A distribution device, in particular a sowing machine, for distributing a good, with at least one storage container and at least one discharge apparatus. The storage container is connected to the discharge apparatus by at least one outlet channel such that the good arranged in the storage container can be transferred to the discharge apparatus such that the good can be distributed by the discharge apparatus. The distribution device has a first and a second part. The first and the second parts can be moved in relation to each other such that the outlet channel can be at least partially exposed.

A spreading control switch structure of a spreader has a spreading tube, a positioning member, a main tube and a switch unit. With the positioning member and the switch unit, the opening and closing state and the spreading amount of the present invention can be adjusted by the circular plate of the valve in the spreading tube. The size of the pipe in the spreading tube is opened to control the blanking amount. On the other hand, the circular plate of the valve can be kept opened in the spreading tube all time without the switching handle being pressed. Therefore, it is easier and less laborious to execute the spreading process.

A spreading control switch structure of a spreader has a spreading tube, a positioning member, a main tube and a switch unit. With the positioning member and the switch unit, the opening and closing state and the spreading amount of the present invention can be adjusted by the circular plate of the valve in the spreading tube. The size of the pipe in the spreading tube is opened to control the blanking amount. On the other hand, the circular plate of the valve can be kept opened in the spreading tube all time without the switching handle being pressed. Therefore, it is easier and less laborious to execute the spreading process.

An agricultural product distribution system includes a fan configured to provide an air flow that fluidizes and transports particulate material throughout the agricultural product distribution system. The fan includes an impeller, an inlet position on a first axial side of the fan, and an outlet position on a peripheral side of the fan. The agricultural product distribution system includes a power transfer shaft having a first end non-rotatably coupled to the impeller, wherein the power transfer shaft extends through the inlet of the fan.

An agricultural product distribution system includes a fan configured to provide an air flow that fluidizes and transports particulate material throughout the agricultural product distribution system. The fan includes an impeller, an inlet position on a first axial side of the fan, and an outlet position on a peripheral side of the fan. The agricultural product distribution system includes a power transfer shaft having a first end non-rotatably coupled to the impeller, wherein the power transfer shaft extends through the inlet of the fan.

A pressure gradient or differential in a product distribution line for conveying granular particulate material, including at least one of seed or 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 cause a blockage in the system. Pressure sensors arranged in the product distribution line are monitored for effectively controlling an air source producing the air flow. A diameter of the product distribution line increases between upstream and downstream locations for monitoring with greater sensitivity.

A pressure gradient or differential in a product distribution line for conveying granular particulate material, including at least one of seed or 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 may become susceptible to falling out of the air flow to potentially cause a blockage in the system. Accordingly, pressure sensors arranged in the product distribution line can be used to generate an air flow at an optimum velocity above the critical air speed yet below a maximum air speed associated with inefficient operation. The air flow can be adjusted to maintain the optimum velocity despite changes in at least one of a type of particulate material or a rate at which the particulate material is metered.

The present invention is directed to an applicator having an agricultural product conveying system which transfers particulate material from one or more source containers to application equipment on demand, and meters the material at the application equipment. The conveying system includes an inline metering system including a number of metering devices associated with each compartment of a particulate material tank on the applicator to meter the particulate material disposed within each compartment. The individual metering devices include gates to initially enable the particulate material from a compartment to enter the metering device, and a rotary metering shaft to meter the flow of the particulate material into the conduits while limiting the passage of pressurized air through the metering device and into the compartment. The individual metering devices also include individual motors to control the operation of the metering devices independently from one another that can allow with sectional control and turning compensation.

The present invention is directed to an applicator having an agricultural product conveying system which transfers particulate material from one or more source containers to application equipment on demand, and meters the material at the application equipment. The conveying system includes an inline metering system including a number of metering devices associated with each compartment of a particulate material tank on the applicator to meter the particulate material disposed within each compartment. The individual metering devices include gates to initially enable the particulate material from a compartment to enter the metering device, and a rotary metering shaft to meter the flow of the particulate material into the conduits while limiting the passage of pressurized air through the metering device and into the compartment. The individual metering devices also include individual motors to control the operation of the metering devices independently from one another that can allow with sectional control and turning compensation.

An improved particulate metering system is provided. The system includes a flow path having an inlet in communication with an intake and an outlet in communication with a discharge. The flow path receives a first input and a plurality of inputs, each of the plurality of inputs having a separate origin. A mixing area within the flow path comprises a confluence of the first input and one or more of the plurality of inputs. One or more metering controls are in operable communication with the first input and the plurality of inputs for controlling a blend of the plurality of inputs at the confluence.