The present invention relates to a flower pot of a double structure comprised of an inner container and an outer container. The present invention relates in particular to a flower pot of a double structure comprised of an inner container and an outer container, in which an inside container for planting a plant is designed to be transparent so that how the plant is rooted or watered is observable, and the interior of the pot is completely shielded from the light by preventing the light from entering from above and an outside container covering the pot is completely shielded from the light so that moss is suppressed from being grown on the inner surface of the pot and the plant can be grown in a most suitable environment without applying the light to the roots.

The pot is of a double structure comprised of the inner container 11 and the outer container 21 disposed outside the inner container 11. The inner container 11 is transparent and an upper part of the inner container is shielded from the light and the outer container 21 is colored in a completely lightproof color or formed of a completely lightproof material.

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, and various derivations, including 90 degree applications, obtuse angle applications, and acute angle applications. The angle elements fit together like puzzle pieces.

A robotic farming system includes a storage structure and a mobile robot. The storage structure has a set of parallel rails and is configured to accommodate crops in a plurality of horizontal rows arranged in a vertical direction. The robot includes a body, a mobility assembly to move the body along the set of parallel rails and a service effector for servicing the crops. The service effector may be provided on a plate that is extendable in a vertical direction relative to the body for servicing the crops accommodated within the storage structure. In one aspect, the service effector includes one or more nozzles for spraying fluid such as water, a gas or growth media on the crops. Alternatively, the service effector may be a manipulator and/or pruning tool.

A propagation tray for growing a plurality of plug plants in bounded transplantable growing media has two spaced apart aperture plates. The plug plants are held loosely in the apertures in a top plate while retained at the apertures in the bottom plate over air cells associated with and under the apertures in the bottom plate. The air cells provide a volume into which roots from the plug plant may grow, and the air cells have at least one port for drainage and/or ventilation and toward which roots are guided to be air pruned. The propagation tray maximizes air flow around the plug for air pruning of roots, while minimizing contact of the plug with the structures on the tray to reduce the formation of root defects.

Provided herein are various embodiments of plant containers that facilitate removal of plants from body structures of the containers. In some embodiments, the plant containers include selectively detachable members that are configured to at least partially detach from the body structures to partition segments of the body structures from one another. In other exemplary embodiments, the plant containers include closures are configured to reversibly open and close to partition segments of the body structures from one another.

An apparatus for growing plants is includes a body section having an upper orifice, a lower orifice, a back section, and at least one door. The upper orifice allows for planting of a plant while the at least one door allows for removal of the plant for transplanting. The upper orifice is smaller in cross-sectional area than the lower orifice allowing for plants to grow in their natural pattern giving the roots more room to grow in more soil from which to absorb nutrients making for a happier, healthier plant which will not need to be transplanted as often.

Growing systems may include a number of modular growing chambers with integrated support columns that eliminate the need for an external support frame and which provide a simple way to remove chambers from a stack for harvesting. Pins provided on the support columns ensure alignment and provide for easy removal of a lower chamber by first supporting the stack and slightly lowering it relative to the stack. The chambers may be provided with one or more removable access panels that provide access to the interior of the chambers for harvesting from the plant section inside. The chamber structure supports harvesting processes that permit harvesting of chambers in sequence by sequentially accessing the interior of successive chambers and harvesting a production portion from the plant section inside. Plant production can be made continuous and perpetual by sequentially harvesting from successive chambers and repeating the process after a plant section in a first chamber has regenerated another production portion. The chambers may include one or more plant guides for guiding growth of the plant sections within each chamber.

A tree box for growing and transporting a tree includes sidewalls and a removable bottom panel. The bottom panel can be removed prior to replanting the tree. In some embodiments portions of the tree box are formed of a plastic material.

The invention relates to a method for the cultivation of a number of plants (9), comprising providing a carrier with apertures for said plants (3, 13) and providing a water supply (8), wherein said carrier can be provided on said water supply in a floating manner and wherein a growth medium containing the roots of said plant or the precursor thereof are placed in an air-containing intermediate space (10) in the apertures in said carrier at such a distance from said water supply that said roots of said plant or the precursor thereof are situated at a vertical distance (a) from said water supply, wherein at least two horizontally opposing sides of an upper part of the growth medium are sideways supported along a height (h) by corresponding sides of a removable side support structure (18), removably arranged on top of the carrier.

Growing systems may include a number of modular growing chambers with integrated support columns that eliminate the need for an external support frame and which provide a simple way to remove chambers from a stack for harvesting. Pins provided on the support columns ensure alignment and provide for easy removal of a lower chamber by first supporting the stack and slightly lowering it relative to the stack. The chambers may be provided with one or more removable access panels that provide access to the interior of the chambers for harvesting from the plant section inside. The chamber structure supports harvesting processes that permit harvesting of chambers in sequence by sequentially accessing the interior of successive chambers and harvesting a production portion from the plant section inside. Plant production can be made continuous and perpetual by sequentially harvesting from successive chambers and repeating the process after a plant section in a first chamber has regenerated another production portion. The chambers may include one or more plant guides for guiding growth of the plant sections within each chamber.