A growing system is described. The growing system includes a conveyor system, at least one floating tray, a plurality of multifunction beams arranged to contain at least one row, a microclimate exchange system, and a nutriment supply system.

An automated aquaponics system and method of use comprising an autonomously operated plant growing conveyor belt system that allows the plant to germinate from seed capsules to fully grown plants that are then fully harvested for consumption while the plant roots are cut, chopped, cooked, and processed for the appropriate consumption of the aquarian species that resides within the aquaponic ecosystem.

A controlled environment agriculture system maximizes high quality yield, plant or organism density, and life cycle productivity. A combined structure contains automated conveyance and more than two vertically stacked planes of horizontal track that plants traverse throughout their life cycle. Nutritional support, controlled lighting, controlled climate and air flow are managed at each plane and coordinated across all planes as a system for optimized life cycle productivity. Plant or organism growth carriers are conveyed and connected to multiple planes with controlled elevators that enable continuous movement of plants throughout their lifecycle from seedling to harvest in a serpentine, carousel, or straight path configuration. Plants enjoy a variety of controlled environmental conditions including lighting, airflow, CO2, temperature and humidity configured to their organism type and optimized by life cycle stage. The ongoing movement provides an optimal environment for robust plant growth, eliminates the opportunity for pests to settle and lay eggs, and enables the ability to course correct organisms to higher yields.

Systems and methods for growing vegetation are provided. The disclosed systems (100) and methods (1100, 1200) use rotating growth mats (102) and a cutting device (112). The rotating growth mats and cutting device can be coupled to an anaerobic digester (402) to generated methane gas using vegetation grown on the growth mats. The systems and methods may further use C artificial light sources (108) and a nutrients delivery system (110) to assist growth.

Devices, systems, and methods for providing and operating a valve control module and valves in an assembly line grow pod are provided herein. Some embodiments include an assembly line grow pod having a plurality of fluid lines fluidly coupled between a fluid source and a fluid destination within the assembly line grow pod, a plurality of valves, each coupled to a fluid line such that fluid movement through the fluid lines is selectively controlled by the valves, and a master controller communicatively coupled to the valves. The master controller is programmed to receive information relating to fluid delivery within the assembly line grow pod, determine one or more valves to direct the fluid, determine valve parameters for each of the valves that achieve the fluid direction, and transmit one or more control signals to the valves for directing the fluid within the assembly line grow pod.

A gravity-driven plant cultivation system includes: (a) a frame; (b) a plurality of stacked conveyor assemblies mounted to the frame, each conveyor assembly including at least one gravity conveyor extending along a sloped conveyor axis; and (c) a plurality of plant cultivation trays rollingly supported on each gravity conveyor and urged to translate along a corresponding conveyor axis via gravitational force. Each tray includes: (i) a tray body having at least one underside surface parallel and in engagement with the gravity conveyor for supporting the tray thereon; (ii) a plurality of plant cavities in the tray body for holding plants; and (iii) a nutrient chamber internal the tray body for holding plant nutrient solution for the plants. The nutrient chamber is bounded from below by a nutrient chamber bottom wall lying in a horizontal plane for maintaining a constant depth of the plant nutrient solution.

A controller for a hydroponic growing apparatus, system, and method is provided. The controller includes a program-enable logic controller housed within a control housing and a graphical user interface operable by the programmable logic controller and disposed on the control housing. A home screen has one or more status indicators for each seed bed on the plurality of levels. A seeding screen has one or more seeding controls for actuating a seeder for depositing seed on each seed bed on the plurality of levels. A harvesting screen has one or more harvesting controls for autonamously controlling seed growth harvesting from each seed bed on the plurality of levels.

The present invention relates generally to agricultural growing apparatuses and methods. More specifically the present invention relates to a dynamic, modular, rotating apparatus, and methods related to the apparatus' use and/or function.

An aeroponic growing system includes a plurality of parallel vertical aeroponic growing apparatuses each having a closable loop articulated wall made up of vertical strips or panels that are pivotally attached side-by-side together with flexible joints. The motor-driven articulated wall moves on rails as an oblong-shaped carousel. The panels are provided with numerous plant-growing cups such that the growing plant extends outwardly out of the cup while the roots thereof are located inwardly of the wall. A spraying system delivers nutrients to the roots in darkness. On the external side, plants are exposed to controlled lighting provided by a programmable vertical LED system. Every growing step of the plants is optimized and supported by sensors and interactive software. The articulated wall is disengageable from its aeroponic growing apparatus to be displaced along a railing system between a grow room and other areas, and/or inverted for the roots to face outward.

An irrigation system for a vertical farming structure having vertical grow towers and associated conveyance mechanisms for moving the vertical grow towers through a controlled environment, while being exposed to controlled conditions, such as lighting, airflow, humidity and nutritional support. The present disclosure describes a grow tower conveyance system that moves vertically-oriented grow towers to select positions along a grow line. An irrigation line having apertures at the select positions provides aqueous nutrient solution to the grow towers, while a gutter structure captures excess solution. In a closed loop system, the excess solution returns to a recirculation tank. The present disclosure provides a dual pump system for effectively and efficiently removing excess nutrient solution from the gutter structure.