A particulate material metering system includes a controller configured to determine a radius of curvature of a path of a lead vehicle coupled to an agricultural implement. The controller is configured to determine a lead time of the lead vehicle relative to the agricultural implement based on a speed of the lead vehicle and/or the agricultural implement. The controller is configured to determine a radius of curvature of a path of the agricultural implement based on the radius of curvature of the path of the lead vehicle at a determination time, in which the determination time is a current time minus an offset time, and the offset time is based on the lead time. The controller is configured to determine target particulate material flow rates of respective metering devices of the particulate material metering system based on the radius of curvature of the path of the agricultural implement.

A yaw rate is sensed on a towing vehicle that is towing an air seeder. The sensed yaw rate is used to predict a future yaw rate on a planting implement of the air seeder. An application rate of material is varied across the application implement based upon the predicted yaw rate across the implement.

A particulate material delivery system for an agricultural implement including, an inductor box configured to receive particulate material from a tank, the inductor box including, an inductor segment comprising an air bypass channel extending through a particulate material supply chamber, wherein the particulate material supply chamber is configured to receive the particulate material for distribution to at least one row unit, and the air bypass channel is configured to guide airflow through the particulate material supply chamber without interacting with a flow of the particulate material through the particulate material supply chamber, and an airflow control device in communication with the inductor segment and configured to control the airflow through the air bypass channel.

A system for automatically controlling air flow rate within an agricultural system is provided. One system for distributing an agricultural product includes a metering system configured to meter the agricultural product from a storage tank into a conduit. The system includes an air conveyance system to provide an air stream for moving metered agricultural product in the conduit toward a distribution device. The air conveyance system comprises one or more sensors to monitor the product status and/or the air stream inside the conduit. The system also includes control circuitry configured to control air flow rate based on the product status and/or the air stream inside the conduit and/or the geographic location of the system.

A system for controlling fan operation of an agricultural implement includes a tank configured to store an agricultural product and a conduit configured to receive the dispensed agricultural product. Furthermore, the implement includes a conduit fan configured to supply pressurized air to the conduit such that the pressurized air conveys the dispensed agricultural product through the conduit and a tank fan configured to supply pressurized air to the tank. Additionally, a computing system is configured to determine a first pressure of the pressurized air within the conduit and a second pressure of the pressurized air within the tank based. Moreover, the computing system is configured to determine a pressure differential between the first and second pressures. Furthermore, the computing system is configured to control a flow of the pressurized air supplied to the tank based on the determined pressure differential.

A conveyor apparatus includes a conveyor sloping upward from a lower conveyor intake to an upper conveyor discharge and with a downspout extending down from the conveyor discharge. Wheels support the conveyor for movement along the ground, and a downspout control is operative to remotely move a bottom end of the downspout radially with respect to the conveyor discharge. A method is provided as well for using the conveyor to conveniently transfer a first agricultural product from a first transport vehicle to a first tank on the air seeder cart, and for transferring a second agricultural product from a second transport vehicle to a second tank.

A fluid line connection for a manifold of a pneumatic distribution system for an agricultural air seeder. The fluid line connection has a male connector extending from the manifold and a plurality of threads on an exterior surface, a fitting connector configured to retain a primary tube thereon, the fitting connector defining a lip, and a locking ring having a plurality of threads and a receiving portion on an interior surface, the receiving portion configured to receive the lip to retain the fitting connector with the locking ring, and the plurality of threads of the locking ring configured to engage the plurality of threads on the male connector. The fitting connector is removable from the male connector by disengaging the locking ring without requiring axial movement of the fitting connector.

A metering device for an agricultural machine for outputting granular solids out of at least one storage container to at least one dispensing unit by means of, in particular, a pneumatic conveyor system, has a metering housing. The metering housing comprises at least one mounting flange on the storage container-side and/or conveyor system-side as well as at least one inflow opening and at least one discharge opening for the granular solid. The at least one mounting flange is formed as polygon or circular.

In an embodiment, an autonomous vehicle system includes an autonomous vehicle. The autonomous vehicle includes a communications system configured to communicate with the base station, and a control system communicatively coupled to the communications system, the control system comprising a processor. The processor is configured to receive driving commands from the base station, execute the driving commands to drive the autonomous vehicle, and execute a vehicle controller-to-subsystems latency protocol to determine a communications latency between a vehicle controller and vehicle subsystems, and to stop the autonomous vehicle if the communications latency exceeds a user-configurable latency value, wherein the vehicle controller and vehicle subsystem are disposed in the autonomous vehicle.

The controller that receives at least one sensor signal indicative of a measured profile of a particulate material within a storage tank of an agricultural system. The controller also determines whether a variation between the measured profile and a target profile is greater than a threshold value. The controller outputs a first output signal to a user interface indicative of instructions to inform an operator of a profile variation, outputs a second output signal to an agitator indicative of activation of the agitator, or a combination thereof, in response to determining that the variation between the measured profile and the target profile is greater than the threshold value.