A system for controlling nozzle flow rate includes a master node having an expected overall flow rate module configured to generate an expected overall flow rate of an agricultural product based on one or more sprayer characteristics, and an adjustment module configured to generate an error correction based on a difference between the expected overall flow rate and an actual overall flow rate of the agricultural product. A plurality of smart nozzles are in communication with the master node, each of the smart nozzles includes an electronic control unit in communication with one or more control valves and one or more nozzle assemblies. Each of the smart nozzles includes a target smart nozzle flow rate module configured to generate a target smart nozzle flow rate of the agricultural product based on the one or more sprayer characteristics. The target smart nozzle flow rate is adjusted according to the error correction.

An anhydrous ammonia trailer hitch incorporating a base; a vehicle mounting receiver hitch fixedly attached to and extending forwardly from the base; a bolt mounted to the base, the bolt being adapted for moving between latching and releasing positions; a release plate having a first eye fitted for receiving the bolt, the bolt extending into the eye upon movement to the latching position; a remotely actuatable linear motion actuator connected operatively to the bolt for moving the bolt between the latching and releasing position; a tongue mount fixedly attached to the release plate; and at least a first safety chain mount fixedly attached to the release plate.

The invention relates to a distributing device for liquids, particularly for solids-containing liquids, comprising: a distribution chamber with an inlet opening that leads to a chamber interior space of the distribution chamber, a first perforated blade disc with several outlet openings that connect the chamber interior space to several connection ports, and a blade drive shaft that is swivel-mounted about a drive shaft axis. According to the invention, a first eccentric member, which is connected to the blade drive shaft and defines a first eccentric axis lying at a distance to the drive shaft axis, and a first cutting blade are provided, which first cutting blade is connected to the first eccentric member and has a cutting edge that rests against the first perforated blade disc and can be moved relative to the first perforated blade disc by means of the first eccentric member.

A method for handling a fluid includes separating the fluid into a liquid and a vapor within a container such that at least a portion of the vapor is disposed above the liquid, detecting a level of the liquid in the container, and actuating at least one valve to exhaust the vapor from the container to maintain the level of the liquid at or above a desired level. The at least one valve is communicatively coupled to a controller. The method further includes sending a signal from the at least one valve to the controller, and determining diagnostic data based at least in part on the signal.

Systems and methods for suppressing vaporization of a volatile fluid dispensed from a pressure vessel are provided. The system includes an evaporator coupled in thermal communication with a first flow of volatile fluid from the vessel and in fluid communication with a second flow of volatile fluid from the vessel. The evaporator includes at least one channel for channeling the second flow of volatile fluid therethrough. A metering valve is coupled in fluid communication with the channel and between the evaporator and the vessel. In addition, the system includes a compressor coupled in fluid communication with and downstream from the at least one channel. Moreover, the system includes a return line coupled in fluid communication with an outlet of the compressor. The compressor is configured to compress the second flow of volatile fluid and channel the compressed second flow of volatile fluid to the pressure vessel via the return line.

Embodiments of a system and method are described. In one embodiment, the system generates ions for use in treating vegetation to optimize growth of the vegetation. The system includes an ion generation region having a pair of dissimilar metal plates. The ion generation chamber receives a liquid and routes the liquid past the dissimilar metal plates to capture ion transfer between the dissimilar metal plates. The ions form a charged solution. The system also includes a collection region having a collection bed for storing the charged solution, and a fertigation region for dispersing the liquid. Other embodiments of the system are also described.

Embodiments of a system and method are described. In one embodiment, the system generates ions for use in treating vegetation to optimize growth of the vegetation. The system includes an ion generation region having a pair of dissimilar metal plates. The ion generation chamber receives a liquid and routes the liquid past the dissimilar metal plates to capture ion transfer between the dissimilar metal plates. The ions form a charged solution. The system also includes a collection region having a collection bed for storing the charged solution, and a fertigation region for dispersing the liquid. Other embodiments of the system are also described.

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.

Present invention relates to a locking and emptying system of a refill cartridge containing nutrients or chemicals, said system comprising at least one replaceable refill cartridge, at least one receiving socket for the refill cartridge, in every receiving socket a locking mechanism of the refill cartridge, discharge means of the refill cartridge and control means of the locking system and for each refill cartridge a emptying container. The control means of the locking system are set to release the empty refill cartridge from the receiving socket only when the emptying container has enough free volume to receive the content of the next refill cartridge,

An apparatus for use in establishing or re-establishing plant growth over a land area. The apparatus includes a supply of a growing medium and an arrangement including at least one delivery outlet for delivering the growing medium at spaced intervals from a height onto a soil surface of the land area. The growing medium contains seeds or is delivered in tandem with and on top of seeds deposited on the soil surface or deposited onto or adjacent to seeds or seedlings already deposited on the soil surface.