The present invention relates to a modular personal growing system (PGS). The components of a PGS are designed to work in unison to grow plants hydroponically from seed to maturity. A PGS can be scaled and configured into a desired interior or exterior space requirement for residential or commercial use. The individual components of a PGS may include a stand, a trellis, a vessel, a luminaire and an enclosure.

A device for a multi-pot system consisting of at least 3 plant pots and a water collection tray suitable for collecting excess water from these plant pots, wherein the plant pots comprise a bottom with openings, a wall that rises from the bottom, and 3-8 legs, wherein the legs are located at the bottom, along the other side of the wall, characterized in that the water collecting tray comprises a top with at least 3 indentations, wherein the height of the legs of a plant pot differs by a maximum of 10% from the depth of at least one indentation and the diameter of an indentation differs by a maximum of 10% from the diameter of the bottom of at least one plant pot.

A farming system and a control facility are disclosed, the farming system including a growing facility having at least one growing floor including a track network, based on a grid system. The track network includes access aisles and growing aisles, wherein the growing aisles include one or more booths for receiving growing trays. A booth includes a support for supporting a growing tray, and a hood for providing services to the growing trays, wherein the hood provides at least irrigation. A load handling device operating on the track network for lifting and transporting growing trays includes a tray support pad located on the upper surface of the load handling device.

A block storage element which is used for the propagation of vegetable or fungal biomass and is stackable. To enhance functionality of the block storage element, the block storage element includes a fluid reservoir with an overflow mechanism.

A plant hanger assembly having multiple level plant trays, useful for growing plants in an upright configuration is provided for use with a trolley conveyor. A plurality of plant trays of selected size and shape are provided spaced apart along a vertical axis. A vertical support shaft has an upper end and a lower end. The plant trays may be circular in shape, with sloping sidewalls. The sloping sidewalls may be angled out sufficiently that the plant trays can be stacked in a nested configuration for storage. The plant trays include a base having grooved channels for transfer of water on the obverse side, and reinforcing ribs for strength, on the reverse side. Apertures between the obverse side and the reverse side allow excess water in an upper plant tray to drain downward into a plant tray therebelow. Shaft couplers are provided, with attachment rings or pins, to securely join the plant trays to the vertical support shaft. The plant hangers are adapted for attachment to and use with a trolley conveyor in a plant factory.

A hydroponic growing system is presented. The system can include multiple growing trays in a vertical arrangement, where a pump supplies the top-most tray and each lower tray is supplied by the overlying tray, and where the plumbing elements for supply and drainage are arranged to one side of the system. The system includes variations to support different crop types within the same system, including removable growing structures for root vegetable, microgreens and supports for vining crops. The system can monitor and adjust the nutrients and other features of the systems water profile to concurrently group multiple crops in differing developing stages.

Embodiments of the invention provides an enhanced self-draining crop growing tray/flood table where smaller growing trays can be located for automated watering systems. The self-draining crop growing tray .flood table of the present invention allows enhanced self-draining on a level table with inclined slopes. The enhanced self-draining hydroponic flood table comprises an inlet and an outlet formed. This type of table requires cleaning at frequent intervals and the growing trays inside the flood tray/growing table will all receive the same depth of water or a water solubilized nutrient solution.

A green roof planter module includes a planter including a bottom wall and a plurality of side walls that cooperate with one another to define an interior space configured to receive an aggregate and plant matter therein, the bottom wall including at least one aperture extending therethrough, a basin including a bottom wall and a plurality of side walls, wherein the bottom wall of the basin and the side walls of the basin cooperate to define a fluid retention space, wherein the planter is supported above the basin, and a fluid wicking member providing fluid communication from the fluid retention space of the basin to the at least one aperture of the bottom wall of the planter, such that the fluid wicking member is configured to transfer fluid from the fluid retention space of the basin to the aggregate and plant matter located with the interior space of the planter.

A floating panel for cultivation of plants, including through-holes at a top side, each receiving a substrate and a plant extending through the panel from a first plane at the top side to a second plane parallel to and spaced apart from the first plane, the panel further including an air chamber at a lower side, extending substantially below the second plane and allowing formation of air roots of plants supported in the substrate of the through-holes. The air chambers include a ceiling into which the through-holes debouch. A circumferential side wall delimits the chamber and a circumferential bottom edge of the circumferential side wall extends into the water when the panel floats. The panel also has spaced apart lower support surfaces supporting the substrate, and water-collecting surfaces transitioning into the lower support surfaces, guiding the flow of water from the water collecting surfaces along the lower support surfaces

A sub-irrigation bed includes a bottom, a side wall surrounding the bottom, a water inlet, and a water outlet. A plurality of support structures is arranged on an upper surface of the bottom, and tops of at least a part of the plurality of support structures lie in the same horizontal plane. By reducing the contact area between the cultivation container and the surface of the sub-irrigation bed to reduce local water accumulation caused by surface tension, the sub-irrigation bed and the cultivation apparatus using the sub-irrigation bed provided by the present invention solve the problem of water accumulation caused by incomplete drainage and the resulting problems that roots grow out of the cultivation container and seedlings grow irregularly, thereby achieving a good root control effect.