A planting unit for a seeding machine having a seed meter with a metering member that moves seed sequentially along a first path to a release position at which the seed is moving in a first direction and a delivery system adapted to take seed from the metering member at the release position and control movement of the seed from the seed meter to a discharge location adjacent a seed furrow formed in soil beneath the seeding machine. The delivery system, at the release position, moves seed in a second direction along a second path. A blocking member located adjacent the first path immediately preceding the release position prevents movement of the seed in the second direction until the seed has passed the blocking member.

Metering devices for an agricultural implement are provided for applying a field input, for example, pneumatically delivered granular product including seed or fertilizer or sprayed liquid product including fertilizer and the like, to an agricultural field. In the applying of the field input, the rate of application of the dispensers of one section of the implement can be collectively varied in relation to the rate of application of the dispensers of a different section of the implement frame.

An agricultural seed planter is provided. The agricultural seed planter has a large diameter rotating planting wheel with fingers or teeth spaced around the periphery of the planting wheel. The teeth are positioned so as to achieve a spacing of the seeds when planted in the soil. The teeth have a small dimple in the end and an even smaller hole passing through the entire length. The dimple provides a place for the seed to sit in and the small hole allows positive or negative air pressure to be transmitted to the seed. The negative air pressure creates a vacuum suction that attaches the seed to the teeth, and the positive air pressure releases the seed from the teeth. In an example implementation, the wheel includes many individual mechanical modules that are linked together to form the wheel.

A system for controlling the speed of a seed-planting implement, the system having: a furrow closing assembly including at least one ground engaging component configured to rotate relative to soil within a field as the seed-planting implement is moved across the field, the furrow closing assembly configured to close a furrow formed in the soil by the seed-planting implement; a sensor configured to capture data indicative of an operational parameter of the furrow closing assembly; and an implement-based controller supported on the seed-planting implement and being communicatively coupled to the sensor, the implement-based controller being configured to initiate control of a drive parameter of a work vehicle configured to tow the seed-planting implement based on sensor data received from the sensor in a manner that adjusts the speed of the seed-planting implement.

An agricultural implement system having: a row unit coupled to a tool bar of an agricultural implement; an opener system coupled to a chassis of the row unit and configured to engage soil to form a trench; a downforce system configured to apply a downforce to the row unit to adjust a contact force between the row unit and the soil; a soil condition sensor configured to detect a condition of the soil and/or an operational sensor configured to detect operation of the agricultural implement system; a closing system, configured to close the trench created by the opener system; and a controller coupled to the soil condition sensor and/or the operational sensor, wherein the controller is configured to control the downforce system and the closing system in response to feedback from the soil condition sensor and/or the operational sensor.

An agricultural implement system having: a row unit coupled to a tool bar of an agricultural implement; an opener system coupled to the row unit and configured to engage soil to form a trench; a soil condition sensor; a closing system, configured to close the trench created by the opener system, the closing system comprises: a first disk configured to engage the soil and close the trench; a second disk configured to engage the soil and close the trench; and a controller configured to couple to the soil condition sensor and control a position or orientation of the first disk or the second disk in response to feedback from the soil condition sensor.

A trench closing sensor adapted to mount to an agricultural implement to detect whether a seed trench is sufficiently closed with soil to ensure good seed to soil contact. The trench closing sensor may also detect the amount of compaction of the soil over the seed within the seed trench. The trench closing sensor may be in the form of a seed firmer from which a drag wire extends. As the open seed trench and drag wire are covered with soil, instrumentation measures or detects whether the seed trench is being adequately closed with soil by measuring the amount of force required to pull the wire through the soil or by measuring the amount of strain, pulling force or tension in the wire or by measuring the amount of soil pressure acting on the wire. The trench closing sensor may include other sensors for detecting soil characteristics.

Provided is a seeder assembly for an aerial vehicle as shown and described. The distribution assembly includes a frame selectively attachable to an aerial vehicle and at least one distribution device attached to the frame. The distribution device having a body defining a cavity to receive a plurality of products and a barrel to discharge the plurality of products. A control device configured to communicate with the aerial vehicle and the distribution device to coordinate the timing that products are discharged and a spacing of a subsequent discharged product relative to the speed of the aerial vehicle. A system, method, and cartridge device associated with the distribution assembly are also contemplated by this disclosure.

A trench closing sensor adapted to mount to an agricultural implement to detect whether a seed trench is sufficiently closed with soil to ensure good seed to soil contact. The trench closing sensor may also detect the amount of compaction of the soil over the seed within the seed trench. The trench closing sensor may be in the form of a seed firmer from which a drag wire extends. As the open seed trench and drag wire are covered with soil, instrumentation measures or detects whether the seed trench is being adequately closed with soil by measuring the amount of force required to pull the wire through the soil or by measuring the amount of strain, pulling force or tension in the wire or by measuring the amount of soil pressure acting on the wire. The trench closing sensor may include other sensors for detecting soil characteristics.

A pressure gradient or differential in a product distribution line for conveying granular particulate material, including at least one of a seed or a fertilizer, in an air flow to an agricultural field consistently decreases as air speed and velocity in the product distribution line decreases until a critical air speed is reached. Below the critical air speed, the particulate material is susceptible to falling out of the air flow to potentially cause a blockage in the system. A control system efficiently determines an optimum operating velocity for an air flow that is above the critical air speed yet below a maximum air speed associated with inefficient operation. The control system retains the air flow setting in a data structure for later retrieval.