The present disclosure provides an advantageous pan jig for installing a pan relative to a frame. The disclosed pan jig semi-permanently engages the pan relative to a frame. Specifically, the disclosed apparatus and method of use advantageously facilitates formation and mounting of a drip pan for use with a system that facilitates aeroponic growing. The disclosed aeroponic growing system may include a plurality of drip pans.

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 storage system is disclosed where goods can be stored in containers and the containers are stored in stacks. Above the stacks runs a grid network of rails (e.g., tracks) on which load handling devices can run. To take containers from the stacks and deposit then at alternative locations in the stacks or deposit then at stations where goods may be picked. The framework may be provided with one or more of the following exemplary services: power, power control, heating, lighting, cooling, sensors, and data logging devices. The provision of these services within the framework rather than across the system as a whole, can allow for flexibility in storage whilst reducing cost and inefficiency.

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.

A tower catch mechanism that facilitates loading of vertical grow towers in a vertical farming structure having associated conveyance mechanisms for moving the vertical grow towers through a controlled environment, while being exposed to controlled conditions, such as lighting, airflow, humidity and nutritional support. The present disclosure describes a load conveyance mechanism that transfers grow towers to a loading position where grow towers are loaded onto a select grow line. Each grow line may include a grow tower conveyance system that moves vertically-oriented grow towers to select positions along a grow line. The system may include a tower catch mechanism that registers grow towers in position at the loading position for insertion into a select grow line. In some implementations, the tower catch mechanism can be integrated into other structures of the vertical farming system, such as a gutter basin corresponding to a select grow line.

A storage racking system for plant products can be capable of automated rotation and curing of dried cannabis and hemp flowers in sealed containers, which can maintain relative humidity along with a UV light and oxygen deficient environment to reduce degradation. The storage containers can be positioned horizontally to maintain a connection to the inert gas connection and allow for daily rotation in either direction. Each storage container can have a lid and a humidity pack. The lid can have a pressure relief valve that can exchange the gaseous atmosphere from the storage container with an inert gas through a check valve connection. The humidity pack can maintain the relative humidity in the storage container at about 58% to 62% during the curing and storage stages.

A storage racking system for plant products can be capable of automated rotation and curing of dried cannabis and hemp flowers in sealed containers, which can maintain relative humidity along with a UV light and oxygen deficient environment to reduce degradation. The storage containers can be positioned horizontally to maintain a connection to the inert gas connection and allow for daily rotation in either direction. Each storage container can have a lid and a humidity pack. The lid can have a pressure relief valve that can exchange the gaseous atmosphere from the storage container with an inert gas through a check valve connection. The humidity pack can maintain the relative humidity in the storage container at about 58% to 62% during the curing and storage stages.

An automatic and modular system for handling trays (32) used for containing plants or the like to be grown through hydroponic, or aeroponic, or aquaponic farming, comprises a first module (30) with a quadrangular plan and a vertical arrangement delimited by respective vertical supports (31), said first module (30) comprising two lateral zones, each of which includes a plurality of substantially horizontal and overlapping supporting seats or guides (37, 37′) for trays (32), and a central zone in which a vertical tray transfer device (33) operates, slidably along a vertical axis (Z) arranged on a movement means activated by motorization assemblies (34) able to translate said vertical transfer device (33) from a lowered position to a raised position for bringing itself to each tray (32) and vice versa, said vertical transfer device (33) being provided with a resting shelf (33′) for a tray (32) and with a first means adapted to translate along a first horizontal axis (Y) said tray from and towards a respective seat provided inside one of said lateral zones. Said first module (30) further comprises a second means (36) arranged in said central zone in which said elevator device (33) operates, adapted to take in charge a tray (32) when the latter is located on the shelf (33′) of said elevator device (33) and to displace said tray (32) along a second axis (X) horizontal and orthogonal to said first horizontal axis (Y) for performing the direct transfer of said tray (32) towards a further shelf (33′) of a further vertical transfer device (33) of a second module (30) arranged adjacent and connected to said first module.

An automatic and modular system for handling trays (32) used for containing plants or the like to be grown through hydroponic, or aeroponic, or aquaponic farming, comprises a first module (30) with a quadrangular plan and a vertical arrangement delimited by respective vertical supports (31), said first module (30) comprising two lateral zones, each of which includes a plurality of substantially horizontal and overlapping supporting seats or guides (37, 37′) for trays (32), and a central zone in which a vertical tray transfer device (33) operates, slidably along a vertical axis (Z) arranged on a movement means activated by motorization assemblies (34) able to translate said vertical transfer device (33) from a lowered position to a raised position for bringing itself to each tray (32) and vice versa, said vertical transfer device (33) being provided with a resting shelf (33′) for a tray (32) and with a first means adapted to translate along a first horizontal axis (Y) said tray from and towards a respective seat provided inside one of said lateral zones. Said first module (30) further comprises a second means (36) arranged in said central zone in which said elevator device (33) operates, adapted to take in charge a tray (32) when the latter is located on the shelf (33′) of said elevator device (33) and to displace said tray (32) along a second axis (X) horizontal and orthogonal to said first horizontal axis (Y) for performing the direct transfer of said tray (32) towards a further shelf (33′) of a further vertical transfer device (33) of a second module (30) arranged adjacent and connected to said first module.

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 light, at least one liquid conduit, and at least one gas conduit. The system may include at least one robot disposed on a top side of the frame and movably supported by the frame. The at least one robot may include at least one tool configured to manipulate the plurality of vertical plant growth structures. The system may include a control system including at least one processor configured to automatically control illumination by the at least one light, liquid flow through the at least one liquid conduit, gas flow through the at least one gas conduit, and operation of the at least one robot.