An aeroponic planter for use in-ground includes a top strip for receiving plugs that are designed for holding plants. The planter has a rooting chamber capable of enabling aeroponic growth of plant roots, the rooting chamber having a base with a drain. A drain chamber mounts at the base of the rooting chamber for receiving liquid from the rooting chamber. At least one anchor mounted on each of the rooting chamber and the drain chamber for securing the aeroponic planter in soil. In an alternate embodiment, the at least one anchor is integral with the top strip.

An integrated modular and scalable fogponics crop growth system for cultivating a crop includes an upper growth chamber housing a leafy portion of a crop, a lower growth chamber housing a root portion of the crop, a nutrient tank and dispenser, and an environmental system. The nutrient dispenser is coupled to the nutrient tank holding a nutrient mixture for sustaining the crop. The dispenser atomizes the nutrient mixture into a nutrient fog using a booster pump and a high pressure pump capable of generating approximately 800 PSI to 1500 PSI. The high pressure pump is operatively coupled to a nozzle configured to dispense the atomized nutrient fog, substantially between 6 microns and 15 microns droplet size, into the lower growth chamber. Temperature and humidity are separately controlled in the leaf area.

A growth system includes growth trolleys each having at least one carrier configured to support products for growing, and a growth hub including equipment facilitating growth of products from a group comprising fluid supply, nutrient supply, and the like. At least one of the growth hub and the growth trolleys is displaceable relative to the other of the growth trolleys and the growth hub to furnish at least one growth facilitating function to products in at least one of the trolleys, when the at least one of the growth trolleys is adjacent to the growth hub.

The present invention relates to a hydroponic system including an enclosure, the enclosure comprising a top, a bottom, and a plurality of sides defining an interior, the interior containing within one or more plants. The hydroponic system further includes a plurality of lights, comprising a light located on the top, and at least two lights, each of the at least two lights located on at least two sides, wherein all the lights are positioned to illuminate the plants within the enclosure. The hydroponic system may further include a light controller, a water system, a fan system, and a sensor system. The hydroponic system may be controlled via an enclosure-mounted control panel or via a remote interface coupled to a remote user device.

Provided is a plant cultivation method that promotes plant growth and improves plant quality; also provided is a plant cultivation device. The plant cultivation method uses a nutrient liquid supply device that supplies a nutrient liquid to a plant, a fine bubble-generating device, a spraying device, and a control device. The plant cultivation method carries out plant cultivation by supplying the nutrient liquid in mist form, and comprises a first step in which an oxygen-containing gas is supplied as the gas into the nutrient liquid and the fine bubble-containing nutrient liquid is sprayed on the leaf surface of a plant, and a second step in which, after the first step, a carbon dioxide-containing gas is supplied as the gas into the nutrient liquid and the fine bubble containing nutrient liquid is sprayed on the leaf surface of the plant.

A hydroponic growing system is presented. The system can include multiple growing trays in a vertical arrangement, where a pump supplies the top-most tray and each lower tray is supplied by the overlying tray, and where the plumbing elements for supply and drainage are arranged to one side of the system. The system includes variations to support different crop types within the same system, including removable growing structures for root vegetable, microgreens and supports for vining crops. The system can monitor and adjust the nutrients and other features of the systems water profile to concurrently group multiple crops in differing developing stages.

An osmotic food production system designed to produce fruits, vegetables, and freshwater from urine or saltwater. In some embodiments the osmotic food production system also produces oxygen. In some embodiments, the osmotic food production system is portable and capable of transporting on a vehicle capable of space travel. Embodiments of the present invention can be used to address the existing problems of food production, waste disposal/utilization, oxygen generation, and water conservation in an efficient way to allow for prolonged space travel or colonization of distant planets and moons.

An apparatus for cultivating plants and a refrigerator according to a embodiment of the present disclosure includes a cabinet including a cultivation chamber with an open front; a door configured to be rotatably coupled to the cabinet by hinges to open and close the cultivation chamber and having a see-through window through which the interior of the cultivation chamber is capable of being seen; a bed provided to be introduced or withdrawn inside the cultivation chamber and on which a plurality of pods in which plants are cultivated are seated; a pair of side plates forming both sides of the machine room having a front which is opened at the lower portion of the cabinet; a pair of coupling frames configured to extend in the front and rear direction along the side plate in the machine room and to protrude further forward than the open front surface of the machine room; and a supporter coupled to the forward protruding portion of the pair of coupling frames and supported on the ground, in which the supporter is positioned below the door in a state where the door closes the cultivation chamber to prevent the cabinet from being overturned.

An apparatus for cultivating plants according an embodiment of the present disclosure includes a cabinet forming a cultivation space; a machine room configured to be positioned below the cabinet; a bed configured to be mounted inside the cultivation space; a water tank configured to supply water to the bed; and a drain member configured to be positioned between the cultivation space and the machine room; wherein the bed includes a water collecting portion configured to store water; and a water supply portion configured to supply water to the water collecting portion, wherein an end portion of a water supply pipe configured to supply water from the water tank to the water supply portion is positioned above the water supply portion, and wherein the drain member is positioned below the water supply portion.

A propagation system for growing seeds to seedlings, the propagation system comprising: a holding tank configured to be coupled to a water supply; a first plurality of rack docks and a second plurality of rack docks; a central wall disposed between and separating the first plurality of rack docks from the second plurality of rack docks, the central wall comprising water supply infrastructure configured to deliver nutriated water from the holding tank to the first and second plurality of rack docks and water return infrastructure configured to return nutriated water from the first and second plurality of rack docks to the holding tank; one or more pumps operatively coupled to pump nutriated water through the water supply infrastructure and through the water return infrastructure; wherein each rack dock in the first plurality of rack docks and each rack dock in the second plurality of rack docks defines a set of propagation tray locations, each propagation tray location in each set of propagation tray locations including at least one water supply line coupled to the water supply infrastructure and at least one water drain line coupled to the water return infrastructure.