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.

One variation of a method for automatically redistributing plants throughout an agricultural facility includes, at a mobile robotic system: delivering a first moduledefining a first array of plant slots at a first density and loaded with a first set of plants in approximately a second growth stagefrom a grow area within a facility to a transfer station within the facility; delivering a second modulelocated within the facility and defining a second array of plant slots at a second density less than the first densityto the transfer station; and following transfer of a first subset of plants from the first array of plant slots in the first module into the second array of plant slots in the second module at the transfer station, delivering the second module to the grow area in the facility.

A method is disclosed that includes growing romaine lettuce in a greenhouse using a hydroponic technique and using purified water. The romaine lettuce has a heart and outer leaves. The heart is separated from the outer leaves of the romaine lettuce. The outer leaves are packaged in a first container and the heart is packaged in a second container. The first container and the second container are separate from one another. The first container and the second container are transferred to a storage device of approximately 32 to 41 degrees F. The packaging the outer leaves and the heart, and the transferring the first container and the second container, occur in an environment of less than or equal to 41 degrees F. The method occurs in a single, environmentally-controlled facility.

The present invention relates to a floating carrier and a cultivation system for crops such as lettuce in floating carriers on water. The cultivation system comprises a basin comprising at least one elongate production pond with an infeed end on a short side and an opposite outfeed end and with water therein, a number of elongate floating carriers, the length of which corresponds to the width of the elongate production pond and which move in an orientation transversely of a longitudinal direction of the elongate production pond through the production pond from the infeed end to the outfeed end at a rate corresponding to bringing the crops to full growth, which floating carriers each comprise a number of growth locations for the crops where holders for the crops or roots of the crops extend into the water, and a transport system comprising a lifting mechanism and conveyors.

A method for tracking seeds in an assembly line grow pod having a plurality of carts is provided. A target seed is deposited in a selected cell which is a part of a selected tray located in a selected cart travelling on an assembly line grow pod. A position of the target seed is tracked in the selected cell by determining the position of the target seed in the selected cart and determining a position of the selected cart in the assembly line grow pod. Sustenance is provided to the target seed including the selected cell. A growth factor of the target seed is determined in the selected cell. Upon determination that the growth factor of the target seed in the selected cell is below a predetermined threshold, supply of the sustenance provided to the selected cell is adjusted.

Devices, systems, and methods for providing and operating a valve control module and pressure valves in an assembly line grow pod are provided herein. Some embodiments include an assembly line grow pod having a plurality of fluid lines fluidly coupled between a fluid source and a fluid destination within the assembly line grow pod, a plurality of pressure valves, each coupled to a fluid line such that fluid pressure in the fluid lines is selectively controlled by the pressure valves, and a master controller communicatively coupled to the pressure valves. The master controller is programmed to receive information relating to fluid delivery within the assembly line grow pod, determine one or more pressure valves to direct the fluid, determine pressure valve parameters for each of the pressure valves that achieve the fluid pressurization, and transmit one or more control signals to the pressure valves for pressurizing the fluid within the assembly line grow pod.

Devices, systems, and methods for providing a predetermined amount of fluid in an assembly line grow pod are provided. Some embodiments include an assembly line grow pod having a fluid source and a fluid distribution manifold. The fluid distribution manifold includes a fluid inlet, a plurality of fluid outlets, a plurality of valves coupled within the fluid outlets and movable between an open position and a closed position, a plurality of biasing assemblies coupled to the of valves to bias the valves in the closed position, and a plurality of tension rings coupled to the biasing assemblies to adjust an amount of biasing force applied by the biasing assemblies. Fluid from the fluid source having a fluid pressure that exceeds the biasing force causes the valves to move to the open position such that a specific amount of the fluid is ejected from the fluid outlets.

Devices, systems, and methods for providing and operating a valve control module and valves in an assembly line grow pod are provided herein. Some embodiments include an assembly line grow pod having a plurality of fluid lines fluidly coupled between a fluid source and a fluid destination within the assembly line grow pod, a plurality of valves, each coupled to a fluid line such that fluid movement through the fluid lines is selectively controlled by the valves, and a master controller communicatively coupled to the valves. The master controller is programmed to receive information relating to fluid delivery within the assembly line grow pod, determine one or more valves to direct the fluid, determine valve parameters for each of the valves that achieve the fluid direction, and transmit one or more control signals to the valves for directing the fluid within the assembly line grow pod.

A system for bypassing harvesting in an assembly line grow pod is provided. The system includes a track, a cart configured to move on the track, the cart including an upper plate configured to support a plant, one or more sensors 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 receive information about the plant from the one or more sensors, determine whether the plant in the cart is ready to harvest based on the information; and transmit an instruction for bypassing harvesting the plant in the cart in response to determination that the plant in the cart is not ready to harvest.

Assembly line grow pods that include watering stations positioned to provide water plant material at predetermined days of growth and methods of supplying the same are disclosed. An assembly line grow pod includes a track extending a length between a seeder component and a harvester component, a plurality of watering stations arranged adjacent to the track at a plurality of locations along the length of the track between seeder and harvester components, and a cart supported on and movable along the track from the seeder component to the harvester component such that seeds that are placed by the seeder component within the cart grow into plant material that is harvested at the harvester component. Each one of the plurality of watering stations is positioned between the seeder and harvester components such that water is provided by the watering station to the cart at a predetermined growth metric.