A disclosed vertical planter box assembly includes perimeter walls defining an interior space for holding plants. The perimeter wall includes openings aligned around the interior space. A water basin is provided at a top side for communicating water into the interior space. A drip tray is supported below a bottom side for capturing draining water from the interior space. A plurality of pins extend through the openings and across the interior space to hold the plant structures in place within the interior space.

A rainwater distribution system for storing and distributing rainwater includes a first container configured to store rainwater and having a bottom wall and a side wall; a planting container being elevated off of the bottom wall and within the first container, and having a planting container bottom wall and a side wall; a planting container support configured to elevate the planting container off of the bottom wall and within the first container; a cascade aperture having a cascade filter, the cascade aperture positioned on the side wall of the planting container, and allows the rainwater that enters the planting container to exit the planting container into the first container; and an outlet aperture positioned on the side wall of the first container and configured to allow the rainwater to exit the first container at a controlled rate.

A rainwater distribution system for storing and distributing rainwater includes a first container configured to store rainwater and having a bottom wall and a side wall; a planting container being elevated off of the bottom wall and within the first container, and having a planting container bottom wall and a side wall; a planting container support configured to elevate the planting container off of the bottom wall and within the first container; a cascade aperture having a cascade filter, the cascade aperture positioned on the side wall of the planting container, and allows the rainwater that enters the planting container to exit the planting container into the first container; and an outlet aperture positioned on the side wall of the first container and configured to allow the rainwater to exit the first container at a controlled rate.

Disclosed is a self-watering insert for placement within a plant container, the insert comprising a one-piece self-supporting structure having an open bottom end, a closed top end, downwardly-sloping sidewalls, an open or closed interfacing structure that facilitates a secure seal of the insert against an interior wall of the plant container, an open collar on the top to allow temporary insertion of a pipe or water-discharging mechanism into the watering insert, a plurality of holes and/or screen/fabric material permanently attached to the surface of the top end, allowing water and air to pass through the surface. A lower flange extends circumferentially around the bottom end of the water insert, thereby creating a shelf upon which growing medium rests; the flange further featuring downward protruding fins spaced so as to provide channels through which water passes from underneath the interior of the watering insert to its exterior.

Disclosed is a self-watering insert for placement within a plant container, the insert comprising a one-piece self-supporting structure having an open bottom end, a closed top end, downwardly-sloping sidewalls, an open or closed interfacing structure that facilitates a secure seal of the insert against an interior wall of the plant container, an open collar on the top to allow temporary insertion of a pipe or water-discharging mechanism into the watering insert, a plurality of holes and/or screen/fabric material permanently attached to the surface of the top end, allowing water and air to pass through the surface. A lower flange extends circumferentially around the bottom end of the water insert, thereby creating a shelf upon which growing medium rests; the flange further featuring downward protruding fins spaced so as to provide channels through which water passes from underneath the interior of the watering insert to its exterior.

An improved insulating performance fabric has a double-knit body, formed with traditional, relatively smooth, outer surfaces, and an inner surface with the form of multiple fabric bubbles separated, e.g., by a grid pattern of intersecting grooves. An insulating, double-knit performance fabric of this disclosure may also be found in the form of a garment comprising the insulating, double knit performance fabric, or in the form of fabric article comprising the insulating, double knit performance fabric, etc.

An improved insulating performance fabric has a double-knit body, formed with traditional, relatively smooth, outer surfaces, and an inner surface with the form of multiple fabric bubbles separated, e.g., by a grid pattern of intersecting grooves. An insulating, double-knit performance fabric of this disclosure may also be found in the form of a garment comprising the insulating, double knit performance fabric, or in the form of fabric article comprising the insulating, double knit performance fabric, etc.

A self watering bottle planter insert allows a regular bottle to be transformed into a hydroponic planter. The self watering bottle planter insert is insertable into a bottle and removes the need for a separate source of nutrients. The planter uses composite media with an enriched substrate layered beneath a more standard hydroponic growth media to add nutrients to the water for the life cycle of the plant. Also provided is a substrate assembly for use in a bottle planter assembly.

A self watering bottle planter insert allows a regular bottle to be transformed into a hydroponic planter. The self watering bottle planter insert is insertable into a bottle and removes the need for a separate source of nutrients. The planter uses composite media with an enriched substrate layered beneath a more standard hydroponic growth media to add nutrients to the water for the life cycle of the plant. Also provided is a substrate assembly for use in a bottle planter assembly.

An indoor gardening appliance includes a liner defining a grow chamber and a grow module mounted within the grow chamber for receiving a plurality of plant pods. A nutrient dosing system is positioned within a root chamber and includes a plurality of nozzles. A nutrient cartridge and a water supply are fluidly coupled to a dilution tank and are independently regulated to control the flow rate of nutrients and water that are mixed to create a flow of diluted nutrient mixture. A pump system selectively discharges the flow of diluted nutrient mixture to desired locations within the root chamber.