A plant growing system using water extracted from air, the system which has a Peltier element connected to a power supply and includes a heat dissipating member and a cooling member to collect condensate by condensing moisture in the air. The plant growing system includes: a mixing part having a storage tank and a nutrient supply tank, the storage tank into which condensate obtained from the air is introduced and stored, and the nutrient supply tank which is connected to the storage tank so that a predetermined amount of nutrients is supplied through a nutrient control valve; an atomizer having one side connected to a compressor whose opening and closing is controlled by an injection valve, the atomizer being connected to the mixing part via a pipe so that a solution flows and is then stored in the atomizer.

Systems and methods for vertical hydroponic growing of plants within an optional enclosure, in particular utilizing liquid nutrigation and/or solid nutrient medium/supplements in combination with vertically configured arrays of interchangeable grow cups to produce near year-round ideal plant growing conditions.

A plant-growing container (500) can include a lower portion (506) and a wall (502) extending upwardly from the lower portion (506). The wall (502) can include a first aperture (512). The plant-growing container (500) can further include an orifice (510) formed by an upper portion (504) of the wall (502) and configured to receive a removable seed receptacle. The plant-growing container (500) can further include a reservoir provided by a lower portion (506) of the wall (502). The container (500) can be configured to be removably inserted into a port of a module of a plant-growing system, wherein the reservoir can be configured to receive a first volume of fluid from a fluid that is circulated through the plant-growing system.

The present invention relates to an indoor aquaponics assembly which includes a base, an aquarium positioned above and supported by the base, a planter positioned above the aquarium, an aquarium conduit and a planter conduit. The planter is provided with at least two through holes facing towards the aquarium, one being adapted for a water drainage tube to pass through for draining water from the planter to the aquarium, and one being adapted for a tube of a pump to pass through for pumping water from the aquarium to the planter. The present invention aims at reducing the time and efforts required for caring and maintaining the aquarium and the plants.

A modular commercial plant cloning system and method for stimulating root growth from a plant stem. The system includes a supporting frame, a light source, a fluid reservoir, and a cooling element. The supporting frame further includes a plurality of mounting points for securing a plant holding device tray at a desired height and spacing within the supporting frame below the light source. The plant holding device tray houses a plurality of plant holding devices that the plant stems are placed in during the cloning process. The lower end of the supporting frame includes the fluid reservoir, wherein the fluid reservoir further includes a cooling element therein. Additionally, the fluid delivery system helps transport fluid from the fluid reservoir to the sprayer nozzles which are configured to distribute fluid across the plant stems disposed within the plant holding device tray.

A controlled growth system is provided herein. The controlled growth system includes a controlled growth environment, a controller, a sensor, and a computing system. The controlled growth environment is configured to grow a biologic. The controller is in communication with the controlled growth environment. The controller is configured to manage process parameters of the controlled growth environment. The sensor is configured to monitor the biologic during a growth process. The computing system is in communication with the sensor and the controller. The computing system is programmed to perform operations for achieving a desired final quality metric for the biologic.

A flexible plastic molded pod assembly, consisting of a pod collar and a locking pod ring is adapted to easily snap and lock in place against the edges of a circular hole cut through the wall surface of a Vertical Hydroponic System of either a flat or a cylindrical design. The pod assembly will shelter an organic plant matter from its seedling stage to its mature harvest form. The Pod Assembly is adapted to direct the flow of liquid Hydroponic Water with necessary nutrients to the plant in which it shelters. Included in the kit is a water flow diffuser adapted to distribute of Hydroponic water in all directions around the uppermost interior wall of a Vertical Hydroponic System thereby constantly supplying plant matter in each of the pod assemblies below with Hydroponic Water.

The present disclosure provides a hydroponic unit (2) and system (1) for growing crops, the unit being modular to allow different containers and growing conditions within the unit, and the system being modular to allow multiple units to share common power and water requirements. The unit and system aim to provide a more efficient and easier to use hydroponic operation. The unit includes an adjustable framework and manifold in each unit for receiving containers of a first or second type, and the system includes a support structure (4) including module bases (3) for each unit and a water control module for the system. Also provided are growing columns for use within the hydroponic unit.

A plant cultivation apparatus includes a cabinet configured to accommodate a cultivator that is configured to accommodate at least a portion of a plant, a storage configured to store nutrient liquid to be supplied to the cultivator, a supply path connected to the storage and configured to supply the nutrient liquid from the storage to the cultivator, and a nutrient liquid circulator that includes a first member configured to increase a pH of the nutrient liquid and a second member configured to decrease the pH of the nutrient liquid. The nutrient liquid circulator is configured to discharge the nutrient liquid from the storage and to circulate the nutrient liquid to the storage through at least one of the first member or the second member.

The present invention relates to a hydroponic plant growing system. The hydroponic plant growing system includes a reservoir for storing a watering solution including water along with nutrients, a planting lid releasably-engaged to the reservoir, a transparent lid disposed to cover the planting lid and a bubbler or an air pump connected to an air stone for producing bubbles in the watering solution. The planting lid includes a plurality of embedded cups for retaining the plants and enabling the plants to receive nutrients from the watering solution therebelow. A solar panel provides power to the bubbler. The plants are suspended over the bubbled watering solution and nutrients, thereby enabling plants to be grown both indoors and outdoors.