An air purifier apparatus, comprising: a housing comprising an air intake opening to an external environment outside the housing; a plant pot disposed downstream of the air intake, configured to hold soil, and being perforated so as to enable contact between at least some air outside the plant pot and at least some of the soil inside the plant pot; an air purification filter disposed downstream of the plant pot; a fan disposed downstream of the air purification filter; an air outlet disposed downstream of the fan and located in a first compartment of the housing; a dehumidifier disposed in a second compartment of the housing separate from the first compartment and configured to extract water from air interacting with the dehumidifier, the second compartment having an air exchange perforation opening to the external environment; a watering system, configured to circulate water located inside the housing to the plant pot.

An air purifier apparatus, comprising: a housing comprising an air intake opening to an external environment outside the housing; a plant pot disposed downstream of the air intake, configured to hold soil, and being perforated so as to enable contact between at least some air outside the plant pot and at least some of the soil inside the plant pot; an air purification filter disposed downstream of the plant pot; a fan disposed downstream of the air purification filter; an air outlet disposed downstream of the fan and located in a first compartment of the housing; a dehumidifier disposed in a second compartment of the housing separate from the first compartment and configured to extract water from air interacting with the dehumidifier, the second compartment having an air exchange perforation opening to the external environment; a watering system, configured to circulate water located inside the housing to the plant pot.

System and methods for monitoring the growth of an aquatic plant culture and detecting real-time characteristics associated with the aquatic plant culture aquatic plants. The systems and methods may include a control unit configured to perform an analysis of at least one image of an aquatic plant culture. The analysis may include processing at least one collected image to determine at least one physical characteristic or state of an aquatic plant culture. Distribution systems and methods described may track and control the distribution of an aquatic plant culture based on information received from various sources. System and methods described may include a bioreactor having a plurality of vertically stacked modules designed to contain the aquatic plants and a liquid growth medium.

The disclosed technology includes hydroponics systems and methods of efficient, configurable nutrient solution grow reservoirs that utilize shared components while creating more space in grow facilities. The hydroponics systems include vertical and horizontal rows or layouts of connected reservoirs that may include movable reservoirs to allow for better user access and reduce aisles, which allows space for more reservoirs in a grow facility. Multiple reservoirs may be connected to one another by irrigation tubing (e.g., as shown in in vertical layouts) or by pipes or irrigation tubing (e.g., as shown in horizontal layouts) and share various multiple system components, such as water pumps, water chillers, air pumps, float valves, and drain out systems. In some implementations, incorporation of the 4″ pipes in the horizontal layouts provides for efficient water circulation in a closed loop configuration throughout the disclosed hydroponic systems.

A self-wicking plant growth receptacle is provided. The device includes a housing having a base opposite and upper side and a plurality of sidewalls extending therebetween. An upper opening is disposed through the upper side providing access to an interior volume dimensioned to removably receive a grow bag therein. A wick port is disposed through the base in fluid communication with the interior volume. A reservoir housing is securable to the base to define an assembled configuration. The reservoir housing includes a lower side and a perimeter sidewall defining a reservoir volume. A lip is disposed about a perimeter of the upper side, wherein the lip includes a plurality of apertures therethrough. A channel extends through the housing between an inlet on the upper side and an outlet on the base, wherein the channel is in fluid communication with the reservoir volume. A filter is removably secured within the channel.

An irrigation device for promoting deep root growth of a plant. The irrigation device may comprise: a tube and a hose, wherein the hose may have one or more slits that allow liquid to seep out if the water pressure in the hose is too high. The water pressure may get too high if the pores of the soaker hose become temporarily clogged, which may happen if a fertilizer solution is put into the irrigation system.

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.

A modular vertical plant cultivation wall system configured to produce minimal carbon footprint from fabrication through erection, to be built of sustainable material and to be installed rapidly by low skilled labor is provided. The modular vertical cultivation wall system includes at least two vertical posts, at least two planter shelves, at least two endcap walls, and at least one of: a pipe, a seed/plant root retaining matrix, and irrigation fluid. Further, a method of providing a modular vertical cultivation wall is provided.

A gardening appliance includes a liner positioned within a cabinet and defining a grow chamber, a grow tower rotatably mounted within the liner and defining a root chamber, a hydration system comprising a water supply tank for storing water, a supply conduit fluidly coupling the water supply tank to a discharge nozzle, a supply pump for selectively urging the water through the discharge nozzle and a water level sensor operably coupled to the water supply tank. A controller obtains a water level of the water in the water supply tank using the water level sensor, determines a conservative water supply schedule based at least in part on the water level, and operates the hydration system to provide the water in accordance with the conservative water supply schedule, the conservative water supply schedule providing the water at a slower average hydration rate relative to the standard water supply schedule.

A system for intelligent irrigation based on moisture-level data acquired from multiple locations. The system includes a processor of an irrigation server connected to a moisture-level sensor and to a water tank control unit over a network; a memory on which are stored machine-readable instructions that when executed by the processor, cause the processor to: acquire a moisture-level data from the moisture-level sensor at a plant location; determine a plant type based on the plant location associated with the moisture-level sensor; process the moisture-level data and the plant type to generate a feature vector; provide the a feature vector to an AI module for generation of an irrigation instruction output; and responsive to the irrigation instruction output received from the AI module, send a command signal to the water tank control unit to turn on a pump for irrigation of the plant location.