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.

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.

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.

Tray assemblies organized in a vertical stack with a grow light positioned above each. Plant nutrient solution flows into a feed reservoir positioned in a first end of the top assembly. When plant nutrient solution reaches the level of outlets positioned in a sidewall of the feed reservoir, it flows into longitudinal channels positioned on the tray assembly. A collection reservoir at a second end of the tray assembly collects excess solution from the channels. A lip positioned between the channels and the collection reservoir retains some of the solution in the channels so it is available to plants held by the tray assembly. Excess solution flows from the collection reservoir of the top tray assembly to a feed reservoir serving the next tray assembly in the stack. The pattern is repeated while alternating the orientation of each tray assembly such that solution is provided to each tray assembly.

The present invention provides a flower pot saucer. The flower pot saucer includes a base with a sidewall extending upwardly therefrom. The base has an upper surface and a lower surface. An aperture is disposed in the base. A screen covers the aperture and is affixed to the upper surface of the base along the periphery of the aperture. In some embodiments, the screen covers the aperture and is affixed to the bottom surface of the base. A plurality of wheels are affixed to the bottom surface of the base. A tube configured to direct the drainage of water that flows through the aperture is attached to the bottom surface of the base. The tube has a curve that redirects the water out and away from a side of the flower pot saucer. The flower pot saucer is both easily transpositioned and allows for proper water drainage.

This invention relates to a growing tray and growing tray system for a rotating hydroponic garden. The growing tray is shaped to hold a standard cube of hydroponic growing media with or without a basket with a cap to cover the top opening in the tray between the plants. The growing tray may include an indentation at the bottom of the growing tray to provide room for root growth expansion. The cap may additionally include a flap for covering the space between growing trays in a rotating hydroponic garden.

An automated plant cultivation system is provided having multi-tiered vertically arranged horizontal magazine structures each employing seed or plant capsules with a fluid circulation and illumination and communication network controlled by an on-board processor. Particularly, the system includes a magazine structure having seed/plant capsules within seed/plant reservoirs alternately arranged between at least one of a light source substantially concealed from direct viewing. A fluid channel extends across a long axis of the magazine structure, wherein the magazine structure is adapted for use of seed/plant capsules with nutrient composite plant growth cultivation, hydroponic plant growth cultivation, aeroponic plant growth cultivation methods or combinations thereof.

A system, method and apparatus for a container for a plant includes a body having a vertical axis, an open top, a base, a sidewall extending upward from the base, holes in the base and legs extending downward from the base. The holes comprise elongated slots and apertures that intersect each other.

An open-top gutter for cultivation of plants. In an example, the open-top gutter comprises at least one water space formed by a double edge and being closed at the top, or almost closed. The water space is open at the bottom of the gutter. In an example, the open-top gutter includes at least one separate water space formed by a partially double bottom and connected to the bottom of the gutter via a bottom gap. In an example, the open-top gutter includes a space limited by two side walls and a bottom wall and divided into trough-like compartments by at least one dividing wall. The dividing wall includes at least one water space formed by a double wall, open at the bottom of the gutter.