A hanging plant growing apparatus is provided for growing a plant in a hanging container. The hanging plant growing apparatus comprises a frame, suspension lines, a hanging element, and a liner nested within the frame. The suspension lines have a first end and second end. The second end secures to the frame and the suspension lines extend upwardly from the frame. The first end secures to the hanging element. The liner has a plurality of pores throughout and sufficient rigidity to maintain its shape when filled with a growing medium.

A plant growing system includes an outer shell, the outer shell being biodegradable, a rooting material, the rooting material comprising external ribbing, the external ribbing forming gaps between the outer shell and the rooting material when the rooting material is inserted in the outer shell, and one or more of a fertilizer, a nutrient, or a seed. The outer shell and the rooting material form a water reservoir, the water reservoir in communication with the gaps and, prior to the plant growing system being watered, comprising the fertilizer or nutrient.

A system for growing a plant (1) in an at least partly conditioned environment includes a cultivation base (11) for receiving a culture substrate (3) with a root system (4) of the plant therein. Root temperature control elements (12) are provided which are able and adapted to impose a predetermined root temperature on the root system, and lighting elements (20,21,22) which are able and adapted to expose leaves of the plant to actinic artificial light. Leaf heating elements are also provided, which are able and adapted to impose on the leaf of the plant a leaf temperature varying from an ambient temperature. In a method for growing the plant a carbon dioxide assimilation management of a leaf system of the plant is thus influenced, and a supply of actinic light, the root temperature and the carbon dioxide assimilation management are adapted to each other.

A system for growing a plant (1) in an at least partly conditioned environment includes a cultivation base (11) for receiving a culture substrate (3) with a root system (4) of the plant therein. Root temperature control elements (12) are provided which are able and adapted to impose a predetermined root temperature on the root system, and lighting elements (20,21,22) which are able and adapted to expose leaves of the plant to actinic artificial light. Leaf heating elements are also provided, which are able and adapted to impose on the leaf of the plant a leaf temperature varying from an ambient temperature. In a method for growing the plant a carbon dioxide assimilation management of a leaf system of the plant is thus influenced, and a supply of actinic light, the root temperature and the carbon dioxide assimilation management are adapted to each other.

The system includes a pre-fabricated garden seedsheet, with seeds and soil embedded in water-soluble pods within a weed barrier fabric. Each water-soluble pod is fabricated from dissolvable material, which are affixed together to form cavities in which seeds and soil are applied. The pods are then affixed to the weed barrier matrix in an arrangement dictated by the plant algorithm. Upon contact with water, the pods rapidly dissolve, thereby beginning the germination process in which the seeds sprout and emerge through the aligned openings in the weed barrier fabric. The selection of plants and their physical arrangement within each seedsheet may be determined by a software-driven plant algorithm that extrapolates plant characteristics, environmental requirements, and companion benefits. The algorithm may be used both on the customer-facing software program, as well as the in-house design process to create pre-designed seed sheets.

The system includes a pre-fabricated garden seedsheet, with seeds and soil embedded in water-soluble pods within a weed barrier fabric. Each water-soluble pod is fabricated from dissolvable material, which are affixed together to form cavities in which seeds and soil are applied. The pods are then affixed to the weed barrier matrix in an arrangement dictated by the plant algorithm. Upon contact with water, the pods rapidly dissolve, thereby beginning the germination process in which the seeds sprout and emerge through the aligned openings in the weed barrier fabric. The selection of plants and their physical arrangement within each seedsheet may be determined by a software-driven plant algorithm that extrapolates plant characteristics, environmental requirements, and companion benefits. The algorithm may be used both on the customer-facing software program, as well as the in-house design process to create pre-designed seed sheets.

A plant growing vessel includes an impervious outer vessel, a cover, a first permeable membrane, a nutrient chamber, and a pocket. The impervious outer vessel includes an inert substrate in a root zone. The cover is positioned over the impervious outer vessel. The first permeable membrane is in contact with the inert substrate. The nutrient chamber includes solid nutrients. The nutrient chamber is between the cover and the first permeable membrane or between the first permeable membrane and a bottom of the impervious outer vessel, and the solid nutrients are in contact with the first permeable membrane. The pocket is configured to allow seeds, seedlings, or shoots of plants access to the inert substrate through an aperture in the cover.

A container for growing a plant. The container includes at least one container wall having a surface, the container wall having one or more light reflective and/or refractive members attached thereto. The one or more light reflective and/or refractive members may include one or more silicate microbeads that are buffered to neutrality. The container may contain a plant, and the one or more light reflective and/or refractive members may be positioned in the container to redistribute light toward the plant, and may be present in an amount effective to cause harmful light saturation of the plant. To safen the plant from such harmful light, the container also may contain one or more glycopyranosidic compounds, such as one or more alkyl-α-D-mannosides.

A container for growing a plant. The container includes at least one container wall having a surface, the container wall having one or more light reflective and/or refractive members attached thereto. The one or more light reflective and/or refractive members may include one or more silicate microbeads that are buffered to neutrality. The container may contain a plant, and the one or more light reflective and/or refractive members may be positioned in the container to redistribute light toward the plant, and may be present in an amount effective to cause harmful light saturation of the plant. To safen the plant from such harmful light, the container also may contain one or more glycopyranosidic compounds, such as one or more alkyl-α-D-mannosides.

An automated outdoor modular vertical plant cultivation system forming a vertical structure is provided. The system includes a plurality of shelves, each shelf having a web and flanges; two posts, each post having a web and flanges. Each shelf of the plurality of shelves is mounted between the two posts with incremental spacing between each adjacent shelf along a vertical length of the two posts. The web of each shelf includes a plurality of openings for retaining planter vessels. The flanges of each shelf retain an embedded structural member. The system includes a fluid circulatory system including shelf irrigation piping extending longitudinally above the web of each shelf; and power or power and data and fluid members for the system distributed from vertical risers located in proximity to the web of the posts, wherein the flanges of the shelves have provisions to retain the fluid circulatory system.