The embodiments herein relate to a method for delivering nutrients to the plants in a hydroponic system. The method comprises delivering a nutrient solution, planting a plurality of plants in a plurality of plant receivers, combining a plurality of angled joints with a single side of one plastic pipe with rest of the plastic pipes, combining a plurality of T-fitting/connectors with the plurality of plastic pipes, closing an end of the plastic pipes with a plurality of pipe caps and delivering water to the plurality of pipes using a customizable water pipe. The method further comprises adjusting the plurality of plastic pipes with an adjustable pipe brace and circulating the nutrient solution in the reservoir to the plurality of plant receivers using an electrical pump.

A generally planar foundation pad is formed of a material such as concrete, or the like, and supports a framework defining a plurality of concentric circular paths stacked in a cylindrical array. A plurality of helical water troughs are supported by the framework within each of the circular paths. Water circulation apparatus is provided which pumps water from the bottom of each helical water trough to the top and selected intermediate portions of the water trough to produce a continuous circulation of water. The circulating water is combined with various nutrients and the nutrient and water solution is filtered as it is circulated. Each helical water trough is fanned of multiple vertically stacked layers of the trough. As a result, a great length of water trough is stacked upon a small footprint of land. Each water trough is filled with a plurality of floating growing trays to form a continuous train of growing trays extending down the entire water trough. As the water and nutrient solution flows down each helical water trough, the floating growing, trays are carried down the water trough. As the growing trays move, they are continuously removed from the bottom end of the water trough and added at the top.

A method comprises steps for (a) providing a liquid in a container; (b) flowing a gas to a volume within the liquid, wherein the volume is at least partially submerged in the liquid; and (c) repeatedly increasing and decreasing the volume, wherein the cycles of increasing and decreasing generates a pulsed aerated flow, wherein at least one of the pulsed aerated flow is released within the container and the pulsed aerated flow is released outside the container.

A hydroponic grow assembly including an assembly base and at least one plant structure removably connectable to the assembly base to form a plant wall for growing plants. The plant structure includes a plurality of plant wells opened to a root chamber and the base includes a bottom structure enclosed by a perimeter wall to form an inner cavity of a reservoir tank to supply water to the root chamber of the plant structure. The bottom structure includes a support feature within the inner cavity of the reservoir tank to support the at least one plant structure in an upright position to form the plant wall of the assembly.

A portable agrarian biosystem is a self-contained plant and fish growth facility encased in a shipping container so that it can be readily transported and set up. The system is designed for self-sufficient operation without connection to external sources of water or electricity. The modified aquaponic growth system is computer controlled for unattended operation with significantly lower consumption of water than other plant growth systems.

A hydroponic growing system that comprises a plurality of parallel horizontal pipes, a vertical drain pipe, and a plurality of nutrient-delivering tubes. The horizontal pipes are adapted to support crops that receive nutrients from the nutrient-delivering tubes and grow in high density. The horizontal pipes have opposite first and second ends, as well as a plurality of openings along a length, and a plurality of pipe segments extending angularly from an outer surface. The vertical drain pipe has a plurality of angular pipe extensions along a length, which mate with one of the first and second ends of the horizontal pipes. The nutrient-delivering tubes have openings along a length and extend from the vertical drain pipe, branching through the pipe segments extending from the horizontal pipes.

A system for cultivating plants comprising a plurality of cultivation shelves for cultivating plants, support frames structured to support the cultivation shelves so as to form one or more horizontal cultivation planes that develop along a first horizontal direction, an aeroponic feeding system, which is provided with nebulizing devices that are arranged at the cultivation shelves for spraying the liquid towards the cultivation shelves themselves, and a suction duct arranged at the nebulizing devices to suck up the nebulised liquid dispersed by the same.

A plant growing system having a growing chamber containing an aqueous growing medium and a growing atmosphere in which a plant is grown, a compound delivery system configured to deliver one or more compounds including nutrients mixed with surfactant into the growing atmosphere for plant stomatal uptake, an acoustical stimulation system configured to increase stomatal uptake, a growing medium oxygenation system configured for oxygenating, preferably hyperoxygenating or oxygen supersaturating, the growing medium which plant roots immersed therein take up oxygen longer before needing oxygen replenishment, and a plant lighting system configured to deliver ultraviolet wavelength filtered solar light to the plant for photosynthesis. The chamber preferably is a hyperbaric chamber, the growing atmosphere contains at least 0.06% carbon dioxide, the compounds are delivered in the form of atomized droplets, and the growing medium contains at least 2 mg/L oxygen in the form of nanobubbles diffused or dissolved therein.

Modular systems for propagating plants in at least one of a hydroponic environment and an aquaponics environment may include at least one tank configured to hold liquid. A modular drive assembly may be carried by the at least one tank. At least one propagation module may be drivingly engaged for rotation by the modular drive assembly. The at least one propagation module may be configured to support and propagate at least one plant. At least one pump may be disposed in fluid communication with the at least one tank. The at least one pump configured to pump the liquid from the at least one tank through the at least one propagation module. Modular methods for propagating plants in at least one of a hydroponic environment and an aquaponics environment are also disclosed.

A plant growth apparatus includes a vapor duct, a plurality of cascade points, a plurality of mounts, a plurality of spill throughs, a reservoir, a water return, and a vaporizer. The vapor duct allows the passage of vapor into a plant enclosure. The plurality of cascade points allows passage of water from a trough. The plants are set into plant receivers of the mounts. The roots of the plant occupy a root space formed by the plant wall and the mounts. The spill throughs are cut into the mounts which allow water to enter the root space and a pool below the mounts. The reservoir fills the trough with water and causes it to flow through the cascade points. The water return connects the pool of the plant enclosure and the reservoir. The vaporizer located partially within the reservoir creates vapor that moves to the plant enclosure.