A high-efficiency cultivation method for high-frequency drip irrigation, water saving, seedling survival and strengthening, and yield increase of cotton fields in saline-alkali soil is provided, belonging to the field of agricultural planting technologies. It mainly includes performing land preparation; setting a planting mode; laying tubes; performing a high frequency drip irrigation; fertilizing with water; performing intertillage; performing chemical control; and performing green prevention and control. The method effectively solves many defects in the existing methods, improves the quality of cotton field preparation and seeding in saline-alkali soil, saves irrigation water, increases the emergence rate and seedling survival rate, improves the saline-alkali resistance of cotton seedlings, increases the yield, and achieves the goal of water-saving, high-quality and high-efficiency cultivation of cotton seedlings in saline-alkali soil.

A system for dispersing a chemical in a surface water body includes an aerator device, having an injector positioned at a bottom of the surface water body; and a holding tank to store the chemical adjacent to the surface water body; and a metering pump connected to the holding tank, the metering pump having a computing device to program the metering pump; the metering pump is programed to inject an amount of the chemical to the injector at a rate; and the injector disperses the chemical throughout the surface water body.

Crop input application systems, methods and apparatus are provided. In some embodiments, an irrigation system is provided with a reel in fluid communication with a wellhead, secondary cart or fluid supply line outlet. In some embodiments, a drop assembly is incorporated in an irrigation system. In some embodiments, a crop applicator system traverses a field portion at a first speed in a first direction and then traverses the field portion at a second, lower speed in a second, opposite direction

A flexible greening system integrated with water into fertilizer includes a vegetation fixing assembly, a vegetation growth layer and a water supply assembly. The vegetation fixing assembly is configured to connect to a building. The vegetation growth layer is provided on the vegetation fixing assembly and is configured for planting of green vegetation. The vegetation growth layer includes a substrate layer for vegetation growth and a drainage layer provided below the substrate layer. The water supply assembly is configured to supply the water to the green vegetation, and is provided with a drainage pipe communicated with the drainage layer.

The present invention relates to a soil conditioner based on organomodified siloxanes and uses thereof as well as methods for conditioning soil, particularly farmland, which reduce the sodicity and dispersion to improve the mobility of water through the soil.

A system having a boom; a plurality of cameras attached to the boom; and a plurality of lenses on each camera; wherein not all lenses have a same field of view.

An automatic fertilizing apparatus connected in series with a sprinkle watering system. The apparatus includes a liquid fertilizer container having an inlet and an outlet, and a venturi tube configured to sealably fit into the inlet and outlet of the container. The fertilizing apparatus includes a venturi tube that can sealably fit into the inlet port and the outlet port. Water pumped into the venturi tube can produce a partial vacuum that allows the liquid fertilizer in the container to be drawn into the venturi tube through a slot in the venturi tube. The liquid fertilizer can mix with the water stream in the venturi tube and the mixture of water and liquid fertilizer can be dispensed through a sprinkler head of the sprinkle watering system.

A localized product injection system for use with a product dispensing system includes a product injection reservoir coupled with an injection header. One or more injection boom tubes are coupled with the injection head. A plurality of localized injection interfaces are configured for coupling at corresponding product dispensers of a plurality of product dispensers. The plurality of localized injection interfaces in communication with the one or more injection boom tubes. Each of the localized injection interfaces includes an interface valve and an injection port in communication with the interface valve. The injection port is configured for localized coupling and injection to the corresponding product dispenser. The plurality of localized injection interfaces maintains a controlled pressurized environment of an injection product to the plurality of product dispensers.

A system for the fertigation of a plant vessel and method of use for the same is disclosed. The system comprises a grow module containing a plurality of growing trays additionally containing plants, and/or shoots of plants in various stages of development. The growing trays are individually extracted from the grow module via a tray movement system and tray elevator controlled by a control system and precisely placed in a fertigation system, wherein they are aligned over and lowered onto an at least one nozzle which penetrate the plant vessels containing the plants and fertigate them with a combination of water, nutrients, and/or pressurized air. The individual growing tray is then replaced in the grow module and the process is repeated for all growing trays and plant vessels in the grow module.

A monitoring system for an irrigation system that includes a nozzle and a product source that supports a product for mixing with water from a water source to which the irrigation system is operably coupled. The monitoring system includes: a sensor configured to generate a first electrical signal indicative of a travel speed and/or a travel direction of the irrigation system; a fluid pressure sensor configured to generate a second electrical signal indicative of a flow rate, a processor, a memory, and a variable speed pump or a valve. The memory includes instructions, which when executed by the processor cause the monitoring system to: receive the first and second generated electrical signals, determine an applied rate of the irrigation fluid over a predetermined irrigation area based on the first and second electrical signals, and adjust the flow rate of the irrigation fluid through the at least one nozzle.