A growing system and/or plant support structure may include one or more feet supporting at least one or more uprights, on which a plurality of plants and/or grow boards for growing plants may be positioned. A nutrient delivery system may be positioned between opposing uprights to provide nutrient supply to a root zone of plants, which nutrient delivery system may be positioned adjacent each opposing upright in an interior chamber of the plant support structure. A light system may be positioned between two adjacent plant support structures such that it simultaneously provides light to the exterior surface of the two plant support structures.

A growing system is described where plants are grown in containers and the containers are stored in stacks. Above the stacks runs a grid network of tracks on which load handling devices run. The load handling devices take containers from the stacks and deposit them at alternative locations in the stacks or deposit them at stations where goods may be picked out. The containers may be provided with one or more of the following services: power, power control, heating, lighting, cooling, sensing means, data logging means, growing means, water and nutrients.

A lighting system includes a plurality of lighting fixtures coupled to a cooling pipe, each lighting fixture having an open sided pipe coupling portion and a lighting member connected to the coupling portion. The lighting member being thermally coupled to an inside portion of the pipe coupling portion. The lighting member having a light emanating away from the cooling pipe.

A plant cultivation apparatus of the present disclosure is proposed. In the plant cultivation apparatus, a portion where a bed cover is seated is maintained in a state of being positioned in a cultivation room together with the bed cover. In addition, the present disclosure proposes that other portions excluding the portion where the bed cover is seated are configured to be ejected from the cultivation room as needed. Therefore, the bed is washed without separation of the pod.

A plant cultivation apparatus of the present disclosure is proposed. In the plant cultivation apparatus, a machine chamber is configured to be open forward of the cabinet so that indoor air is suctioned and discharged therethrough. Accordingly, even when the plant cultivation apparatus is provided in a specific place in a built-in method, air circulation is smoothly performed.

A hydroponics apparatus includes a housing; two or more channels provided vertically on one side of the housing to be spaced apart from each other; brackets coupled to the channels; and cultivation modules seated on the brackets, wherein a plurality of cultivation modules is fitted and coupled to each other to have an extended form and water channels are formed to communicate with each other, the cultivation modules in the extended form are coupled to each channel and seated through a plurality of brackets disposed in a horizontal direction, and the plurality of brackets are coupled to the channels so that heights are gradually increased or decreased from one-side bracket in the horizontal direction to the other bracket in the horizontal direction to form an inclination of the water channel.

A plant grower includes a base, an upper cover having a surface parallel to an upper surface of the base, the upper cover being disposed above the base so as to be spaced apart from the upper surface of the base, a plurality of growing panels disposed along the circumference of the upper surface of the base, the plurality of growing panels being rotatably disposed at the base and the upper cover, and a lighting bar extending vertically upwards from the center of the upper surface of the base to the upper cover, the lighting bar emitting light in a direction in which the plurality of growing panels is disposed, and a plurality of growing holders, into each of which a plant is inserted, disposed at one surface of each of the plurality of growing panels.

A compact conditioning system for controlling a volume, comprises: (a) at least one light source, said light source being coupled with a replaceable focusing lens; (b) at least one fan; (c) at least one temperature sensor; (d) control circuitry adapted to receive inputs from said sensor(s) and/or from a user, and to operate said light source(s) and/or said fan(s) as a result thereof; and (e) a housing suitable to house said light source, fan and control circuitry and adapted to be positioned at the top of a structural element defining a closed space.

An apparatus for cultivating plants may include a cabinet having a cultivation space; a door that opens and closes the cultivation space; at least one bed disposed in the cultivation space and on which plants are cultivated; at least one light assembly that radiates light for photosynthesis toward the at least one bed; a water tank that stores water to be supplied to the at least one bed; a machine compartment separated from the cultivation space at a lower portion in the cabinet, that communicates with an outside of the apparatus, and that accommodates a compressor and a condenser forming a cooling cycle for controlling a temperature of the cultivation space; an air duct that connects the machine compartment and the cultivation space and guides air in the machine compartment to the cultivation space; and a return duct that connects the cultivation space and the machine compartment and guides air in the cultivation space to the machine compartment.

Various examples of methods and systems are provided for increasing productivity of one or more photosynthetic cultures via self-powered energy output systems. In one example, a system includes a waterproof casing and an energy output module enclosed within the waterproof casing. The waterproof casing is configured to be neutrally buoyant in an enclosure comprising the one or more photosynthetic cultures. In another example, a method includes placing a self-powered energy output system within an enclosure, the self-powered energy output system being neutrally buoyant within the enclosure. The method further includes causing turbulence within the enclosure, and the self-powered energy output system harvests energy to power the self-powered energy output system via the turbulence within the enclosure.