A Tray and Trellis System includes vertical posts or legs, longitudinal members, and cross members. Combs include tines fixed at one end to longitudinal members on one side, and releasably engaged at their other end to other longitudinal members on the other side. Further combs include tines fixed to a cross member at one end, and releasably engaged to another cross member at the other end. There may be intermediate cross members having tines fixed to them and other tines releasably engaged to them. Fixation of the tines may be by clips, rings, welding, bonding, fastening, or by molding as a single piece. The releasably engaged ends of the tines may be engaged with snap-fit slot features in the longitudinal members, the cross members, or the clips or rings, or may be engaged with open grommets inserted into openings in the longitudinal members or cross members.

A hydroponic plant production apparatus comprising: a hollow grow tube with a slot formed in the front face of the grow tube, and a matrix media insert composed of two halves, where the media is insertable into the grow tube, allowing plants to be inserted and grown between the two halves of the matrix media insert in the grow tube is provided. Methods for use of a hollow grow tube with a slot formed in the front face of the grow tube, and a matrix media insert composed of two halves, where the media is insertable into the grow tube, allowing plants to be inserted and grown between the two halves of the matrix media insert in the grow tube are also provided.

There is provided an off-ground plant growing system providing an electronic monitoring system and also providing a thin layer of high porosity organic compost and providing the steps of adding a precise amount of vermicompost to the soil phase, immediately followed by addition of arbuscular mycorhizae, and followed by regular weekly addition of beneficial micro-organisms for plant development, including mycorhizae associated bacteria, plant growth promoting fungi, soil conditioning bacteria, purple non-sulphur bacteria and probiotic disease-preventing bacteria, in order to promote the creation of a well differentiated, dense and ramified root system and complete microrhizobiome in the compost phase, that can effectively assist the functions of plant roots for optimal precision greenhouse, green walling or homegrown crop production of all kinds, without the use of chemical pesticides or fungicides.

A system and related method for monitoring plant growth conditions is provided, comprising a plurality of detectors (7) and central detector data processing means (1103); each detector (7) being arranged to measure properties indicative of a temperature, a water content, and a nutrient content, of a plant growth substrate; each detector (7) being further arranged to transmit the measured property or properties over a communications link to the central detector data processing means (1103); the central detector data processing means (1103) being arranged to store predefined irrigation data, defining a relationship between plural values for temperature, water content, pH level and/or nutrient content of the plant growth substrate; and plural desired irrigation output values; process the measured properties from each detector (7) to determine calculated properties of the substrate; and provide an output indicative of a desired irrigation input for the growth substrate, based upon measured properties received from the detectors (7) and the predefined irrigation data. A portable detector communications device (1105) for communicating configuration data relating to the detectors (7) may be included in the system.

A modular hydroponic tower array fixture system for the growth of organisms such as plants and fungi on arrays of hydroponic towers, allowing for the insertion and removal of individual towers from the array, is provided. Methods for the production of organisms such as plants and fungi using a modular hydroponic tower array fixture system are also provided herein.

This invention is related to a new substrate (6) for soilless cultivation consisting of a three-dimensional reticular structure which is elastically compressible, with empty cells bounded by threads made of polymer or any other material which are chemically inert, hydro-phobic or weakly hydrophilic. For example, the substrate which consists of a lattice made of threads in polyethylene (6) compressed into a container (4) equipped with an irrigation system (3) and with a support (2) where the plants have been inserted (5). The system is a closed cycle wherein the stored solution (1) is recirculated.

Certain exemplary embodiments can provide a system comprising a plurality of trays, at least one retention layer configured to absorb at least a portion of water that falls upon the plurality of trays, and/or a drainage layer configured to allow the water to drain out of the at least one retention layer.

Provided are systems and methods for vertical farming that reduce the deployment cost, operational costs of human labor, and overall use of energy intensive processes, such as lighting, heating and cooling, and ventilation, while increasing crop quality and yield. This reduction is achieved through a hybrid system that alternates natural light, temperature, and ventilation sources with system-controlled lighting, temperature, and ventilation means. The system includes a germination module that allows seeds to germinal on a horizontal substrate, a growth module that provides optimal growth conditions to the germinated seed on the substrate in a vertical position, and a dosing module that controls the micronutrient mixture supplied to the growing plants.

A hybrid grass support structure (100, 200, 300, 400, 500, 600, 710) comprising a growth medium layer (102), a stone wool layer (104) positioned below the growth medium layer, and a plurality of synthetic grass fibers (106). The growth medium layer comprises a growth medium. The synthetic grass fibers are incorporated at least into the growth medium layer.

A hybrid grass support structure (100, 200, 300, 400, 500, 600, 710) comprising a growth medium layer (102), a stone wool layer (104) positioned below the growth medium layer, and a plurality of synthetic grass fibers (106). The growth medium layer comprises a growth medium. The synthetic grass fibers are incorporated at least into the growth medium layer.