro adjustment occurs on both deck plates. The micro adjustment is achieved through resilient members positioned functionally between the deck plates and the row unit frame.

A stalked crop harvesting header comprising multiple harvesting units each comprising a pair of deck plates defining a channel, a pair of snapping rollers mounted below the deck plates and adapted to pull stalks downwardly through the channel, a pair of gathering chains provided with cams, the gathering chains extending between a first pair of gears located at a front end of the harvesting unit and a second pair of gears located at a back end of the harvesting unit, wherein each harvesting unit further comprises a pair of stalk guiders positioned to rotate around axes coinciding with respective axes of the first pair of gears, wherein the stalk guiders each comprise an upper stalk guiding wheel and a lower stalk guiding wheel which are interconnected, and wherein a cutting element is provided below the lower stalk guiding wheel to cut stalks while being guided by the stalk guider.

A stalked crop harvesting header comprising multiple harvesting units each comprising a pair of deck plates defining a channel, a pair of snapping rollers mounted below the deck plates and adapted to pull stalks downwardly through the channel, a pair of gathering chains provided with cams, the gathering chains extending between a first pair of gears located at a front end of the harvesting unit and a second pair of gears located at a back end of the harvesting unit, wherein each harvesting unit further comprises a pair of stalk guiders positioned to rotate around axes coinciding with respective axes of the first pair of gears, wherein the stalk guiders each comprise an upper stalk guiding wheel and a lower stalk guiding wheel which are interconnected, and wherein a cutting element is provided below the lower stalk guiding wheel to cut stalks while being guided by the stalk guider.

A harvesting attachment for whole plant harvesting includes a pick-up for picking up plants from a field, a first transverse conveyor belt and a second transverse conveyor belt for conveying the plants picked up transversely in a direction toward of a longitudinal center plane of the harvesting attachment, and two longitudinal conveyor belts which are arranged side-by-side and adjacent to the longitudinal center plane of the harvesting attachment and are set up to convey the plants entering from the transverse conveyor belts rearward to a rear discharge point of the harvesting attachment. The two longitudinal conveyor belts are inclined vertically upward in a direction toward the center plane at least over part of their length along the center plane.

A harvesting attachment for whole plant harvesting includes a pick-up for picking up plants from a field, a first transverse conveyor belt and a second transverse conveyor belt for conveying the plants picked up transversely in a direction toward of a longitudinal center plane of the harvesting attachment, and two longitudinal conveyor belts which are arranged side-by-side and adjacent to the longitudinal center plane of the harvesting attachment and are set up to convey the plants entering from the transverse conveyor belts rearward to a rear discharge point of the harvesting attachment. The two longitudinal conveyor belts are inclined vertically upward in a direction toward the center plane at least over part of their length along the center plane.

An outer stalk divider for an attachment for harvesting row crop, in particular for a corn picker or corn header, includes a base body that extends in a traveling direction and a surface that extends in the traveling direction on an upper side, a hood, which is situated at the front on the base body as viewed in the traveling direction, and tapers in the traveling direction, and a cover element which, in the traveling direction, is situated behind the hood and on the upper side. The cover element extends at least partially along the surface of the base body, and is at least partially arched in design on an outer surface facing away from the surface. The cover element may be adjustable relative to the base body.

An outer stalk divider for an attachment for harvesting row crop, in particular for a corn picker or corn header, includes a base body that extends in a traveling direction and a surface that extends in the traveling direction on an upper side, a hood, which is situated at the front on the base body as viewed in the traveling direction, and tapers in the traveling direction, and a cover element which, in the traveling direction, is situated behind the hood and on the upper side. The cover element extends at least partially along the surface of the base body, and is at least partially arched in design on an outer surface facing away from the surface. The cover element may be adjustable relative to the base body.