A multi-tank spray system includes a first tank, a second tank, a pump, and a plurality of valves including a first valve, a second valve, and an equalizing valve. A first end of the first valve is in fluid communication with the first tank, a second end of the first valve is in fluid communication with (i) a first end of the equalizing valve and (ii) an inlet of the pump. A first end of the second value is in fluid communication with the second tank. A second end of the second valve is in fluid communication with a second end of the equalizing valve. A tank module is configured to receive a spray mode, receive a measurement from at least one sensor of a plurality sensors, and control operation of the plurality of valves and the pump based on (i) the received spray mode and (ii) the received measurement.

A variable width agricultural applicator is provided. The variable width agricultural applicator is attachable to a boom to apply a liquid to a crop in rows. The variable width agricultural sprayer includes a drop tube and a splitter downstream of the drop tube. The splitter is fluidly connected to the drop tube. A pair of flexible delivery tubes is fluidly connected to the splitter. Each one of the pair of flexible delivery tubes has a predetermined bend.

Systems, kits, and methods for contactless application of mixed concentrates and diluents are disclosed herein. According to an aspect, a system comprising a mix and storage container defining an interior and a first opening and a second opening. The first opening, the second opening and the interior are fluidly connected. Further, the system includes a connector that defines a first end, a second end, and a passageway that extends between the first end and the second end. The first end of the connector is attached to the first opening of the mix and storage container. The connector further defines an opener configured to engage and open a sealed portion of the concentrate container for release of a concentrate from within the concentrate container through the passageway and into the interior of the mix and storage container for mixing with a diluent. The system also includes an application tool.

An intelligent, automated system for loading agricultural product application equipment is provided in which a control system can determine a necessary amount of product for completing a field operation and can automatically couple with a tendering system to receive such product at an optimal time and location. The control system can determine a current amount of product, a projected amount of product necessary to complete a field operation and a refill amount of product from the current amount and the projected amount, then transmit the refill amount to the tender. The control system can further determine whether a position of the equipment relative to the tender is within a threshold, and whether an intake coupler of the equipment is connected to a supply coupler of the tender, and can control valve(s) to open and close channel(s) for loading fluid into the storage tank.

An intelligent, automated system for loading agricultural product application equipment is provided in which a control system can determine a necessary amount of product for completing a field operation and can automatically couple with a tendering system to receive such product at an optimal time and location. The control system can determine a current amount of product, a projected amount of product necessary to complete a field operation and a refill amount of product from the current amount and the projected amount, then transmit the refill amount to the tender. The control system can further determine whether a position of the equipment relative to the tender is within a threshold, and whether an intake coupler of the equipment is connected to a supply coupler of the tender, and can control valve(s) to open and close channel(s) for loading fluid into the storage tank.

A method and system for stacking containers each container of a type having a front face having a truncated trapezoidal shape, a rear face having a truncated trapezoidal shape, a top base, a bottom base, a first vertical side adjacent to the top base, a second vertical side adjacent to the top base, a first sloped side between the first vertical side and the bottom base, a second sloped side between the second vertical side and the bottom base. A discharge valve projects from the bottom base where the first vertical side defines a platform for supporting an RFID tag. The containers are configured to be stackable in a manner to provide simultaneous reading of the multiple RFID tags on the platforms.

A system for dispensing agricultural fluids onto plants present within a field includes a sensor configured to capture data associated with the plant and a computing system communicatively coupled to the sensor. In this respect, the computing system is configured to receive an input associated with the pesticide present within the agricultural fluid. Furthermore, the computing system is configured to determine a size parameter associated with the plant based on the data captured by the sensor. Moreover, the computing system is configured to determine a selected amount of the pesticide to be dispensed onto the plant based on determined size parameter and the received input associated with the pesticide. Additionally, the computing system is configured to control an operation of the nozzle such that a volume of the agricultural fluid containing the selected amount of the pesticide is dispensed onto the plant.

A multi-camera vision system is utilized onboard a work vehicle having an operator cabin and an apparatus associated with performance of a work task. The system includes: one or more display devices defining a plurality of display areas and a plurality of cameras carried by the work vehicle and coupled to display feeds at the display areas. A first camera of the cameras is oriented to selectively provide a first selected feed of at least a portion of the apparatus during performance of the work task. A controller is configured to display the first selected feed of the selected feeds with an insert, overlay, or icon that indicates the origin and orientation of the first camera as the first selected feed depicts performance of the work task by the apparatus.

A system for controlling a ground speed of an agricultural sprayer includes a speed setting device for commanding a selected ground speed of the sprayer when operating within a speed-range mode associated with a ground speed range. The speed setting device is movable across a plurality of positions, with each position being associated with a different ground speed within the ground speed range. A maximum range speed of the ground speed range is lower than a maximum ground speed of the sprayer. As such, the system includes a speed override input device for commanding that the ground speed of the sprayer be increased to the maximum ground speed. When an override input is received from the speed override input device, the computing system controls the operation of a sprayer drive system to increase the ground speed of the sprayer from the selected ground speed to the maximum ground speed.

An agricultural sprayer includes a purge tank, a nozzle configured to dispense an agricultural fluid onto an underlying field, and a downstream valve configured to selectively permit the air from the main fluid conduit to flow to the nozzle. A computing system is configured to initiate a purging operation to purge the agricultural fluid present within the nozzle and, upon receipt of the input, control an operation of a main valve such that the main valve is moved to an opened position to allow the air to flow through a main fluid conduit. In addition, the computing system is configured to monitor a first air pressure associated with the purge tank and a second air pressure associated with the nozzle. Furthermore, the computing system is configured to control an operation of the downstream valve during the purging operation based on the monitored first and second air pressures.