An aeroponic growing system includes a plurality of parallel vertical aeroponic growing apparatuses each having a closable loop articulated wall made up of vertical strips or panels that are pivotally attached side-by-side together with flexible joints. The motor-driven articulated wall moves on rails as an oblong-shaped carousel. The panels are provided with numerous plant-growing cups such that the growing plant extends outwardly out of the cup while the roots thereof are located inwardly of the wall. A spraying system delivers nutrients to the roots in darkness. On the external side, plants are exposed to controlled lighting provided by a programmable vertical LED system. Every growing step of the plants is optimized and supported by sensors and interactive software. The articulated wall is disengageable from its aeroponic growing apparatus to be displaced along a railing system between a grow room and other areas, and/or inverted for the roots to face outward.

A system for vertical hydroponic plant growing. The system, and associated apparatuses and methods, may include or use sprockets, a sprocket drive device that is connected to at least one sprocket among the sprockets, a first continuous loop chain that is mounted on the sprockets, a second continuous loop chain that is mounted on the sprockets, and trays. Each tray includes a first end and a second end that includes a drain hole. The trays are attached to the first continuous loop chain and to the second continuous loop chain. The system also includes a fluid-dispensing device that is configured to dispense a fluid into a tray that is moved by the chains to a position adjacent to the fluid-dispensing device. The chains are configured to longitudinally tilt a tray downward towards the drain hole while the tray is near the position adjacent to the fluid-dispensing device.

A temperature control system includes a shell including an enclosed area, one or more carts moving on a track within the enclosed area, an air supplier within the enclosed area, one or more vents connected to the air supplier and configured to output air within the enclosed area, and a controller. The controller includes one or more processors, one or more memory modules, and machine readable instructions stored in the one or more memory modules that, when executed by the one or more processors, cause the controller to: identify a plant on the one or more carts, determine a temperature recipe for the identified plant, and control a temperature of the air output from the one or more vents based on the temperature recipe for the identified plant.

Embodiments disclosed herein generally relate to systems and methods for emptying and/or cleaning a tray within in an assembly line grow pod. In one embodiment, a sanitizer component for cleaning a tray coupled to a cart in an assembly line grow pod is disclosed. The sanitizer component is coupled to a track such that the cart and the tray are received in the sanitizer component via the track. The sanitizer component comprises a first actuator arm positioned underneath the track and extendable through an opening in the track and an aperture at a bottom end of the cart to contact the tray such that the tray rotates in a first direction. The sanitizer component further includes an actuator motor coupled to the first actuator arm for extending the first actuator arm and a controller. The controller is communicatively connected to the actuator motor in the sanitizer component.

Exemplary embodiments are directed to an improvement of an aeroponic system including a growth chamber and cloth support elements. The improvement generally includes a cloth supported by the cloth support elements. The cloth advantageously satisfies a wicking height parameter and an absorbance parameter so as to deliver advantageous aeroponic performance. The wicking height parameter is a measurement of an ability of the cloth or fabric to absorb moisture. The absorbance parameter is a measurement of moisture the cloth or fabric retains. Exemplary methods of aeroponic farming in an aeroponic system are also provided.

A farming method may be shown and described. In an exemplary embodiment, plants may begin in a germination phase. Next, plants are brought to a nursery for a period of time before optionally being transplanted to one or more subsequent nurseries. Finally, plants are transplanted to a greenhouse where they may grow until they are ready for harvest. In an exemplary embodiment, the nursery phases may be vertical farms while the greenhouse phase may be a traditional, hydroponic, or other type of farm which may receive sunlight. AI may be implemented to optimize environmental conditions and robotics may be used to harvest the plants. Plants may be indexed to efficiently expedite plant growth and optimize the time and plant density/spacing in each phase.

A closed loop system for growing vegetation is provided. The closed loop system includes at least a first transport conveyor and a second transport conveyor. Each of the first and second transport conveyors includes a front end opposite a rear end. The present invention further includes at least a first transfer conveyor. A lighting system is positioned to emit light towards the first transport conveyor and a second transport conveyor. The present invention further includes at least one terrace structure. The first transport conveyor transports at least one terrace structure from the front end to the rear end, the first transfer conveyor transfers the at least one terrace structure from rear end of the first transport conveyor to the front end of the second transport conveyor and the second transport conveyor transports the at least one terrace structure from the front end to the rear end.

A method is provided. In this method, a first tray positioned at a first end of a trough assembly at a selected tier is engaged. The first tray is then lifted and removed. A second tray is then engaged and moved vertically to the selected tiers. It is placed in the trough assembly at a second end. Other trayswhich are positioned within the trough assembly between the first and second ends of the selected tierare moved toward the first end of the trough assembly.

The hydroponic growing system may include a gutter assembly configured to manage flow of a liquid solution to one or more components of the hydroponic growing system. Further, the hydroponic growing system may include at least one growing trough movably engaged to the gutter assembly and configured to hold one or more plants. Moreover, the hydroponic growing system may include an automation assembly movably engaged with the at least one growing trough and configured to move the at least one trough from a first position on the gutter assembly to a second position on the gutter assembly via one or more engagement devices.

A soilless culture facility includes a frame supporting a plurality of profile sections extending parallel to each other in a horizontal plane, from a transverse loading area to a transverse harvesting area, and a plurality of supports, each suitable for receiving a culture substrate. The plurality of supports are longitudinally movable in the longitudinal gap defined by two adjacent profile sections. The movable supports are moved by a motor means suitable for modifying the distance between two consecutive supports during travel in the gap. The plurality of profile sections have opaque and flexible longitudinal joining side band strips, the joining side band strips of two adjacent profile sections joining to close the gap defined by the adjacent profile sections. The movable supports have arcuate slots in the front and rear cross-sections of same, to either side of a longitudinal vertical plane, the two band strips joining at the lower edge.