A modular cell that may be used with other cells to form a matrix under a load bearing feature, the cell being a single piece molding that supports a compressive load placed thereon, the molding including a void space defined within: a skirt shaped support member defining a substantially planar surface with an opening therein; and at least one leg integral to and extending from the support member. The cell further includes at least one separate linking member that releasably links together multiple cells to form a matrix of cells. The cells may be linked together vertically and/or horizontally. The cell and matrix include greater load bearing capacity and rigidity through aligned legs to carry the weight as well as interlinking members that act to share the load among the various cells. The design also requires less material hence is cheaper to produce. The void space is also easily accessed hence allowing for easy access, filling and laying of utility lines where needed.

A self-watering portable greenhouse is disclosed having a tubular frame constructed of light-weight, water-tight tubular members which serves as a combined structural skeleton for external walls, a platform for plant containers, and a reservoir for liquid nutrients provided to plants in plant containers by self-watering through a wick connecting the reservoir and the plant containers.

A Watering device incorporating a light source (5) consisting of at least one inner chamber (2) attached to the exterior surface of the reservoir (1), said inner chamber (2) projecting or extending inwardly, said reservoir (1) having a mouth (3) which is able to be screwed or attached easily to commonly available drip feed devices or watering spikes (4), the inner chamber (2) wall at the exterior surface of the reservoir or extending outwardly from the reservoir exterior surface having a hole to accommodate fully or partially a light source or light sources (5) within the chambers), said light sources providing illumination of the reservoir (1), the plant, and surroundings or part thereof.

A system for cultivating plants comprising a plurality of cultivation shelves for cultivating plants, support frames structured to support the cultivation shelves so as to form one or more horizontal cultivation planes that develop along a first horizontal direction, an aeroponic feeding system, which is provided with nebulizing devices that are arranged at the cultivation shelves for spraying the liquid towards the cultivation shelves themselves, and a suction duct arranged at the nebulizing devices to suck up the nebulised liquid dispersed by the same.

Divided jardiniére suspension and/or watering systems for vandaceous orchids. In some embodiments, the system may comprise two receptacle pieces that may be coupled together to define a complete receptacle for a vandaceous orchid. Some embodiments may further comprise one or more watering elements, such as a watering manifold that may deliver water through one or more outtake ports through water delivery members that may extend from the watering manifold and be wrapped around the roots of the vandaceous orchid to deliver water and/or nutrients continuously via capillary action.

A system, comprising: a housing comprising an elongated hollow body configured to be at least partially embedded in a soil environment adjacent a plant at a desired depth; a swellable element dimensioned to be disposed within the housing, the swellable element being configured to swell when absorbing moisture; a resiliently-compressible flexible tube configured to provide water to the soil environment, the flexible tube is laced transversely through tube openings of the housing, the flexible tube is disposed adjacent to the swellable element inside the housing such that a swelling or displacement of the swellable element compresses the flexible tube, thereby limiting or preventing water flow therethrough; and a moisture transfer adapter configured to communicate moisture along its length from a desired location within the soil environment to the swellable element, as well as methods of using the system.

An irrigation apparatus for dispersing liquid through a plant growing medium is disclosed. The apparatus includes a container. The container has an outer wall with an inner surface, an open top, and a base portion configured to cover the plant growing medium. The base portion is configured with a plurality of holes for receiving liquid therethrough. The plurality of holes are configured as raised shields to block light and receive air, water, and nutrients. The container is configured with at least one center opening therethrough having an inner wall for receiving a plant. The center opening has at least one longitudinal opening extending therefrom to outer wall to allow placement of container on plant or to allow removal of container from plant. The container is configured with a plurality of stakes extending therefrom the base portion for providing stability for apparatus to be secured in plant growing medium.

The disclosed technology includes hydroponics systems and methods of efficient, configurable nutrient solution grow reservoirs that utilize shared components while creating more space in grow facilities. The hydroponics systems include vertical and horizontal rows or layouts of connected reservoirs that may include movable reservoirs to allow for better user access and reduce aisles, which allows space for more reservoirs in a grow facility. Multiple reservoirs may be connected to one another by irrigation tubing (e.g., as shown in in vertical layouts) or by pipes or irrigation tubing (e.g., as shown in horizontal layouts) and share various multiple system components, such as water pumps, water chillers, air pumps, float valves, and drain out systems. In some implementations, incorporation of the 4″ pipes in the horizontal layouts provides for efficient water circulation in a closed loop configuration throughout the disclosed hydroponic systems.

An irrigation device has a generally arc-shaped housing defining an opening through which a plant can grow when the device is placed on a ground face during use. The device further includes a plurality of stakes that can be fitted to the housing, wherein each stake can be rotated between a deployed state where the stake projects away from the housing in a position suitable for being placed into the ground and a non-deployed state where the stake is oriented sideways projecting into the opening.

The disclosed device accommodates and supports a pot plant, including a PLC communicating with an application on a mobile electronic apparatus. Sensors monitor the life cycle of the plant, and equipment provides the plant nourishment, hydration and light. Upon selecting the plant to be grown, the application creates an avatar of the plant. The application imports parameters of the selected plant from a database and communicates them to the PLC which, in turn, receives information from the sensors included in the device, operating the plant support apparatuses. Whenever the plant has a need, an “alert” appears in the application recreating an emotion of the plant as an emoticon and sends a push button. Pressing the button allows the PLC to issue commands for activating the apparatuses. The application further shows a dashboard providing updates regarding the current conditions of the plant and the residual availability of water and fertilizer.