A particle delivery system of an agricultural row unit includes a particle belt housing having a particle engagement aperture configured to receive a particle and a particle exit aperture configured to expel the particle toward a trench in soil. The particle delivery system includes a particle belt having a particle engagement section configured to receive the particle via the particle engagement aperture and a particle exit section configured to expel the particle via the particle exit aperture. The particle exit section is positioned adjacent to the particle exit aperture, the particle belt extends generally parallel to the trench at the particle exit section, the particle engagement section is positioned adjacent to the particle engagement aperture, and the particle belt at the particle engagement section extends at an angle between zero degrees and ninety degrees relative to the particle belt at the particle exit section.

A planting unit for a seeding machine having a frame member and a seed meter mounted thereto. The seed meter has a housing and a metering member rotatably mounted therein. The metering member has a sidewall with an inner surface and an outer surface with a rim portion of the sidewall adjacent an outer edge of the sidewall. The inner surface of the side wall and the housing form a trough at a bottom portion of the metering member to hold a seed pool. A mechanical seed delivery system takes seed from the metering member and moves seed to a discharge location adjacent a seed furrow formed in soil beneath the seeding machine.

A planting unit for a seeding machine having a frame member and a seed meter mounted thereto. The seed meter has a housing and a metering member rotatably mounted therein. The metering member has a sidewall with an inner surface and an outer surface with a rim portion of the sidewall adjacent an outer edge of the sidewall. The inner surface of the side wall and the housing form a trough at a bottom portion of the metering member to hold a seed pool. A mechanical seed delivery system takes seed from the metering member and moves seed to a discharge location adjacent a seed furrow formed in soil beneath the seeding machine.

Agricultural electronics include many components. The components can be connected via an electronic link that connects the various components to components of an agricultural implement. This can include the use of a component type identifier and a master module. The identifier and the module can communicate data, including identification data and instructional data, to easily acknowledge and operate various electrical components of the agricultural implement. Additional sensors can be included to provide even additional data that is communicated between the module and the components of the agricultural implement to aid in providing instructions for operation and to provide additional data information.

A commodity debris guard for a commodity delivery apparatus may comprise a debris guard configured to mitigate debris from engaging with an endless member. The debris guard may comprise a first debris guard operably connected to a housing. The first debris guard may comprise a base and upwardly extending side portions. The first debris guard may be configured to mitigate debris from contacting an endless member positioned at least partially within the housing. A second debris guard may be operably connected to the housing and disposed forward and below the first debris guard. The second debris guard may be configured to mitigate debris from contacting the endless member comprising. The second debris guard may comprise a base, upwardly extending side portions, and an extension portion configured to channel commodity as it exits the extension member to an associated furrow of an underlying surface.

A commodity debris guard for a commodity delivery apparatus may comprise a debris guard configured to mitigate debris from engaging with an endless member. The debris guard may comprise a first debris guard operably connected to a housing. The first debris guard may comprise a base and upwardly extending side portions. The first debris guard may be configured to mitigate debris from contacting an endless member positioned at least partially within the housing. A second debris guard may be operably connected to the housing and disposed forward and below the first debris guard. The second debris guard may be configured to mitigate debris from contacting the endless member comprising. The second debris guard may comprise a base, upwardly extending side portions, and an extension portion configured to channel commodity as it exits the extension member to an associated furrow of an underlying surface.

A work vehicle with a metering system, airflow system, and a covering structure moveable between various positions for user access includes features that facilitate assembly and/or disassembly of the metering system. The work vehicle has a venturi structure with a plurality of venturi tubes that are disposed in a compact arrangement.

A furrow closing unit for a planting unit includes a frame adapted to be pivotally coupled with the planting unit, and a pair of coulter blades rotatably attached to the frame and adapted to move soil into a seed groove to facilitate a closing of the seed groove. The furrow closing unit further includes a basket assembly fixedly attached to the frame and having a basket adapted to roll over a soil surface behind the pair of coulter blades. The basket includes a pair of end caps and a plurality of spokes extending between the pair of end caps. The plurality of spokes is arrayed circularly around a central axis of the basket and is arranged spaced apart from each other.

The present invention discloses an opposite belt-type precise seeding device. The opposite belt-type precise seeding device comprises a seed metering tube consisting of a U-shaped shell and a cover plate, two conveying devices provided inside the seed metering tube in parallel, and a conveying plate provided at the lower end of the seed metering tube. The opposite belt-type precise seeding device belongs to the field of agricultural machinery. In a seeder, a tubular seed conveying tube is usually used for guiding movement of seeds, but the movement of the seeds in the seed conveying tube has certain randomness, so that the seed distance consistency of the seeds in a seed bed is reduced. Through control of the seeds by the conveying devices, the stable movement of the seeds is achieved and the seed distance consistency of the seeds in the seed bed is guaranteed.

The present invention discloses an opposite belt-type precise seeding device. The opposite belt-type precise seeding device comprises a seed metering tube consisting of a U-shaped shell and a cover plate, two conveying devices provided inside the seed metering tube in parallel, and a conveying plate provided at the lower end of the seed metering tube. The opposite belt-type precise seeding device belongs to the field of agricultural machinery. In a seeder, a tubular seed conveying tube is usually used for guiding movement of seeds, but the movement of the seeds in the seed conveying tube has certain randomness, so that the seed distance consistency of the seeds in a seed bed is reduced. Through control of the seeds by the conveying devices, the stable movement of the seeds is achieved and the seed distance consistency of the seeds in the seed bed is guaranteed.