A plant growing, transportation, display, and maintenance system including a plant pot and corresponding container having a selectable valve that controls the flow of liquid into and out of the container.

A self-watering planter features wicking devices whose outer tubes feature a skeletal upper structure having a plurality of columns periodically interconnected by rings spanning circumferentially around the wicking material to delimit windows of large area for optimum water seepage to the soil. A flange at the bottom of the tube's skeletal upper portion cooperates with snap features at the top of a lower portion that hangs in the water reservoir to provide snap-fit installation of the wicking devices on a divider wall of a permanently enclosed planter. A soil drainage filtration device features filtration fabric held in a sandwiched state around a drainage opening in the divider wall by one or more mounting plates. In one embodiment, the fabric forms a sack that hangs into the reservoir to suspend a volume of soil therein, whereby the suspended soil serves as wicking agent in the absence of excess rainwater needing drainage.

A self-watering planter features wicking devices whose outer tubes feature a skeletal upper structure having a plurality of columns periodically interconnected by rings spanning circumferentially around the wicking material to delimit windows of large area for optimum water seepage to the soil. A flange at the bottom of the tube's skeletal upper portion cooperates with snap features at the top of a lower portion that hangs in the water reservoir to provide snap-fit installation of the wicking devices on a divider wall of a permanently enclosed planter. A soil drainage filtration device features filtration fabric held in a sandwiched state around a drainage opening in the divider wall by one or more mounting plates. In one embodiment, the fabric forms a sack that hangs into the reservoir to suspend a volume of soil therein, whereby the suspended soil serves as wicking agent in the absence of excess rainwater needing drainage.

A system and method for cultivating plants is described. The system may include a tower structure having a vertical series of vessels for holding a netted pot or other container. The system may have a pressurized irrigation system that is in fluid communication with each vessel. The system may further include lamps to provide an adequate light source. The system may also include sensors, monitors and controls to establish and maintain environmental conditions suitable for proper plant growth. The system may further be implemented as a scalable system in which multiple tower structures may be installed into a scaffold system. Sets of towers may be slidably affixed to a scaffold such that the towers may be slid along a track thereby creating easy access to the plants, vessels, lights and the irrigation system. The system may be expanded to include multiple scaffolds affixed to a skeletal frame or compartment interior.

A vertical farming structure having vertical grow towers and associated conveyance mechanisms for moving the vertical grow towers through a controlled environment, while being exposed to controlled lighting, airflow, humidity and nutritional support. The present disclosure describes a reciprocating cam mechanism that provides a cost-efficient mechanism for conveying vertical grow towers in the controlled environment. The reciprocating cam mechanism can be arranged to increase the spacing of the grow towers as they are conveyed through the controlled environment to index the crops growing on the towers. The present disclosure also describes an irrigation system that provides aqueous nutrient solution to the grow towers.

A method and an environment simulating system are disclosed which includes a database comprising a library of climate recipes characterizing growing environments for different plants and trees; a micro-controller electrically coupled to receive specific climate recipes when orders for different plants and trees are received from customers; an environment actuating system, electrically coupled to the micro-controller, operable to receive the specific climate recipes from the database; a sub-controller electrically coupled to receive the specific climate recipes from the micro-controller to drive the environment actuating system to generate specific growing environments in a growing enclosure in accordance with the specific orders; an array of web-based sensors, coupled to the growing enclosure and the micro-controller, operable to sense growing conditions of the specific growing environments and to feedback the growing conditions to the micro-controller; and a network server adapted to couple the Database, the micro-controller, the sub-controller, the array of web-based sensors, the growing enclosure, and the customers to a network.

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.

Disclosed are embodiments of an apparatus for displaying and watering vegetation, which watering can be automated. The apparatus can include a base portion, a support member coupled with the base portion and extending generally upwardly away from the base portion, a bracket, a tray supported by the bracket, a container, at least one conduit in fluid communication with the container and configured to communicate a liquid from the container to the tray, and a pump comprising electronic circuitry configured to control an operation of the pump. The pump can be configured to pump a liquid from the container through the conduit to the tray to water at least one plant that can be supported by the tray.

A storage assembly includes a body with a space defined axially therethrough. A tray is connected to the top of the body and multiple pivotable members are pivotably connected to the body and the tray. Each member includes a reception portion for storage purpose, and a cover is mounted to the reception portion. A tube is inserted in a connection portion of the tray and receives fishes and plants in the tube. A base is connected to the underside of the body and is connected with a light device on the top thereof. The pivotable members can be pivoted to enclose the tube or to be pivoted outward around the tube.

A storage assembly includes a body with a space defined axially therethrough. A tray is connected to the top of the body and multiple pivotable members are pivotably connected to the body and the tray. Each member includes a reception portion for storage purpose, and a cover is mounted to the reception portion. A tube is inserted in a connection portion of the tray and receives fishes and plants in the tube. A base is connected to the underside of the body and is connected with a light device on the top thereof. The pivotable members can be pivoted to enclose the tube or to be pivoted outward around the tube.