The pressure of a fluid passing through several air entrainers can be controlled so as to more effectively move particulate material from one or more bulk hoppers to an end location. This is accomplished through use of an integrated, electric fluid pressure source, such as a fan in one or more of the segments. The pressure can be increased based upon a speed of an agricultural implement or a weight of the particulate material and/or the pneumatic flow can compensate for distance the seed must travel before planting. The entrainer can thus be installed with a high speed planting implement, thereby reducing downtime and facilitating repair.

An apparatus and methods for delivering seed from a metering device to a furrow. In one embodiment, a seed meter entrains and releases seed from a seed disc at a seed release location. The released seed is directed into a seed conveyor by a loading wheel. The seed conveyor conveys the seed toward the soil and releases the seed with a rearward relative velocity.

A planter system includes a planter having an unloading valve and a controller. The unloading valve is fluidly coupled between an inlet and an outlet of a pump. The unloading valve is configured to receive a fluid at a supply pressure, to supply a first portion of the fluid from the inlet to a hydraulic planter system at an unloading pressure less than the supply pressure, and to recirculate a remainder of the fluid to the pump via the outlet. The controller is communicatively coupled to the unloading valve and to the pump. The controller is configured to control the pressure of the fluid supplied to the inlet and to control the unloading pressure of the first portion supplied to the hydraulic planter system.

A flow control assembly for an agricultural metering system includes a first gate control shaft configured to drive a first gate of a seed meter to transition between an open position and a closed position. The flow control assembly also includes a handle configured to drive the first gate control shaft to rotate via rotation of the handle between a first position that corresponds to the open position of the first gate and a second position that corresponds to the closed position of the first gate. In addition, the flow control assembly includes a locking assembly configured to secure the handle to the first gate control shaft at least while the handle is in the first position, and to enable the handle to be released from the first gate control shaft at least while the handle is in the second position.

Disclosed is an air filtration module for seed planters. The filtration module includes a filter cartridge with a filter media disposed therein. The cartridge is sized and shaped to fit into the stock seed hopper. The filter media is configured to filter out and contain particles of seed coating materials that contain neonicotinoids and/or other airborne contaminants. The filter cartridge can replace the porous seed container wall through which compressed air is discharged out the seed hopper air discharge vent.

The agricultural product application equipment, and in particular, to an agricultural air cart assembly where each distribution line is a self-contained unit with movable shroud portion that provides greater airflow control in each of the product distribution lines.

This document relates to a method and a device for feeding granular material in an agricultural implement and to an agricultural implement comprising such a device. The method comprises providing a take-up zone (102), the extent of which, viewed in a horizontal plane, is defined by a roof (1022, 1026) above the take-up zone, providing side walls (1023, 1027) extending downward from the roof, so that a space (S), which is open in the downward direction and toward an outlet (102b), is formed between the roof (1022, 1026) and the side walls (1023, 1027), providing an airflow (F) through the take-up zone (102) in the direction toward the outlet (102b) from the take-up zone, feeding the material (M) to the take-up zone (102) with the aid of gravity, so that the material falls in a direction transversely to the airflow (F) into the take-up zone (102) and thus delimits the space (S) in the downward direction, providing a part (1022, 1025) which is adjustable between at least two positions, and, with the aid of the adjustable part (1022, 1025), regulating a flow rate of the airflow (F) in a space between the material (M) and the roof (1022, 1026).

The present disclosure includes an agricultural system having first and second product meters configured to meter product to first and second lines, respectively. First and second motors are coupled to the first and second product meters and configured to drive them at first and second metering rates, respectively. An air source is configured to provide first and second airflows to the first and second lines, respectively. A controller electrically coupled to the first and second motors is configured to receive first and second inputs indicative of first and second numbers of first and second outlets fluidly coupled to the first and second lines, respectively. The controller is configured to instruct the first and second motors to drive the first and second product meters at the first and second metering rates, respectively, based on the first and second inputs, and to instruct the air source to provide the first and second airflows with first and second dynamic pressures or first and second velocities.

A method for identifying a flow of commodity through a commodity distribution system. The method including providing a tank configured to contain a commodity, selectively distributing commodity from the tank to a drill assembly to be distributed to an underlying surface, and monitoring the flow of commodity from the tank to the drill assembly with a camera to identify flow characteristics.

A seeding device system is presented for use with helicopters and other vehicles. The system includes a bulk seed container, a feed tube that connects the seed container to a metering device that precisely meters out seed, a flow control system that controls operation of the metering device, and a blower connected to a venturi that blows the seed outward from the helicopter. When seed is metered out of the metering device, the seed is sucked into the venturi and blown outward. The seed container is held in the back seat or cargo area of the helicopter and the blower, venturi and metering device are positioned exterior to the helicopter. This arrangement does not adversely affect the operational characteristics or aerodynamic properties of the helicopter. In addition, all components of the system are rigidly connected to the helicopter thereby increasing safety and control of the helicopter.