A chemical agent-spraying device is provided with a chemical agent tank and chemical agent-jetting parts that jet out a chemical agent supplied from the chemical agent tank. The chemical agent-jetting parts include a first chemical agent-jetting part that jets out the chemical agent onto the reverse surfaces of crop leaves as an area to which the chemical agent is to be jetted, and a second chemical agent-jetting part that jets out the chemical agent onto the obverse surfaces of crop leaves as an area to which the chemical agent is to be jetted.

Connectors and methods for contactless transfer of fluid between containers are disclosed. According to an aspect, a connector includes a body that defines a first end, a second end, and a passageway that extends between the first end and the second end, wherein the first end and second end are configured to attach to a first container and a second container, respectively. The passageway provides a pathway between the first and second containers when the first and second containers are attached to the first and second ends, respectively. Further, the connector includes an opener configured to engage and open the first container for release of a fluid from within the first container through the passageway and into the second container when the first and second containers are attached to the first and second ends, respectively.

A spray fluid operation system for an agricultural sprayer and method for operating same is disclosed. The method comprising: providing a spray fluid in a reservoir; and conveying at least one of the spray fluid and an additional fluid into a fluid flow system by a pump and control system (PCS). The fluid flow system comprising a dispensing device configured to dispense a first pumped fluid from the PCS to a field, and a backflow system configured to pipe second pumped fluid from the PCS back to the reservoir. The method further comprises: determining a fluid level in the reservoir; receiving the fluid level in a control device; generating the second pumped fluid by the PCS; and controlling allocation of the second pumped fluid according to an allocation ratio to: a first return device and a second return device configured to return the second pumped fluid to the reservoir.

An agricultural implement arrangement includes a container of seed having an ID tag associated therewith; an implement for applying a product to a geographic area; an electrical reader configured for reading the ID tag and providing an output signal; and an electrical processing circuit coupled with the reader and the implement. The ID tag has data representing at least one attribute associated with the seed. The electrical processing circuit receives the output signal and controls the implement, dependent upon the output signal.

An agricultural implement includes the calibration of liquid fertilizer distribution for an agricultural implement. The calibration system measures the level of the liquid fertilizer or utilizes a known volume in a container and the pressure of the liquid fertilizer. The system uses the level and pressure to calculate the density of the liquid fertilizer, which helps achieve more consistent fertilizer application. Additionally, the density of the liquid fertilizer can be used to more accurately measure the tank level of a particular tank. The system can include a tilt sensor and valves so that when the agricultural implement is traversing a hill or otherwise rough terrain, the system can accurately measure tank level and selectively draw liquid fertilizer from a particular tank or tanks to mitigate spillage. The system also can measure and monitor the tank level of the tank or tanks and automatically fill the tank or tanks based on the measured tank level.

A self-propelled agricultural product application implement such as high clearance sprayer and/or spreader is provided that includes a product container that is sectioned. Emptying of the container sections is controlled to approximate a target front-to-back weight distribution of the implement for a substantially long period of time during a product application session. An outlet system having multiple variable outlet arrangements is arranged between the product container and an application arrangement such as a spray boom or a rotary broadcaster. The variable outlet arrangements are configured to allow the container sections to sequentially empty to maintain ballast provided by the store product at relatively later portions of the implement for a relatively longer period of time during the product application session.

An autonomous spraying platform is provided. The autonomous spraying platform has a main frame platform supported by a first and a second wheel in tandem. Supported by the main frame platform and extended perpendicular thereto are extended booms having multiple movable and/or telescoping arms which touch the ground on each side by small wheels for balance and sensing of the ground. Liquids, foams or powders, which may carry pesticides, herbicides, insecticides, fungicides, fertilizers or other pro-growth ingredients, may be dispensed across the bottom edge of the extended booms. The main frame platform may be controlled locally by sensors utilizing GPS (or other positioning technology) or remotely by a computer or even alive operator. The device may allow for real-time precise delivery of pro-growth materials to plants.

A work vehicle fleet includes a first model of work vehicle and a second model of work vehicle, different than the first model. The first model includes a first set of display devices; a first set of cameras; and a first controller configured to display a standard set of feeds from the associated first side, second side, and central location of the first set of cameras at the first set of display devices so that the associated feeds are arranged at the first side, the second side, and the central location, respectively, relative to the first operator FOV. The second model includes a second set of display devices; a second set of cameras; and a second controller configured to display so that the associated feeds are arranged at the first side, the second side, and the central location, respectively, relative to the second operator FOV.

In one aspect, a system for monitoring a level of hydraulic fluid in an agricultural sprayer includes a drive system, a hydraulic fluid system, and a fill level sensor. The system also includes a computing system communicatively coupled to both the drive system and the fill level sensor. The computing system is configured to monitor the level of hydraulic fluid within the hydraulic fluid reservoir based on data received from the fill level sensor. The computing system is further configured to detect a leak condition in the hydraulic fluid system based at least in part on the monitored level of the hydraulic fluid within the hydraulic fluid reservoir and control an operation of the drive system to reduce the ground speed of the agricultural sprayer in response to detecting the leak condition.

A system for irrigating an agricultural field includes a high-clearance vehicle (e.g., a sprayer vehicle) and a hose configured to connect an external water source to the high-clearance vehicle while the high-clearance vehicle traverses the agricultural field. A method for irrigating an agricultural field includes connecting an external water source to a high-clearance vehicle by a hose, and dispensing water from the nozzles of the high-clearance vehicle while the external water source remains connected thereto and while the high-clearance vehicle traverses the agricultural field.