Tray assemblies organized in a vertical stack with a grow light positioned above each. Plant nutrient solution flows into a feed reservoir positioned in a first end of the top assembly. When plant nutrient solution reaches the level of outlets positioned in a sidewall of the feed reservoir, it flows into longitudinal channels positioned on the tray assembly. A collection reservoir at a second end of the tray assembly collects excess solution from the channels. A lip positioned between the channels and the collection reservoir retains some of the solution in the channels so it is available to plants held by the tray assembly. Excess solution flows from the collection reservoir of the top tray assembly to a feed reservoir serving the next tray assembly in the stack. The pattern is repeated while alternating the orientation of each tray assembly such that solution is provided to each tray assembly.

Accordingly, the present disclosure relates to a modular hydroponic system that may integrate various farming mechanisms. More specifically, the modular hydroponic system may utilize interconnected modules and lines to cycle nutrient-rich water to a range of plant and animal life. The modular hydroponic system may comprise aquaponic modules that may continuously process recycled water and replenish it with nutrients to facilitate growth of the plant life. With a combination of hydroponics and aquaponics, the modular hydroponic system may provide for both a farm and fisheries, allowing for the harvest of produce and fish. The modular aspect of the modular hydroponic system may allow for customization based on resources, spaces, and needs, wherein modules may be combined and substituted.

There is a modular, insulated, all-in-one, plug-and-play (MIAP) aquaponics unit that includes a framework having a single base and plural walls; an aquaculture tank defined by a first portion of the single base and a first set of the plural walls; a clarifier tank defined by a second portion of the single base and a second set of the plural walls; a bio-reactor tank defined by a third portion of the single base and a third set of the plural walls; a hydroponics tank defined by a fourth portion of the single base and a fourth set of the plural walls; and piping extending through the plural walls between each two adjacent tanks for allowing water from the aquaculture tank to flow into the clarifier tank and then into the bio-reactor tank and then into the hydroponics tank and back to the aquaculture tank.

The present disclosure provides an advantageous pan jig for installing a pan relative to a frame. The disclosed pan jig semi-permanently engages the pan relative to a frame. Specifically, the disclosed apparatus and method of use advantageously facilitates formation and mounting of a drip pan for use with a system that facilitates aeroponic growing. The disclosed aeroponic growing system may include a plurality of drip pans.

An alternative salt nutrient mixture for plant growth, wherein one or more of the following nutrients is present as a carbonate: nitrogen (eg ammonium), potassium, calcium, magnesium, iron, manganese, boron, zinc or copper and/or one or more of the following nutrients is present as a nitrate: nitrogen (eg ammonium), potassium, calcium, magnesium, iron, manganese, boron, zinc or copper.

A vertical farming system is disclosed herein. The vertical farming system can comprise a frame configured to fit into an enclosed growing environment. The vertical farming system can further comprise a track supported by the frame, where the track is configured to provide side access. The vertical farming system also includes an irrigation conduit coupled to the frame adjacent to the track. The vertical farming system includes a growth media field where the growth media field includes brackets coupled to a top portion of the growth media field. The growth media field can be made of porous material configured to form a root zone environment support and provide fluid distribution to root systems. The brackets can be configured to slidably couple to one or more tracks such that the growth media field is suspended from the one or more tracks.

An aquaponics system including a rearing tank of a rearing system and cultivation beds of a cultivation system, wherein the cultivation beds are arranged vertically in two or more stages. The system includes a rearing and cultivation circulating system in which liquid in the rearing tank is supplied to each of the cultivation beds, and the liquid in each bed is returned to the tank, to thereby circulate through the tank, beds, and tank. Fish and shellfish can be reared in the rearing tank and a plant can be cultivated in the cultivation beds, with the liquid circulating through the circulating path. Both a cultivation circulating system in which the liquid circulates through the water storage tank, the cultivation beds, and the water storage tank, and a rearing circulating system in which the liquid circulates through the rearing tank, the water storage tank, and the rearing tank may be arranged.

An automated plant cultivation system is provided having multi-tiered vertically arranged horizontal magazine structures each employing seed or plant capsules with a fluid circulation and illumination and communication network controlled by an on-board processor. Particularly, the system includes a magazine structure having seed/plant capsules within seed/plant reservoirs alternately arranged between at least one of a light source substantially concealed from direct viewing. A fluid channel extends across a long axis of the magazine structure, wherein the magazine structure is adapted for use of seed/plant capsules with nutrient composite plant growth cultivation, hydroponic plant growth cultivation, aeroponic plant growth cultivation methods or combinations thereof.

A plant cultivation apparatus comprising a cultivation box which has a hollow rhizosphere portion for hanging a root of a cultivation plant, wherein: the cultivation box is constructed by detachably combining an upper panel and a lower panel; a bottom wall of the lower panel is provided with a waste liquid port and a trough-shaped gutter is detachably installed below the bottom wall of the lower panel over an entire length in a length direction; the upper panel is provided with nozzle-mounting holes at intervals in the length direction; a nozzle for spraying nutrient solution is inserted into each of the nozzle-mounting holes and hung in the rhizosphere portion; the upper panel is provided with planting holes for the cultivation plant; and a root of the cultivation plant is inserted into the planting hole and hung in the rhizosphere portion, to which the nutrient solution is sprayed from the nozzle.

Hydroponic growing systems are gaining in popularity because of the relative ease of use and these systems eliminate the traditional problems with growing plants in earth: insects and fungus, among other issues. Hydroponic growing systems do not depend on soil and therefore the issue of insects and bugs and/or other harmful elements to plants are largely avoided. The device in this case circulates water through a closed system on a timed basis; the primary issue for this system is accommodating the right growing conditions for the plant. This issue is addressed by using substrate to promote healthy plant growth.