An integrated modular and scalable fogponics crop growth system for cultivating a crop includes an upper growth chamber housing a leafy portion of a crop, a lower growth chamber housing a root portion of the crop, a nutrient tank and dispenser, and an environmental system. The nutrient dispenser is coupled to the nutrient tank holding a nutrient mixture for sustaining the crop. The dispenser atomizes the nutrient mixture into a nutrient fog using a booster pump and a high pressure pump capable of generating approximately 800 PSI to 1500 PSI. The high pressure pump is operatively coupled to a nozzle configured to dispense the atomized nutrient fog, substantially between 6 microns and 15 microns droplet size, into the lower growth chamber. Temperature and humidity are separately controlled in the leaf area.

The invention relates to a plant cultivation device (1) having: a housing (2), a receiving drum (3) which is rotatably mounted on the housing (2) and comprises multiple plant receiving containers (5) for plants (6), a drive (8) for rotating the receiving drum (3) within the housing (2), and a robot device (10) with a mounting (11) for a first working head (12) for supplying the plants (6) into the plant receiving containers (5), comprising a first linear guide (13) for moving the mounting (11) for the first working head (12) along a first axis and comprising a second linear guide (14) for moving the first linear guide (13) together with the mounting (11) for the first working head (12) along a second axis.

An aeroponic system for supporting efficient low-resource-usage plant growth comprises a housing comprising one or more openings and one or more root chambers; one or more sealing members configured to substantially conform to a stalk of a plant and to substantially isolate a canopy of the plant from the one or more root chambers; one or more root chamber sensors; one or more nutrient storage reservoirs for storage of plant nutrients; one or more air-assisted nozzles configured to introduce atomized nutrient solution into the one or more root chambers; a temperature control system configured to control a temperature of the one or more root chambers; and a control system configured to control the temperature control apparatus and the one or more air-assisted nozzles to maintain environmental parameters associated with the one or more root chambers within desired parameter ranges.

An integrated modular and scalable fogponics crop growth system for cultivating a crop includes an upper growth chamber housing a leafy portion of a crop, a lower growth chamber housing a root portion of the crop, a nutrient tank and dispenser, and an environmental system. The nutrient dispenser is coupled to the nutrient tank holding a nutrient mixture for sustaining the crop. The dispenser atomizes the nutrient mixture into a nutrient fog using a booster pump and a high pressure pump capable of generating approximately 800 PSI to 1500 PSI. The high pressure pump is operatively coupled to a nozzle configured to dispense the atomized nutrient fog, substantially between 6 microns and 15 microns droplet size, into the lower growth chamber. Temperature and humidity are separately controlled in the leaf area.

An indoor gardening appliance includes a grow module that is seated on a turntable that is rotatably mounted within a grow chamber and is rotated by a drive assembly. A position sensing assembly monitors an angular position using two proximity sensors, such as Hall-effect sensors, mounted below the sump, and the turntable includes a plurality of proximity indicators, such as magnets, positioned at various circumferential positions on the turntable. A controller is configured to initiate rotation of the turntable from a first angular position, determine that the turntable should have reached a second angular position, e.g., based on the operating duration or drive signal of the drive motor, and identify a drive assembly fault upon determining that the turntable has not reached the second angular position.

A plant treatment apparatus includes: a plant holding unit; an ultraviolet irradiation unit configured to irradiate a plant held by the plant holding unit with light comprising ultraviolet light in a wavelength range of no less than 270 nm and no more than 290 nm; and either (i) a plant immersion unit configured to immerse the plant held by the plant holding unit into a liquid that comprises water and is held by the plant immersion unit, or (ii) a liquid ejection unit that ejects the liquid towards the plant held by the plant holding unit.

A gardening appliance includes a liner positioned within a cabinet and defining a grow chamber, and a grow tower is positioned within the grow chamber and includes a module support frame rotatably mounted within the grow chamber and a grow module mounted to the module support frame to at least partially define a root chamber and defining an aperture for receiving a plant pod. One or more water collecting ribs extend from an inner surface of the grow module into the root chamber, the one or more water collecting ribs being oriented toward the aperture for directing collected condensation toward the aperture.

A seed pod assembly that has a pod defining an interior region and configured to support contents therein, a grow media positioned at least partially within the interior region, a plant seed positioned at least partially within the interior region, and a lid coupled to the pod to contain the plant seed within the interior region. The pod is sized to be positioned in an opening of a plant growing apparatus to allow water and nutrients to reach the plant seed or be released from within the pod.

Vertical farming/gardening systems and methods of using. The systems include a track defining a path in which a change in elevation occurs, buckets pivotally secured to the track to travel along the path, and a moving mechanism for moving the buckets along the path. A first bucket has a cavity containing either a growing medium capable of supporting plants growing within the cavity or a solar collector for dehydrating plants within the cavity. One or more service stations located along the path of the track perform actions on the growing medium or the plants within the cavity of the first bucket as the first bucket travels along the path. One or more sensors analyze the growing medium or plants within the cavity of the first bucket. A master control unit controls the system including travel of the buckets along the path of the track.

An indoor gardening appliance includes a cabinet defining a grow chamber within the cabinet. The gardening appliance further includes an artificial lighting system configured to illuminate one or more back portions of the grow chamber. The gardening appliance also includes a controller. The controller is configured for, and/or methods of operating the gardening appliance may include, operating the artificial lighting system according to a first profile for a first period of time and operating the artificial lighting system according to a second profile for a second period of time after the first period of time.