A particulate material leveling system includes an agitating system disposed within a storage tank for a particulate material. The agitating system includes a drive system and a shaft coupled to the drive system. Further, the drive system drives the shaft to rotate about a central axis. The agitating system also includes a wrapped wire coupled to the shaft. The wrapped wire extends around the shaft along a helical path in an axial direction and a circumferential direction, and the wrapped wire moves the particulate material in the axial direction in response to rotation of the shaft in a first direction about the central axis.

A particulate material sensing and agitation control system includes a controller with a memory and a processor, where the controller is configured to receive at least one sensor signal indicative of a measured profile of a particulate material within a storage tank of an agricultural system, determine whether a variation between the measured profile and a target profile is greater than a threshold value, and output a first output signal to a user interface indicative of instructions to inform an operator of a profile variation, output a second signal to an agitating system indicative of activation of the agitating system, 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.

A nutrient distributor in accordance with the present disclosure includes a vehicle with a frame, a prime mover, and a distribution system. The distribution system conveys dry nutrients to rowed crops.

An agricultural machine includes a metering system comprising one or more meters configured to meter particulate material into a first material distribution line and a second material distribution line, a first sensor configured to generate a first sensor signal indicative of a first measure of a flow of the particulate material in the first material distribution line, a second sensor configured to generate a second sensor signal indicative of a second measure of the flow of the particulate material in the first material distribution line, and a control system. The control system is configured to receive an indication of a sensed flow rate of the particulate material in the second material distribution line, obtain an adjusted flow rate indication by applying, to the sensed flow rate, a rate offset based on the first and second sensor signals, and control the metering system based on the adjusted flow rate indication.

The present invention relates to a fertilizer allocation system and fertilizer allocation method. The fertilizer allocation system includes a sprayer, a plurality of solution tanks, a camera, a processor, data storage unit and a controller. The sprayer connects to solution tanks by a flow switch and spray fertilizer, which in solution tanks to crop. The camera takes a picture of a crop and the processor compared the picture with a plurality of identification data stored on the data storage unit, then judges a growing situation of crop and generates an allocation information. The controller receives the allocation information and adjust the flow switch to change the flow of fertilizer so that crop get desired element.

In one aspect, a liquid tank assembly is provided and configured to be mounted to a tractor. The liquid tank assembly includes a first tank configured to contain liquid, a second tank configured to contain liquid, a first support frame coupled to and supporting the first tank, and the first support frame includes a first mounting member configured to mount the first support frame to the tractor. The liquid tank assembly also includes a second support frame coupled to and supporting the second tank. The second support frame includes a second mounting member configured to mount the second support frame to the tractor, and the first support frame is coupled to the second support frame. In one aspect, a liquid tank assembly is provided and configured to be mounted to a tractor having a maximum width. A tank assembly width is no greater than a maximum width of the tractor.

An autonomous agricultural implement is operable to advance itself across a field while dispensing agricultural product. The implement includes an implement chassis, a drive system, an interchangeable product container, and a plurality of openers. The container presents a chamber configured to hold a supply of product. The container is shiftable between coupled and uncoupled positions, with the container being detached from the implement chassis in the uncoupled position. The container includes a product flow barrier to selectively restrict product from flowing out of the chamber when the container is in the uncoupled position prior to the container being attached to the implement chassis. The container fluidly communicates with the openers when in the coupled position so that the openers receive product from the chamber.

An agricultural system includes an agricultural product supply station, an autonomous agricultural machine, a plurality of product containers, and a powered transfer mechanism. The machine is operable to advance across a field while dispensing product. The product containers are configured to be removably stored by the supply station in a stored position and used interchangeably with the machine. Each container is configured to contain product and operably couple to the machine to dispense product thereto. Each container is shiftable between a machine-coupled position and the stored position. The container is attached to the machine in the machine-coupled position and detached from the machine in the stored position. The transfer mechanism is operably supported by at least one of the supply station and the implement and is configured to shift each container between the machine-coupled and stored positions.

A mobile agricultural product dispensing system is configured to hold a supply of agricultural product and transport the product for operations on a field by an agricultural machine. The dispensing system includes a wheeled supply station and a plurality of product containers. The supply station is operable to be advanced to and from the field and includes a rack assembly defining a series of container-receiving bays. The product containers are configured to be used interchangeably with the machine. Each container is configured to contain product and operably couple to the machine to dispense product thereto. Each container is removably supported by the rack assembly in a corresponding one of the bays.

A control system is operable to control an autonomous machine for autonomously applying one or more products to a jobsite in accordance with a set of operation instructions. The products are stored in one or more interchangeable containers which are initially located on a station. The control system broadly includes an alignment sensor and a machine processor. The alignment sensor is configured to sense and generate alignment data regarding a relative position of the station and a particular container that contains a particular product. The machine processor is configured to align the autonomous machine with the station and the particular container based on the alignment data from the alignment sensor, and transfer the particular container from the station to the autonomous machine; move the autonomous machine over the jobsite and apply the particular product from the particular container in accordance with the set of operation instructions; and align the autonomous machine with the station based on the alignment data from the alignment sensor, and transfer the particular container from the autonomous machine to the station.