The disclosed pneumatic seed meters for small seeds and fine grains may include a rotational disk with a plurality of radially disposed holes. The holes may define a seed path when the rotational disk rotates. The seed meters may also include a sealing structure that is positioned and configured to inhibit seed leakage from the seed meter. The sealing structure may define a seed containment chamber. Various other related methods, systems, and devices are also disclosed.

An agricultural planting machine includes a seed meter configured to meter seed, a transport mechanism configured to transport the seed to a discharge location, and a loader assembly. The loader assembly includes an element having an actuating surface, a hub configured to rotate relative to the actuating surface, and a compartment supported on the hub and configured to receive the seed from the seed meter and to eject the seed into the transport mechanism, the compartment comprising first and second movable elements that are movably coupled to the hub and configured to engage the actuating surface and move relative to the hub based on rotation of the hub relative to the actuating surface.

In one aspect, a calibration method for a seed meter may include controlling an operation of a singulator to apply an initial aggressiveness setting for the singulator. The method may further include controlling the seed meter to rotate a seed transport member of the seed meter relative to a seed chamber of the seed meter containing a plurality of seeds. The method may additionally include performing a calibration cycle, which may include monitoring a first parameter indicative of a number of occurrences of seed multiples as the seed transport member rotates, iteratively adjusting the aggressiveness setting from the initial aggressiveness setting as the first parameter is being monitored, and when the first parameter crosses a first threshold, recording the associated aggressiveness setting as a minimum aggressiveness setting for the singulator.

A method including adjusting a changeable component of a seed planting machine when switching from a first variety of seed to a second variety of seed during planting, wherein the adjusting is based on a location of the planting machine.

An agricultural machine includes a seeding system having a seed transport mechanism configured to transport a seed along a transport route, a seed sensor configured to sense presence of the seed at a first location along the transport route, and a motor configured to drive movement of the seed transport mechanism to transport the seed from the first location to a second location in which the seed is released from the seed transport mechanism. A processing system is configured to track a position of the seed along the transport route based on an indication of the sensed presence of the seed at the first location and detected movement of the seed transport mechanism, and generate a motor operating parameter based on the tracked position of the seed and a target parameter for releasing the seed. The motor of the seeding system is operated based on the motor operating parameter.

A control system for a double-acting air cylinder of an agricultural implement includes a valve assembly configured to control a base end air pressure and a rod end air pressure of the double-acting air cylinder. The control system also includes a controller communicatively coupled to the valve assembly. The controller is configured to determine a target base end air pressure and a target rod end air pressure based on a target force of the double-acting air cylinder and a target damping factor of the double-acting air cylinder. The controller is also configured to control the valve assembly such that a first difference between the base end air pressure and the target base end air pressure is less than a first threshold value and a second difference between the rod end air pressure and the target rod end air pressure is less than a second threshold value.

A product delivery conduit for an agricultural product hopper assembly includes an inlet segment and an outlet segment. The inlet segment is configured to receive agricultural product from an inlet conduit, the outlet segment is configured to output the agricultural product to a storage area within a hopper of the agricultural product hopper assembly, the outlet segment is configured to be oriented substantially vertically while the agricultural product hopper assembly is in a working position, the inlet segment and the outlet segment are configured to position an outlet of the product delivery conduit above the storage area while the agricultural product hopper assembly is in a non-working position, and the outlet segment is configured to be oriented downwardly while the agricultural product hopper assembly is in the non-working position to enable the agricultural product to flow into the storage area.

A particle delivery system of an agricultural row unit includes a shuttle track configured to be disposed adjacent to a particle metering and singulation unit, shuttles movably disposed along the shuttle track, and a track belt disposed inwardly of the shuttle track. Each shuttle is configured to receive a particle from the particle metering and singulation unit at a particle reception section of the shuttle track and release the particle toward a trench in soil at a particle deposition section of the shuttle track. The track belt includes paddles, and each paddle is configured to move a respective shuttle along a particle transfer section of the shuttle track from the particle reception section to the particle deposition section.

An apparatus for separating grains of seed or fertilizer includes a separating device having a housing with a housing base for mounting on an agricultural machine. A releasable housing cover is arranged on the housing base in a releasable manner. A grain sump receives the grains introduced into the housing interior to be separated out. A rotatable separating disc having openings is positioned in the housing interior. An overpressure region is formable in the housing cover on a front side of the separating disc during operation, such that a flow can form from the overpressure region through the openings to the rear side of the disc and grains separated can be localized near the openings. A grain transfer device includes a feed, a wall bushing and an outlet, wherein the separated grains can be introduced through the feed into the bushing and discharged from the housing interior through the bushing.

A particle delivery system of an agricultural row unit includes a particle belt configured to be disposed apart from a particle metering and singulation unit and a particle acceleration system configured to apply a force to a particle to accelerate the particle from the particle metering and singulation unit and to guide the particle toward the particle belt. The particle belt is configured to receive the particle accelerated from the particle metering and singulation unit, and the particle acceleration system is configured to apply the force to the particle to accelerate the particle from the particle metering and singulation unit to the particle belt, such that a particle speed of the particle reaches a target particle speed, is within a target percentage of a belt speed of the particle belt, or both, as the particle reaches the particle belt.