An aeroponic plant-growth system includes growth space and a control unit that may be assembled using factory made modules. The growth space includes layers at different heights, and each layer includes plant holders and misters positioned to apply a mist to roots of plants in the plant holders. The control unit employs a controller to execute a program that operates a liquid supply system to provide liquid flows to the misters in the layers. Each of the liquid flows may be regulated according to the height of the layers.

The disclosed device accommodates and supports a pot plant, including a PLC communicating with an application on a mobile electronic apparatus. Sensors monitor the life cycle of the plant, and equipment provides the plant nourishment, hydration and light. Upon selecting the plant to be grown, the application creates an avatar of the plant. The application imports parameters of the selected plant from a database and communicates them to the PLC which, in turn, receives information from the sensors included in the device, operating the plant support apparatuses. Whenever the plant has a need, an “alert” appears in the application recreating an emotion of the plant as an emoticon and sends a push button. Pressing the button allows the PLC to issue commands for activating the apparatuses. The application further shows a dashboard providing updates regarding the current conditions of the plant and the residual availability of water and fertilizer.

A system for vertical hydroponic plant growing. The system, and associated apparatuses and methods, may include or use sprockets, a sprocket drive device that is connected to at least one sprocket among the sprockets, a first continuous loop chain that is mounted on the sprockets, a second continuous loop chain that is mounted on the sprockets, and trays. Each tray includes a first end and a second end that includes a drain hole. The trays are attached to the first continuous loop chain and to the second continuous loop chain. The system also includes a fluid-dispensing device that is configured to dispense a fluid into a tray that is moved by the chains to a position adjacent to the fluid-dispensing device. The chains are configured to longitudinally tilt a tray downward towards the drain hole while the tray is near the position adjacent to the fluid-dispensing device.

A horticulture apparatus and method for planting, growing, and harvesting plants may include a platform having a width axis and a length axis, a gantry sized to straddle and move across at least one of the platform's width and length axes, and a controller. The gantry may comprise a frame, a motor mounted to the frame, a container bin operatively connected to the frame, and a modular tool operatively connected to the frame. The controller may engage the motor of the gantry to move the gantry across the platform, thereby providing the modular tool with access to different locations on the platform.

An indoor gardening appliance includes a liner defining a grow chamber and a grow module rotatably mounted within the grow chamber and defining a root chamber. A hydration system is fluidly coupled to the root chamber for selectively implementing a hydration cycle where the root chamber is charged with mist and an air circulation system selectively urges a flow of air through the root chamber to maintain a desired temperature. A controller is configured for stopping the flow of air during the hydration cycle, e.g., to minimize disruption of the hydration cycle. The stopping of the flow of air may be time-based, e.g., based on the start/end times of the hydration cycle, or may be based on moisture level, e.g., as measured by an optical sensor.

Automatic watering systems for hydrating a cut tree or the like from a reservoir of standing water are described herein. Automatic watering systems may include a water source comprising a tank and a supply-water reservoir within the tank. Water may be automatically delivered from the supply-water reservoir to a tree-receiving reservoir which may be associated with a tree stand. Water in the tree-receiving reservoir may be taken up by the tree to keep the tree branches green and supple. A controller detects water levels in the supply-water reservoir and tree-receiving reservoir to control operation of a pump which pumps water to the tree-receiving reservoir for continuous tree hydration. The tank and other components of the system can be made to have the decorative appearance of a gift package to enhance the appearance of the tree and surrounding decor.

An assembly line grow pod includes 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 container garden irrigation assembly includes a reservoir for containing a fluid. A pump is positioned inside the reservoir thereby facilitating the pump to be submerged in the fluid. A control unit provided that is in electrical communication with the pump. The control unit turns the pump on and off at predetermined times of day. A pair of irrigation units is each in fluid communication with the pump to receive the fluid from the pump. Each of the irrigation units has a plurality of irrigation ports therein and each of the irrigation units is positioned over a container garden. Moreover, each of the irrigation ports is aligned with a respective one of a plurality of containers in the container garden to release the fluid into the respective container.

A hydroponic cultivation apparatus, a system and a method for facilitating hydroponic cultivation is disclosed. The hydroponic cultivation apparatus includes a reservoir, a plinth, a grow tray with a grow tray lid, and a docking with coupler. The reservoir, placed upon the plinth, is located at a higher position adjacent to the grow tray for optimizing liquid circulation from the reservoir to the grow tray and vice-versa using one or more pipes, a solenoid valve and a pump. The base further includes a dock coupled to the grow tray for providing an electrical connectivity to the grow tray and simultaneously allowing the liquid to flow through the grow tray without being leaked. Further, the apparatus is having a roof which is provided with sources of illumination for providing light required for plant growth.

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.