A method for tracking seeds in an assembly line grow pod having a plurality of carts is provided. A target seed is deposited in a selected cell which is a part of a selected tray located in a selected cart travelling on an assembly line grow pod. A position of the target seed is tracked in the selected cell by determining the position of the target seed in the selected cart and determining a position of the selected cart in the assembly line grow pod. Sustenance is provided to the target seed including the selected cell. A growth factor of the target seed is determined in the selected cell. Upon determination that the growth factor of the target seed in the selected cell is below a predetermined threshold, supply of the sustenance provided to the selected cell is adjusted.

An air flow control system for an assembly line grow pod is provided. The air flow control system includes a shell including an enclosed area, one or more carts moving on a track within the enclosed area, an air supplier within the enclosed area, one or more outlet vents coupled to the air supplier, and a controller. The controller includes one or more processors, one or more memory modules, and machine readable instructions stored in the one or more memory modules that, when executed by the one or more processors, cause the controller to identify a plant on the one or more carts, determine an airflow rate based on an airflow recipe for the identified plant, and control the air supplier to output air through the one or more outlet vents at the airflow rate.

A closed loop system for growing vegetation is provided. The closed loop system includes at least a first transport conveyor and a second transport conveyor. Each of the first and second transport conveyors includes a front end opposite a rear end. The present invention further includes at least a first transfer conveyor. A lighting system is positioned to emit light towards the first transport conveyor and a second transport conveyor. The present invention further includes at least one terrace structure. The first transport conveyor transports at least one terrace structure from the front end to the rear end, the first transfer conveyor transfers the at least one terrace structure from rear end of the first transport conveyor to the front end of the second transport conveyor and the second transport conveyor transports the at least one terrace structure from the front end to the rear end.

A plant cultivation apparatus including a conveyor that contains a conveying device for a cultivation bed and a blowing means that sends a flow of air to plants on the cultivation bed on the conveying device. The plant cultivation apparatus is provided with a space for causing the flow of air to pass between the cultivation bed adjacent in a conveying direction and pass through a bottom surface of the conveying device.

The present disclosure is directed to improved vertical farming using autonomous systems and methods for growing edible plants, using improved stacking and shelving units configured to allow for gravity-based irrigation, gravity-based loading and unloading, along with a system for autonomous rotation, incorporating novel plant-growing pallets, while being photographed and recorded by camera systems incorporating three dimensional/multispectral cameras, with the images and data recorded automatically sent to a database for processing and for gauging plant health, pest and/or disease issues, and plant life cycle. The present disclosure is also directed to novel harvesting methods, novel modular lighting, novel light intensity management systems, real time vision analysis that allows for the dynamic adjustment and optimization of the plant growing environment, and a novel rack structure system that allows for simplified building and enlarging of vertical farming rack systems.

An apparatus for cultivation of long-stem vegetable plants, related system, methods and uses are provided. The apparatus includes a frame rack with at least one essentially horizontal cultivation platform configured to support a stem portion of at least one long-stem vegetable plant rooted in a static cultivation tray, wherein each the cultivation platform is established by a conveying device and wherein speed of the conveying device is adjustable such, as to correspond to the speed of plant growth.

The invention provides a horticulture system (1) comprising a plurality of repeating horticulture system units (100) and a control system (300), wherein: each horticulture system unit (100) comprises (i) a horticulture unit space (110) and (ii) a radio transmission pair (120) arranged to monitor the horticulture unit space (110), wherein the radio transmission pair (120) comprises a radio transmitter and a radio receiver arranged in radio signal receiving relationship; the control system (300) is configured to execute in a unit sensing stage (230) a measurement in at least one of the horticulture unit spaces (110) with the respective radio transmission pair (120); the control system (300) is further configured in an operational mode to: (i) execute a first signal sensing stage (231), wherein the first signal sensing stage (231) comprises the unit sensing stage (230) with a first radio transmission pair (121) related to first horticulture unit space (111) thereby providing a first signal (241) to the control system (300); and (ii) determine a plant-related parameter data based on (a) the first signal (241) and (b) a baseline signal (245), wherein the baseline signal (245) is based on a second signal (242) obtained with an execution of a second signal sensing stage (232), wherein the second signal sensing stage (232) comprises the unit sensing stage (230) with a second radio transmission pair (122) related to a second horticulture unit space (112) thereby providing the second signal (242).

The present invention relates to a self-contained growth system that functions as a stand-alone growth system or combined with a hydroponic or aeroponic growth system for the controlled growth of plants. A Spiral Tower having an entry port for seedling or seeds embedded onto trays floating on a downward spiraling water flow provides a closed environment with optimum nutrient and growth conditions for each plant type. The Spiral Tower is capable of germinating seedlings in a closed environment for subsequent maturation in an aeroponic or other system. As a stand-alone growth system, the Spiral Tower is capable of the continued growth of certain early life plants. Other applications as a seed to harvest system used in harvesting wheatgrass and similar plants. The system is designed for cost-effective use in restricted space and in regions not conducive for commercial plant production.

Embodiments disclosed herein include a farm arranged to grow crops. In some embodiments, the farm includes a seeding station, an irrigation and growing station, and a harvesting and packaging station. In some embodiments, the farm is arranged to grow crops via to a hybrid aeroponic and hydroponic irrigation system. In some embodiments, the crops are grown in a container having a hydroponic irrigation zone and an aeroponic irrigation zone.

A system for vertical hydroponic plant growing. The system, and associated apparatuses and methods, may include or use sprockets, a sprocket drive device that is connected to at least one sprocket among the sprockets, a first continuous loop chain that is mounted on the sprockets, a second continuous loop chain that is mounted on the sprockets, and trays. Each tray includes a first end and a second end that includes a drain hole. The trays are attached to the first continuous loop chain and to the second continuous loop chain. The system also includes a fluid-dispensing device that is configured to dispense a fluid into a tray that is moved by the chains to a position adjacent to the fluid-dispensing device. The chains are configured to longitudinally tilt a tray downward towards the drain hole while the tray is near the position adjacent to the fluid-dispensing device.