An embodiment of the novel and inventive vertical hydroponic system comprises a double-sided system, each side having two sets of double-door tile panels. Each door is mounted on hinges attached at either the right or left sides of an external support frame with the doors opening out from the middle. Each door in this embodiment may support a 6×4 array of novel and inventive tiles, each tile arranged with two columns of 3 pot supports, each such tile capable of supporting 6 grow pots, for a total of 144 grow pots per door. In this embodiment all four doors can support up to 576 grow pots. However, an infinite number of tile variations are possible with the 2×3 array being just one. The doors can be opened during the growth cycle without disconnecting or interrupting the irrigation components which allows for fast and easy harvesting and maintenance. A submersible pump and its control electronics are mounted in the support framework so the system is self-contained. Scheduling software is provided via digital mobile app, which is downloadable from common app sources. The hydroponic system is interconnectible to the internet for remote maintenance and monitoring.

Certain exemplary embodiments can provide a system, machine, device, and/or manufacture adapted for and/or resulting from, and/or a method configured for, activities that can comprise and/or relate to, installing a support system for a green wall, the support system comprising a plurality of trays that are configured to interface with a securement system.

A body through which a medium can flow, in particular a body through which a fluid and/or gas can flow, with at least one exterior, wherein the body through which a medium can flow is self-supporting or includes at least one supporting body that provides mechanical stability, as well as a greenery system with at least one greenery element for installation on a surface, including at least one such body through which a medium can flow, in particular a body through which a fluid and/or gas can flow.

This is a roof drainage gutter system that is utilized as a hydroponic growth conduit, where the plant media growth extends over the roof providing shade and a form of insulation for the building. The system serves as a form of green roofing that does not require a soil medium to grow the plants and therefore does not require the additional structural components or costs. Existing roofs can easily be modified to accommodate this proposed system. The roof drainage system functions much like traditional gutter systems except for a designed volume of water is retained to provide a growth medium for the plants root systems. The gutters contain all the growth support mechanisms typically included in a traditional hydroponics system.

A device for growing plants is provided. The device has a panel assembly on which a one or a plurality of nutrient flow channels is supported to provide nutrient flow passages from an inlet at an upper region to an outlet at a lower region of the support panel. A plurality of grow pockets is supported on an opposite side face of the support panel, the grow pockets in alignment with the nutrient flow channels. Each grow pocket has a plant access opening. A fluid aperture in the support panel is disposed at a lower region of each grow pocket for fluid communication between an interior of the grow pocket and the aligned nutrient flow passage.

A flowerpot assembly is provided a support including a plurality of equally spaced openings from top to bottom; and a plurality of flowerpots each disposed on the opening and including a container and a conduit wherein the container includes a storing section for anchoring a plant and a water distribution device on a bottom of the storing section, the water distribution device including a coupling, a wall, an inlet, and an overflow exit; wherein a bottom of the conduit is connected to the water distribution device; wherein the inlet communicates the conduit with the storing section; wherein the wall is around the coupling; and wherein the overflow exit is between the water distribution device and the wall and extends out of the container.

A seed and/or plant system contains a strand-shaped seed and/or plant carrier suspended on a mounting. The seed and/or plant carrier contains several seed and/or plant locations with seeds and/or plants arranged spaced apart from each other in its longitudinal extension. The seeds and/or the plants are supplied with a liquid via a supply tube. In order for the seed and/or plant locations in the seed and/or plant system to be provided at a distance from one another definable by the manufacturer of the seed and/or plant system in a simple manner, a sleeve is provided on each of the seed and/or plant locations, from which a substrate with the seed and/or the plant is received or receivable and/or which at least partially forms a substrate for the seed and/or the plant, wherein the sleeve is formed from the or around the seed and/or plant carrier.

A supply and/or cooling system contains a supply tube or a supply channel for receiving a liquid and/or a gas, which is coupled to a liquid supply device and/or a gas supply and/or gas suction system and has at least one liquid and/or gas discharge opening in a tube, and a channel base or casing region. A strand-shaped ingredient carrier and/or cooling strand is suspended on the supply tube or the supply channel and/or the supply tube or supply channel coupled to the gas supply and/or a gas suction system is suspended below the at least one ingredient carrier and/or cooling strand. The ingredient carrier contains and/or carries at least one ingredient and the ingredient carrier and/or cooling strand can be supplied with the liquid and/or the gas via the liquid and/or gas discharge opening. The supply tube or the supply channel is vertically moveable.

Systems and methods for providing and operating a modular garden are provided. Modular gardens of the present technology may be attached to an indoor or outdoor wall. Modular gardens of the present technology include modular planters having at least one panel, a watering system, and a garden computing system that monitors plant conditions, automatically waters plants in the modular garden, and may communicate with a user personal computing device.

A hydroponic system (1) is provided with a light-collecting apparatus (3) having a pair of reflecting plates (31a) that are vertically arranged in parallel with a culture surface (23) of a culture panel (21) of a hydroponic unit (2). During a process in which natural light taken from a light-collecting opening (30) propagates while repeatedly reflected by opposing reflecting surfaces of a reflecting plates (31a), by allowing seedlings p that are transplanted into the culture panel (21) to be irradiated with the light through a light-emitting hole (32) bored in the reflecting plate (31a), a culture object can be grown efficiently at a low cost by taking natural light from the outside.