A method and system for supporting containerized plants in an upright and stationary position and at customizable, uniform spacing therebetween. The system comprises a frame, pockets, stabilizers positioned within the pockets and spacers. The pockets, stabilizers and spacers provide both horizontal and vertical support to each containerized plant, holding it securely in place without stakes or cables. The pockets with stabilizers and the spacers may be arranged in various patterns to promote stability of the system and health of the containerized plants. An irrigation system may be coupled to the system for maintaining and nourishing plants. The length of the frame is greater than the width, thus creating a stable environment to combat winds and disruptive forces. Individual frames may be attached to form designated and defined uniform growing or display areas and provide greater stability.

The embodiments of the present invention relate to the cultivation-, packaging-, and shipping of plugs, containing a seed or seedling and a substrate. In particular, a holder (10) is contrived having one or multiple cavities (11) in which a plug can be placed, together with one or multiple removal slits (12). Furthermore, a packaging tray (30) is contrived, having engaging means (32) and a perforated foil, to be used in unison with a particular holder for shipping that particular holder to a retailer or a customer. The holder could be placeable in both a cultivation tray (80) and a packaging tray (30).

Panel for floating cultivation of plants on water, including parallel grooves at a top side extending longitudinally, adapted for receiving a substrate and a number of plants or precursors in the substrate, each groove extending through the panel from a first top plane to a second parallel plane. The panel includes air chambers at a lower side extending substantially below the second plane, each of the air chambers allowing therein formation of air roots of plants supported in the substrate of the grooves. At the second plane, each groove is spaced apart from the circumferential side wall of the air chamber it debouches in when projected onto a plane normal to the longitudinal direction, each of the grooves including at least two side support surfaces extending parallel to the groove and below the top side, the side support surfaces adapted for substantially completely supporting the substrate in the groove.

An aeroponics system is provided which includes a rack with multiple shelves thereon and with a tray accommodated on each shelf. Light modules are located above each shelf. Each tray has a hood with openings therein leading into a hollow chamber and above a base which includes spray heads therein. Water from a reservoir upon the rack is pumped to each of the spray heads to provide a spray within the hollow chambers. Plant cuttings are placed passing through the openings in the hood so that lower portions of the cuttings can receive the spray (and nutrients added into the reservoir) for propagation of the plant cuttings.

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.

The plant cultivation device which workability of cutting of the leaves of the plant at the base portion thereof from the root portion of the plants. The plant cultivation device includes a culture medium holding portion in a cylindrical shape, accommodating and holding a seedling culture medium, arranged in the through-holes of the fluid passage member and absorbing the culture fluid into the seedling culture medium and a leaf supporting portion formed in a cylindrical shape, arranged at an upper side of the culture medium holding portion and supporting the leaves from around the leaves which are cultivated from the seeds. The culture medium holding portion and the leaf supporting portion are formed such that a cutting tool, used for separation between the seedling culture medium and the leaves, can be insertable from outside into a bordering portion between the culture medium holding portion and the leaf supporting portion.

The present disclosure is directed to improved vertical farming using autonomous systems and methods for growing edible plants, using improved stacking and shelving units configured to allow for gravity-based irrigation, gravity-based loading and unloading, along with a system for autonomous rotation, incorporating novel plant-growing pallets, while being photographed and recorded by camera systems incorporating three dimensional/multispectral cameras, with the images and data recorded automatically sent to a database for processing and for gauging plant health, pest and/or disease issues, and plant life cycle. The present disclosure is also directed to novel harvesting methods, novel modular lighting, novel light intensity management systems, real time vision analysis that allows for the dynamic adjustment and optimization of the plant growing environment, and a novel rack structure system that allows for simplified building and enlarging of vertical farming rack systems.

A plant-growing tray 102 comprises an array of cells 108 for containing stabilised media for propagating plants. The tray comprises a tray top 110, and each cell comprises a base 116 and an inclined side wall 114 extending from the base to the tray top. Each cell is configured to receive a stabilised medium, and comprises a plurality of projections 123, positioned around the side wall and facing into the cell, and a plurality of openings 125 defined in the side wall below the projections. The projections 123 are configured in use to support an upper portion of the stabilised medium. In a further aspect, a plant-growing tray for containing stabilised media for propagating plants is configurable in a nesting configuration with a similar tray, and comprises: a tray base configured to support a base portion of a stabilised medium; a support member, configured to support an upper portion of the stabilised medium; and an inclined tray wall connecting the support member to the tray base.

A vegetation partition wire mesh, for use in the vicinity of shores, coasts or roads, includes an outer wire mesh formed by upwardly bending left and right ends of a planar wire mesh, first partition wire meshes formed by upwardly bending front and rear ends of the planar wire mesh, and inner barriers. The first partition wire meshes are fixed inside the outer wire mesh while forming outer walls at front and rear ends thereof. Outer wire mesh nonwoven fabric along the inner surface of the outer wire mesh covers the outer wire mesh. A first partitioning nonwoven fabric along inner surfaces of the upwardly bent portions of the first partition wire meshes covers the upwardly bent portions of the first partition wire meshes. A mixture of soil and seeds is spread at high pressure to fill the inside of the outer wire mesh divided into a plurality of spaces.

A liquid capture tray and conservation system for capturing agricultural liquids which would otherwise be wasted and could contaminate groundwater. The liquid capture tray has a tray body and a reservoir matrix across the tray body. The reservoir matrix has a plurality of adjacent interconnected concave liquid capture cups, each with a sidewall and bottom wall defining an upwardly disposed reservoir. The tray is positioned below the root zone of a plant growing area to capture liquids that pass through the root zone into the reservoirs of the cups. Apertures in the tray body allow excess liquids to drain from the tray. A connecting mechanism can be utilized to connect two trays together. Cut-outs in the sidewalls of the cups allow liquid to move from one cup to another to disperse liquid across the reservoir matrix. The system includes a growing area, root zone, liquid and liquid capture tray.