An aquaponic grow system includes a plurality of sensors for sensing nutrient levels in liquid provided to a grow chamber, and to adjust nutrient levels based on the sensed levels. In some embodiments the system includes a plurality of sensors configured to sense nutrient levels in a common chamber, with the system configured to calibrate the sensors.

This invention pertains to a plant container. The plant container is characterised, essentially, by: a rigid frame (1) formed by at least two mounting supports (2), one for each side of the container, a top ring (3) preferably in a quadrilateral shape, supplemented with lateral and transverse (5) and longitudinal reinforcing beams (4); a soil, water or plant substrate reservoir (6) , supported on said frame; a water deposit (7); and a water transmission system to said substrate.

The present disclosure provides novel agricultural microbial inoculant compositions for uses in promoting plant growth, plant productivity and/or soil quality. The novel microbial inoculant compositions comprise one or more microbial species, one or more urease inhibitors and/or one or more nitrification inhibitors. The present disclosure also provides fertilizer compositions comprising said microbial inoculant compositions.

Embodiments described herein provide for multi-media structures 100 with growth enhancement additives for multiple stages of growth of an organism such as a plant, fungus or bacteria, including the production of individual media structures and multi-media structures 100 for multi-stage growth. Methods for the production of individual media structure and multi-media structures 100 with growth enhancement additives are provided. Methods for using multi-media structures 100 to grow an organism through multiple stages of growth such as root production, vegetative growth and flowering are also provided.

The present invention relates to an intelligent gardening system, for monitoring and controlling gardening apparatuses in a gardening area, including: multiple sensors that collect environmental information of the gardening area; one or more gardening apparatuses that perform gardening work according to a control instruction; and a control center that generates the control instruction based on the environmental information; wherein the sensors, the gardening apparatuses and the control center communicate with each other to form an Internet of Things.

Provided is a planting cup for hosting growing plants, for use in conjunction with hydroculture systems, and a development for producing same. The planting cup may be configured with a side wall formed with a plurality of openings and extending between an open bottom base and an open top base. The planting cup may also be constructed out of a sheet of pliable material.

An aeroponic system for supporting efficient low-resource-usage plant growth comprises a housing comprising one or more openings and one or more root chambers; one or more sealing members configured to substantially conform to a stalk of a plant and to substantially isolate a canopy of the plant from the one or more root chambers; one or more root chamber sensors; one or more nutrient storage reservoirs for storage of plant nutrients; one or more air-assisted nozzles configured to introduce atomized nutrient solution into the one or more root chambers; a temperature control system configured to control a temperature of the one or more root chambers; and a control system configured to control the temperature control apparatus and the one or more air-assisted nozzles to maintain environmental parameters associated with the one or more root chambers within desired parameter ranges.

A multilevel indoor mobile gutter system for growing vegetation including at least a first level and a second level is provided. Each level may include a first level conveyor and a second level conveyor respectively. A transfer conveyor is operable to convey from the first level to the second level. A plurality of lights are positioned to emit light towards the first level and the second level. At least one gutter is operable to support a plant within. The first level conveyor transports the at least one gutter from the front end to the rear end of the first level, the transfer conveyor transfers the at least one gutter from rear end of the first level to the front end of the second level, and the second level conveyor transports the at least one gutter from the front end to the rear end of the second level.

A hydroponic grow assembly including an assembly base and at least one plant structure removably connectable to the assembly base to form a plant wall for growing plants. The plant structure includes a plurality of plant wells opened to a root chamber and the base includes a bottom structure enclosed by a perimeter wall to form an inner cavity of a reservoir tank to supply water to the root chamber of the plant structure. The bottom structure includes a support feature within the inner cavity of the reservoir tank to support the at least one plant structure in an upright position to form the plant wall of the assembly.

An automatic vertical farming system including: vertical supports adapted to accommodate a plurality of tray-receptacles in a vertically-stacked arrangement showing a plurality of tray positions, the tray-receptacles each being adapted for farming plants in a soilless growing environment, wherein the vertical supports provide a tray position being an irrigation station for the tray-receptacles, and a tray-receptacle transport device arranged and adapted to move the tray receptacles along the vertical supports between different tray positions. The plant irrigation station includes: an irrigation device adapted to deliver a liquid into a tray-receptacle being accommodated in the irrigation station, and a tray manipulator arranged and adapted to manipulate the spatial orientation of the tray-receptacle being accommodated in the irrigation station by a movement of the tray-receptacle such that the liquid in the accommodated tray-receptacle is accelerated by gravity and/or the movement caused by the tray manipulator towards an edge of the tray receptacle.