The present disclosure relates to a plant cultivating apparatus. The plant cultivating apparatus according to an aspect of the present disclosure includes a body configured to have a cultivation chamber therein, a water storage configured to be disposed in the body and store water, a water supply bed configured to be disposed at one side of the cultivation chamber and have a water supply flow path receiving water from the water storage, and a cultivation port configured to be seated on the water supply bed and receive water from the water supply flow path, in which the cultivation port includes a suction member disposed in the cultivation port and suctioning water stored in the water supply flow path, and a medium disposed above the suction member, receiving water from the suction member, and storing nutrients required for plant growth.

A greenwall cladding system for the growth of organisms such as plants and fungi on the side of structures, such as internal and external walls of buildings, is provided. Methods for the production of organisms on a greenwall cladding system, such as plants and fungi are also provided herein.

A system includes one or more machines carrying out steps in a plant production process using growing towers, beginning after harvest and concluding immediately after transplanting. These steps include media removal, plant waste disposal, media cleaning, tower cleaning, and tower re-transplanting. A material handling scheme may be used to manage the flow of towers to and from the machine and across the growing system.

A soil-free cultivation system including a cultivation container into which a growing solution is conducted in order to cultivate plants, the cultivation container having two root compartments and a centrally positioned solution compartment.

An aeration container system for plants having aerial roots, comprising an aeration container comprising a plurality of elongate curved vanes, each vane comprising a top portion, lower portion, a first planar side and a second planar side opposing the first planar side, the planar sides connecting a front edge, outer edge and the top and bottom portions. A reservoir is also provided wherein each vane is equidistantly spaced and attached perpendicular to an outside surface of the reservoir and focus light and ambient airflow from outside the aeration container to inside the aeration container.

The present invention is a scalable and re-configurable system for indoor growing. The scalable and re-configurable system for indoor growing is comprised of a plurality of growing sleds, in which each growing sled has a plurality of plant stations. Plants are grown in receptacles on each plant station. The plant station is rotated by a drive system. Each plant station provides irrigation. Each plant station has a forced frame connected to the top of a plant support assembly. A forced frame is used to confine each plant to a known foot-print. This is necessary in indoor growing in order to make the production uniform and efficient.

A growing medium for a plant production apparatus utilized in greenhouse crop production is provided. The growing medium comprises a fibrous, non-woven matrix media material wherein the media material is constructed from a plastic material.

The hydroponic growing system may include a gutter assembly configured to manage flow of a liquid solution to one or more components of the hydroponic growing system. Further, the hydroponic growing system may include at least one growing trough movably engaged to the gutter assembly and configured to hold one or more plants. Moreover, the hydroponic growing system may include an automation assembly movably engaged with the at least one growing trough and configured to move the at least one trough from a first position on the gutter assembly to a second position on the gutter assembly via one or more engagement devices.

A plant grow tray system comprising a plurality of trays comprising at least one upper tray and at least one bottom tray is provided. The upper tray is placed inside the bottom tray with upper tray supports between the upper tray and the bottom tray creating a space between the trays. The upper tray and the bottom tray comprise a sealing mechanism to seal the upper tray to the bottom tray. The upper tray has a corrugated profile with crest and trough portions, air holes on the corrugated surface, a drain basin, drain flange, and drain pipe. The bottom tray has an air-flow modifier, air flange, and a drain hole. The system is designed to allow air to be ducted or exhausted from the space between the upper tray and the bottom tray enabling the delivery of conditioned, fresh, or recirculated air directly to a plant.

A gutter assembly is provided that is configured to collect water passing through a plurality of vertical hydroponic towers, the assembly minimizing leakage while simplifying gutter maintenance. The gutter assembly includes a gutter pipe from which an upper portion has been removed to form a pair of mounting ledges. The gutter assembly also includes a gutter cap that is attached to the gutter pipe via the mounting ledges using a snap fit system.