A container, including a number of angle elements. Each angle element includes a) a horizontal puzzle member including a male knob at one end and a female lock at the other end; and, b) a vertical member including a vertically extending male adjunct at one end thereof and a vertically extending female adjunct at the other end thereof, the vertical member being integrally orthogonally connected to the horizontal puzzle member. The angle elements are configurable, i.e. can be assembled, to form a container by: engagement of the male knobs of the plurality of angle elements with female locks of adjacent angle elements; and, engagement of the vertically extending male adjuncts of the angle elements with female adjuncts of adjacent angle elements. The container may include corner angle elements and additional types of angle elements such as intermediate angle elements, curved angle applications, L-shaped angle elements, etc.

A system for suspending and self-balancing containers of crops includes first and second support rods and two cables tensioned between them. The two cables are connected to each other to form a closed-loop cable system. Support members for supporting the closed-loop cable system are coupled to the first and second support rods. Each support member includes a first arc-shaped surface. The closed-loop cable system is tensioned against the first arc-shaped surfaces. When the closed-loop cable system is under stress, it can facilitate the self-adjustment of the height of the cables by a relative sliding motion between the closed-loop cable system and the first arc-shaped surfaces.

A growing unit for biological hydrosynthesis, energy generation and storage and/or topsoil restoration, the growing unit comprising: a container configured for growing plants and containing a growth media located therein; a reservoir located in a lower portion of the container and associated with an outlet portion of the container, and a substantially vertical liquid inlet pipe associated with the reservoir, wherein the growth media comprises a mixture including a first catalyst, wherein the first catalyst stimulates formation of a humified soil and wherein the growth media is amended with an irrigation liquid which stimulates biological activity in the growth media and in and adjacent to the reservoir.

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.

An automatic vertical farming system may include a frame defining at least one growth area and configured to support a plurality of vertical plant growth structures within the at least one growth area. The system may include at least one robot disposed on a top side of the frame and movably supported by the frame. At least one robot may include at least one tool configured to manipulate the plurality of vertical plant growth structures. The system may include at least one infiltration chamber configured to contain at least one of the plurality of vertical plant growth structures and expose the vertical plant growth structure to an inoculant. The system may include a control system including at least one processor configured to automatically control operation of the at least one robot and the at least one infiltration chamber.

A conveyor system (4, 5) moves vertical poles (2) in an agricultural facility between a growing area (20) and a workstation (W). Each pole carries plant growing containers (3) at multiple levels (H1-H9). An irrigation reservoir (30) may be mounted atop each pole. Irrigation lines (31-33) from the reservoir may be individually metered (35) at each level to compensate for differing water pressure with height. Sensors (40) in the reservoir and at each level of the poles may provide a controller (36) with data input. The controller may impose different growing conditions in different areas of the facility, including vertically different grow areas (20A, 20B), and controls pole movements and locations selectively to provide a sequence of poles at the workstation ready to harvest on a demand schedule. The workstation may have multiple heights (W1, W2, W3) for tall poles that increase plant density per facility footprint.

A plant growing system comprising a growing panel and a porous air hose coupled to the growing panel. The growing panel includes a plurality of openings for receiving a plurality of plant receptacles. The plurality of openings are arranged in a plurality of parallel lines on the growing panel, and the porous air hose extends along the growing panel between at least two of the parallel lines.

The panel-modular layered wall system for shaping spatial structures is characterised by the fact that: the arrangement of horizontal layers configured by means of joined sideways panels of various shapes, filled with the substrate, whose surfaces are planted with plants according to the principle of bipolarity, preferably using transparent or opaque panels, which are mounted on cantilevers with a variable supporting angle, always forms the horizontal arrangement of panels, placed a maximum of three (when with plants and more when without) on the flat or bent frame of the module in the shape of a rhombus, a rectangle and a trapezium made of a closed profile with a rectangular cross-section, where the frames of modules joined together along the perimeter by means of couplers form the vertical load-bearing frame, sloping load-bearing frame, arched-barrel load-bearing frame, spherical load-bearing frame, cylindrical load-bearing frame and sloping cylindrical load-bearing frame, which, together with the use of silos filled with the substrate, joining individual panels and layers, forms self-supporting layered wall structures in six variants, which can be configured with each other.

A pollinator attraction pot includes a pot body made up of a top portion having an opening, a bottom portion, and a side wall connecting the top portion and the bottom portion, the bottom portion and side wall defining an interior which can be used to contain a growing plant, wherein the sidewall is made of a flexible fabric material suitable to serve as a plant pot. A pollinator attractor is positionable on or within the pot body. The pollinator attractor includes a material or substance that serves to attract a pollinator to the pollinator attraction pot.

A lighting system for a vertical garden includes at least one light ring including a central hub member configured to be removably mounted to the vertical garden, an outer ring member, and a plurality of spoke members extending radially between the central hub member and the outer ring member, a plurality of light sources supported in the outer ring member, and a drive circuit for the plurality of light sources, a power supply, and at least one power connector connected between the drive circuit and the power supply.