The present invention may relate to Aeroponic Systems and their individual elements. More particularly to automated systems capable of monitoring and adjusting some if not all of the light, nutrient, water quality and environmental factors required for the propagation and sustained growth of all types of plants. It may also describe methods to support the plants during propagation from seeds and for growth and harvesting. It may describe various methodologies for reducing space requirements and for increasing plant density without detriment to the growth cycles.

An industrial hydroponic control apparatus for monitoring and modifying an environment for growing plants includes a portable table, a reservoir, a refrigerator assembly, and a control device. The portable table includes predetermined positions for mounting insulated plant containers (IPC). Each IPC supports one or more plants. The reservoir is positioned below the portable table. The reservoir is in fluid communication with each IPC to distribute a fluid to each IPC and drain the excess fluid from each IPC via a piping network. The refrigerator assembly is positioned adjacent to the reservoir and is operably engaged to the reservoir. The refrigerator assembly adjusts a temperature of the fluid within a predefined range, thereby chilling the fluid. The control device is in operable communication with the IPC, the refrigerator, and the reservoir. The control device is configured for monitoring and modifying the environment for growing the plants.

Growing systems may include a number of modular growing chambers adapted to be configured in a stacked arrangement with each growing chamber surrounding a corresponding portion of the plant. The grow chambers may be selectively added or removed during plant growth, such that different sections of the growing plant may be influenced differently using aeroponic, hydroponic or other growing techniques. The grow chamber stack may be portable and provided with integrated or independent lifting devices to assist an operator in adding or removing chambers from the stack. Three growing processes may be facilitated using such systems. These include a process for producing assorted product from a single plant for simultaneous harvest, a process for producing an extended harvest of a desired size product from a single plant, and a process for extending the productive life of a plant and provide for multiple, continued, and perpetual harvest.

A method of irrigating a saline aquaculture system to control pests is described herein. The method includes acquiring a second set of environmental condition data on a computing device using a sensor coupled to a platform, such that the platform is configured to grow a salt-tolerant plant therein; comparing the second set of environmental condition data to a first set of environmental condition data acquired at a previous time point; determining whether freshwater accumulation has increased or will increase at a future time point on a surface of the platform; when it is determined that the freshwater accumulation on the surface of the platform has increased or will increase relative to the previous time point, activating a saltwater distribution device coupled to the platform; and reducing an accumulation of one or more of: insects, caterpillars, fungi, and bacteria on the surface of the platform.

An indoor soilless plant cultivating system, comprising a plurality of stationary light posts, each of which adapted to illuminate a predetermined sector of an indoor facility in accordance with a predetermined illumination signature; a plurality of plant growth towers that are rotatable about a substantially vertical axis in accordance with a predetermined timing sequence so as to be exposable to the light generated at any given time by one or more of the light posts and that are arranged by at least one module defining a module darkened interior region within which plants being instantaneously positioned receive a sensation of nighttime; and irrigation means for supplying the plants being cultivated in each of said towers with a nutrient-rich solution. Moreover, an artificial pollination system based on compressed air nozzles is incorporated within the light posts.

A vegetable preservation and growing case includes a thermally-insulated case body for vegetable growing or preservation. An electrical control component is electrically controlling the thermally-insulated case. A pipeline component is circularly supplying a nutrient solution to the thermally-insulated case body under an action of gravity. The preservation and growing case allows the freshness of a vegetable to be preserved for an extended period of time, has a simple structure, and is easy to maintain.

A growing system for providing fluids to a plurality of growing assemblies using only a single pump and fluid source. The growing system generally includes a single fluid source such as a reservoir from which fluids are drawn by a single pump. A main manifold connected to the pump outlet splits the fluids drawn from the fluid source into a plurality of feeder pipes. Each of the feeder pipes provides fluid to a separate growing assembly; with the present invention providing support for a plurality of growing assemblies. Each growing assembly comprises an inlet manifold for receiving the fluids, a plurality of growing pipes for providing the fluids to a plurality of planters, and a drainage device for discharging fluids back into the fluid source for further use.

A device for growing plants is provided. The device has a panel assembly on which a one or a plurality of nutrient flow channels is supported to provide nutrient flow passages from an inlet at an upper region to an outlet at a lower region of the support panel. A plurality of grow pockets is supported on an opposite side face of the support panel, the grow pockets in alignment with the nutrient flow channels. Each grow pocket has a plant access opening. A fluid aperture in the support panel is disposed at a lower region of each grow pocket for fluid communication between an interior of the grow pocket and the aligned nutrient flow passage.

The facility has a pair of side bars (1,1) acting as inclined supports for an upper sheet (2) with openings (8) for inserting the plants, a closed lower sheet (4) acting as a collector, and at least one intermediate sheet (3) with openings determining a cascade trajectory for the water with the nutrients. The multi-layer upper sheet (2) preferably includes four layers (2a, 2b, 2e and 2d), which together define narrow channels (7) such that at insertion, the root of each plant is placed in a channel (7) different from that used by the adjacent plants. The openings (8) for the insertion of the plants form two marginal and longitudinal lines, so than the roots of adjacent plants can be completely isolated during the first growth phase thereof, preventing interference therebetween and allowing plants with different growth rates and even different types of plants to be arranged on the facility, generating, in turn, continuous production and an improved yield from the facility.

Vertical hydronics cultivation equipment including a vertical flow path formation opposed panel retained by a frame body. The vertical flow path formation opposed panel includes a pair of plates that are parallelly opposed to each other and a block section blocking both sides of the plate. The pair of plates have therebetween a nutrient solution flow path that has a predetermined width in a horizontal direction to the floor face and that extends in a vertical direction to the floor face. The vertical flow path formation opposed panel has a plurality of retention holes through which the plant retention member is inserted. The frame body includes a nutrient solution tank, a spray bar, a hollow connecting member connecting the spray bar to the outlet of the nutrient solution tank, a gutter for guiding the nutrient solution to the tank, a circulation pump, and a controller for controlling the circulation pump.