This invention pertains to a plant container. The plant container is characterised, essentially, by: a rigid frame (1) formed by at least two mounting supports (2), one for each side of the container, a top ring (3) preferably in a quadrilateral shape, supplemented with lateral and transverse (5) and longitudinal reinforcing beams (4); a soil, water or plant substrate reservoir (6) , supported on said frame; a water deposit (7); and a water transmission system to said substrate.

The following disclosure relates to a valve assembly for allowing filling and draining of a container with a liquid, preferably for use in growing plants, the valve comprising: a filling catchment containing at least one opening for receiving liquid and at least one drainage orifice, the filling catchment being located within the container; a draining outlet adapted to convey liquid out of the container; a plugging member configured to move between a first position where the plugging member allows liquid to flow into the draining outlet and a second position where the plugging member prevents liquid from flowing through the draining outlet; and a biasing member which acts to retain the plugging member in the first position unless a force is applied above a predetermined value. Also provided are systems including and methods of using said valve assembly.

An indoor gardening appliance includes a grow module rotatably mounted within a liner to at least partially define a first grow chamber and a second grow chamber. A climate control system includes an evaporator plenum housing an evaporator, a fan assembly for urging air through the evaporator plenum, recirculation ducts for independently circulating air through the first grow chamber and the second grow chamber, and ambient duct systems for independently circulating fresh ambient air through the first grow chamber and the second grow chamber. A system of dampers selectively opens or closes each respective recirculation duct and ambient duct system for independent climate control of the first grow chamber and the second grow chamber.

An indoor gardening appliance includes a grow module rotatably mounted within a liner to at least partially define a first grow chamber and a second grow chamber. A climate control system includes an evaporator plenum housing an evaporator, a fan assembly for urging air through the evaporator plenum, recirculation ducts for independently circulating air through the first grow chamber and the second grow chamber, and ambient duct systems for independently circulating fresh ambient air through the first grow chamber and the second grow chamber. A system of dampers selectively opens or closes each respective recirculation duct and ambient duct system for independent climate control of the first grow chamber and the second grow chamber.

A Vertical-Hive Green Box (or V-Hive Green Box) is a modular cultivation system utilized in a modular Vertical Farm or Plant Factory, as well as a warehouse-type or greenhouse-type of vertical farm or plant factory. The V-Hive Green Box includes growing boards, lighting boards, and an irrigation system arranged within a frame structure to maximize the quantity of crops that can be grown within an available volume of space in a modular Vertical Farm unit, warehouse or greenhouse per unit time. The V-Hive Green Box can also include aquaculture boards that can be used for aquaculture of aquatic fish and plants.

A lighting system for a vertical farm can include a plurality of modules configured to be stacked and removably coupled physically and electrically to one another by at least one overhead robot. Each of the plurality of modules can include at least one physical and electrical connector. At least some of the modules can include one or more lighting elements.

A stackable pot assembly having pots arranged in horizontal and vertical directions to form the stacked pot assembly. The assembly includes two or more blocks mounted over each other. The first block mounted over the floor, the first block has one or more rows of twin-bases arranged lengthwise or side-by-side. The upper blocks mounted one over another, and the upper blocks mounted over the first block. The upper block comprises twin-pots and round-pots. The twin-pots and round-pots have feet configured in their bottom, wherein the twin-pot has two spaced-apart feet while the round pot has a single feet. A lid secures the twin-bases, twin-pots, and round-pots, wherein the lid has apertures for receiving the feet when a twin-pot or a round-pot is mounted over the lid secured to below block. The lid is further having a plant hole.

A storage system is disclosed where goods can be stored in containers and the containers are stored in stacks. Above the stacks runs a grid network of rails (e.g., tracks) on which load handling devices can run. To take containers from the stacks and deposit then at alternative locations in the stacks or deposit then at stations where goods may be picked. The framework may be provided with one or more of the following exemplary services: power, power control, heating, lighting, cooling, sensors, and data logging devices. The provision of these services within the framework rather than across the system as a whole, can allow for flexibility in storage whilst reducing cost and inefficiency.

An automatic vertical farming system may include a frame defining at least one growth area and configured to support a plurality of vertical plant growth structures within the at least one growth area. The system may include at least one light, at least one liquid conduit, and at least one gas conduit. The system may include at least one robot disposed on a top side of the frame and movably supported by the frame. The at least one robot may include at least one tool configured to manipulate the plurality of vertical plant growth structures. The system may include a control system including at least one processor configured to automatically control illumination by the at least one light, liquid flow through the at least one liquid conduit, gas flow through the at least one gas conduit, and operation of the at least one robot.

The disclosed container defines (i) an “interior” configured to interact with a fluid and/or developing plants, and (ii) an “exterior” that at least partially defines a perimeter around the interior. The disclosed container may further include stacking features/elements which allow one container to be stacked/nested one upon the other. The disclosed container may further include features/elements which enable one container to be connected adjacent to the other. The disclosed container may further include (i) features/elements for delivering fluid, (ii) features/elements for draining fluid, and (iii) features/elements for supporting developing plants that are conducive to their growing within the disclosed container.