The disclosed device includes a water storage container, an evaporation cover, a funnel, an indicator rod and a float. The water storage container has an evaporation cover. The evaporation cover is a gas permeable structure. A funnel is connected to the evaporation cover and an indication is provided in the leakage tube of the funnel. A rod. A float is connected to the lower end of the indicator rod and the float drives the indicator rod to indicate the water level in the water storage container. The method is as follows: the water storage container and the evaporation cover are buried in the soil of the plant root, and the water is filled into the water storage container through the funnel. The water in the water container naturally evaporates into the soil through the evaporation hood, which maintains the water in the soil to maintain the survival of the plant.

Disclosed a plant cultivation system including: a replaceable cultivation box including a housing, and identification information of the cultivation box, and an electronic device configured to acquire the identification information from the cultivation box, detect state information about an inside of the cultivation box or around the cultivation box using a sensor, and spray liquid into the cultivation box based on the identification information and the state information.

An irrigation management system monitors irrigation parameters, including progress of flood irrigation water admitted onto a farm field, water levels in ditches, basins or boxes, soil moisture, water usage and other important factors. In flood irrigation a series of small, inexpensive sensors detect the presence in each of the sensor locations in a field, and each sends a signal when water first reaches the sensor. In a preferred form the sensor communicates by long-range radio communication either directly with a hub or gateway, or by sending a transmission that is relayed from location to location and ultimately to the hub or gateway. All aspects of irrigation water need, availability, task completion, pipe and equipment status, and water usage are monitored and communicated to the farmer. The system allows efficient water management and reliable and responsible irrigation at all irrigated fields.

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.

A stain-proof gardening container having a cap brace including a plurality of grooves, each groove connects to a top edge of one of a corresponding vertically oriented left side panel member, right side panel member and back panel member, a front panel member including a handle, the front panel member attaches to the left side panel member, a floor panel including a well and a plurality of grooves, each groove connects to a bottom edge of one of a corresponding vertically oriented left side panel member, right side panel member and back panel member, a housing frame formed by the cap brace, left side panel member, right side panel member, back panel member, front panel member and floor panel, the housing frame including an interior cavity, a gardening collection receptacle for receiving and storing at least one gardening component, the gardening collection receptacle including an elastic headband located at its top region for installing the gardening collection receptacle in the interior cavity of the housing unit and a drainage aperture located at its bottom region for draining excess materials from the gardening collection receptacle and a drainage collection repository for receiving the excess materials drained from the gardening collection receptacle. The drainage collection repository including a handle for removing the drainage collection repository from the housing unit, and wherein the drainage collection repository is positioned within the well in the floor panel.

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.

An intelligent farming arrangement comprises a cultivation receptacles receiving a soil medium for cultivation of a plant. Each receptacle has a growth condition sensor for monitoring a condition of the soil medium in the receptacle. A leaching reservoir arranged below the receptacles receives leached nutrients from the receptacles gravity. A fluid redistribution arrangement having at least one fluid pump is arranged within the reservoir for redistributing such nutrients from the reservoir to the receptacles. A controller is in communication with each sensor and the fluid redistribution arrangement, the controller configured to operatively provide a GUI, via a communications network, to a user, the GUI having a prediction engine configured to predict plant growth in each receptacle by analysing the monitored soil condition, the GUI configured to display such predicted plant growth and monitored soil condition and to enable remote control of the fluid redistribution arrangement in real-time.

A wall mounted agricultural assembly includes a first planter and a second planter below the first planter, and a water supply arrangement that includes a fluid supply delivering fluid from a fluid supply to the first and second planters and a first valve configured to allow or prevent fluid flow to the planters, and a second valve configured to prevent or allow fluid to bypass the planters.

A fluid retention assembly includes a housing that may be positioned on a support surface. The housing is located proximate a downspout of a building. The housing has an upper section removably coupled to a bottom section of the housing. A lip is coupled to and extends outwardly from the outer wall of the bottom section. A spout extends through the housing to be directed into the downspout. The fluid enters the fluid opening, allowing the spout to capture the fluid. A first hose is fluidly coupled to the spout, directing the fluid into the housing. A pump is positioned within the bottom section of the housing. The pump is immersed in the fluid when the fluid is directed into the bottom section. A spigot is coupled to the housing. A second hose is fluidly coupled between the spigot the pump. The pump urges the fluid outwardly through the spigot. A power supply is electrically coupled to the pump.