A gardening apparatus includes one or more of a base, a fluid reservoir, and a plant tray or support disposed on the reservoir. The support is adapted for receiving one or more modular plant inserts, and can define a flow structure for channeling fluid to each insert. A pump supplies fluid from the reservoir to the plant tray or support, with a light assembly adapted to generate a spectrum of light for growth of plants from the inserts. A processor is configured for controlling fluid flow from the pump, the light spectrum generated by the lighting elements, or both. For example, the processor can use a dynamic recipe, algorithm or control schedule to modulate the fluid flow or spectrum based the plant type, growth stage, height, plant health data, digital phenotyping data, or ambient conditions, or a combination thereof.

A planter and planter stack are described. The planter includes a planter pot configured to be nestable with other such planter pots. The planter pot includes a base, a planter sidewall integrally formed on the base and extending upwards towards a rim, and a hollow support pillar formed on the base and extending substantially vertically upwards with a drain opening at the top of the hollow support pillar in communication with an exterior side of the base. The planter further includes a removable riser configured to be nestable with other such removable risers. The removable riser includes a plate supported by an interior of the planter sidewall by an interference fit, and an aperture configured to accept a corresponding hollow support pillar.

A planter and planter stack are described. The planter includes a planter pot configured to be nestable with other such planter pots. The planter pot includes a base, a planter sidewall integrally formed on the base and extending upwards towards a rim, and a hollow support pillar formed on the base and extending substantially vertically upwards with a drain opening at the top of the hollow support pillar in communication with an exterior side of the base. The planter further includes a removable riser configured to be nestable with other such removable risers. The removable riser includes a plate supported by an interior of the planter sidewall by an interference fit, and an aperture configured to accept a corresponding hollow support pillar.

An irrigation apparatus and feeding system for dispersing liquid through a plant growing medium is disclosed. The apparatus includes a first and a second geometrically shaped container each having an outer wall with an inner surface, an open top, and a base portion configured to cover the plant growing medium. Second container is configured to be positioned within first container such that base portion of second container sets atop base portion of first container and is secured therein from an open position to a closed position thereby forming a single unit. Each base portion is configured with a plurality of elongated holes for receiving liquid therethrough such that holes of first and second container are offset from one another for blocking light from penetrating therethrough when second container is secured within first container in closed position. First and second container are configured with at least one center opening therethrough having an inner wall for receiving a plant such that center opening has at least one longitudinal opening extending therefrom to outer wall to allow placement of first and second container on the plant or to allow removal of first and second container from the plant.

An irrigation apparatus and feeding system for dispersing liquid through a plant growing medium is disclosed. The apparatus includes a first and a second geometrically shaped container each having an outer wall with an inner surface, an open top, and a base portion configured to cover the plant growing medium. Second container is configured to be positioned within first container such that base portion of second container sets atop base portion of first container and is secured therein from an open position to a closed position thereby forming a single unit. Each base portion is configured with a plurality of elongated holes for receiving liquid therethrough such that holes of first and second container are offset from one another for blocking light from penetrating therethrough when second container is secured within first container in closed position. First and second container are configured with at least one center opening therethrough having an inner wall for receiving a plant such that center opening has at least one longitudinal opening extending therefrom to outer wall to allow placement of first and second container on the plant or to allow removal of first and second container from the plant.

The invention relates to a flower pot (1) comprising an inner element (2) with a cover (4) in which multiple fluid openings (8) are formed, an outer element (3) which surrounds the inner element (2) and which has a base (9), a lateral wall (10) protruding from the base (9) and a liquid storage chamber (11), the height of the lateral wall (10) of the outer element (3) being lower than the cover (4) of the inner element (2) and, at least one filling and viewing opening (12) between the inner element (2) and the outer element (3) for filling the liquid storage chamber (11) with liquid and for visually checking a level of the liquid in the liquid storage chamber (11) of the outer element (3).

The present invention relates to a flower pot of a double structure comprised of an inner container and an outer container. The present invention relates in particular to a flower pot of a double structure comprised of an inner container and an outer container, in which an inside container for planting a plant is designed to be transparent so that how the plant is rooted or watered is observable, and the interior of the pot is completely shielded from the light by preventing the light from entering from above and an outside container covering the pot is completely shielded from the light so that moss is suppressed from being grown on the inner surface of the pot and the plant can be grown in a most suitable environment without applying the light to the roots.

The pot is of a double structure comprised of the inner container 11 and the outer container 21 disposed outside the inner container 11. The inner container 11 is transparent and an upper part of the inner container is shielded from the light and the outer container 21 is colored in a completely lightproof color or formed of a completely lightproof material.

Assembly (1) of a patio pot (3), a plant pot support (9) and at least one plant pot (2,4), wherein the plant pot support (9) comprises a through-opening with a wick (6) accommodated in the through-opening of the plant pot support (9) to extend there through towards a fluid reservoir (5) in the patio pot (3).

Described herein are example portable indoor hydroponic garden assemblies and associated methods of use. The portable indoor hydroponic garden assemblies can include features that facilitate hydroponic gardening in an indoor environment, including structural features that enhance the indoor environment itself, such as through sounds, smells, textures, sights, and so on. In an example, the portable indoor hydroponic garden system includes a tiered growing assembly housed fully within an enclosure. The tiered growing assembly can include a group of trays defining tiers that are recessed from one another, allowing water or other fluid to flow from tray to tray, creating waterfall features there between that can aerate the water and emit a pleasurable sound to the indoor environment. The enclosure can be climate controlled and thus adaptable to a variety of indoor conditions to grow desired plants, including embodiments using programmable heating and lighting systems.

A vertically oriented aquaponics stand having a basin, a frame, and a grow bed.