Disclosed is a wall landscaping system for easy growth management with automatic watering and plant growth analysis, which creates a vertical garden on an interior or exterior wall of a structure, the system including: a main body (10) installed to cover the wall (W) to have a plant grown thereon; a watering part (20) disposed at an upper end of the main body (10) to supply water to the plant; a detector (30) disposed around the main body (10) to photograph the plant; and a controller (40) automatically checking and recording a growth state of the plant by analyzing an image photographed by the detector (30), and remotely notifying a manager according to the growth state of the plant, whereby it is possible to automatically supply water at a predetermined interval for each plant, and analyze the growth state of the plant and notify the same.

An indoor gardening appliance includes a liner defining a grow chamber and a grow tower mounted within the grow chamber for receiving a plurality of plant pods. A hydration assembly is positioned within a root chamber and includes a nozzle support frame mounted at a top of the root chamber, the nozzle support frame comprising a plurality of support arms, at least one of the plurality of support arms being off-axis relative to the central axis of the grow tower, an upper nozzle mounted to the nozzle support frame proximate a top of the root chamber, a lower nozzle mounted to the nozzle support frame proximate a bottom of the root chamber, and a water supply for supplying a flow of fluid to at least one of the upper nozzle or the lower nozzle.

Devices, systems, and methods for providing and operating a pump control module and one or more pumps in an assembly line grow pod are provided herein. Some embodiments include the assembly line grow pod having one or more pumps, a master controller with a plurality of bays and being communicatively coupled to the pumps, and a pump control module within one of the bays such that the pump control module is communicatively coupled to the master controller and the pumps. The pump control module is programmed to receive information regarding fluid within the assembly line grow pod, determine one or more control signals necessary to provide or pressurize the fluid, and provide the one or more control signals to the one or more pumps.

Systems and methods for operating a grow pod are provided herein. One embodiment of a system includes a cart that moves on a track of the grow pod, where the cart receives a seed for growing into a plant. The system may also include a human-machine interface (HMI) that is coupled to the grow pod and a pod computing device coupled to the HMI. The pod computing device stores logic that, when executed by the pod computing device, causes the system to receive a grow recipe for the seed in the cart, wherein the grow recipe includes actuation of at least one environmental affecter and provide a user option to alter functionality of the grow recipe. In some embodiments, the logic may also cause the system to receive a user selection of the user option and in response to receiving the user selection, alter functionality of the grow recipe.

Air dispersing member adapted for use buried in soil and comprising annular portions defining a hollow annular member comprising an air flow conduit, there being a plurality of holes communicating between the air flow conduit to a location exterior of the hollow annular member for aerating soil, the air dispensing member preferably being combined with an irrigation system for providing an optimal amount of water to a plant or seed, comprising an inner pot having a porous bottom portion and adapted for containing soil for hosting the plant or seed, an outer pot adapted for containing a certain water level, the inner pot and the outer pot together defining a partially enclosed space, an inlet water pipe, an outlet water pipe, and a wicking pad adapted to be in fluid communication between water in the bottom portion of the outer pot and the porous bottom portion of the inner pot.

This invention is a hydroponic appliance that allows users to grow sufficient yields of fresh produce with relatively little maintenance. The appliance incorporates multiple features required for hydroponic plant cultivation into a plug-and-play system with a feedback loop to manage optimal growing conditions, comprising a growing area, a processor, a mixing chamber, and, in embodiments, more than one reservoir. In aspects, the grow area is divided between two or more reservoirs allowing users to stratify their crops or plant different crop types simultaneously. The apparatus and associated method provide the overall system with increased versatility, including removing aspects of day-to-day maintenance. The system automatically regulates the environment in response to various sensor readings. This includes automatically regulating the temperature, humidity, carbon dioxide level, pH level, and/or nutrient concentration. Accordingly, the plants have more optimum conditions for growth. The system utilizes, for example, pre-seeded trays, a single mixing chamber, a processor, and a plurality of reservoirs.

A device for dispensing liquids, in particular irrigation water, comprises a liquid tank (1) of displaceable type with a cover (2) for closing said tank (1), an electric pump (7) inserted into the cover (2) for drawing the liquid from the tank (1) and delivering the liquid itself to irrigation pipes extending outwards, and an electronic control unit (13) for setting the liquid delivering times. The electronic control unit (13) comprises a movable selector (15) for programming the times and durations of the liquid deliveries, a start button (16) for starting the selected program, and a display (17) for viewing the state of the device as a function of the selected program. An external power source (33) is provided, with the possibility of using rechargeable cells (35), which are automatically rechargeable and which can be enabled in case of absence of external power supply.

A cultivation floor system has a floor on which plant containers are to be placed. The system includes a watertight basin and a water-permeable structure in the basin, which structure has a permeable top cloth which forms the top side of the floor on which plant containers are placed. The structure includes one or more water-retaining layers. A watering installation supplies water so that water is available for the plants in the plant containers. A perforated film is placed between the permeable top cloth on the one hand and the one or more water-retaining layers on the other hand, which perforated film is made of impermeable film material which is provided with distributed perforations in such a manner that the film reduces the free evaporation surface for water from the one or more water-retaining layers.

An automated plant cultivation system is provided having multi-tiered vertically arranged horizontal magazine structures each employing seed or plant capsules with a fluid circulation and illumination and communication network controlled by an on-board processor. Particularly, the system includes a magazine structure having seed/plant capsules within seed/plant reservoirs alternately arranged between at least one of a light source substantially concealed from direct viewing. A fluid channel extends across a long axis of the magazine structure, wherein the magazine structure is adapted for use of seed/plant capsules with nutrient composite plant growth cultivation, hydroponic plant growth cultivation, aeroponic plant growth cultivation methods or combinations thereof.

An indoor gardening appliance includes a liner defining a grow chamber and a grow tower mounted within the grow chamber for receiving a plurality of plant pods. A hydration assembly is positioned within a root chamber and includes a nozzle support frame mounted at a top of the root chamber, the nozzle support frame comprising a plurality of support arms, at least one of the plurality of support arms being off-axis relative to the central axis of the grow tower, an upper nozzle mounted to the nozzle support frame proximate a top of the root chamber, a lower nozzle mounted to the nozzle support frame proximate a bottom of the root chamber, and a water supply for supplying a flow of fluid to at least one of the upper nozzle or the lower nozzle.