A plant watering device designed and configured to efficiently provide water to either potted plants or to in-ground garden plants. The plant watering device having a hollow elongated cylindrical member and at least one series of linearly aligned apertures having sequential decreasing diameters along a length of a lower section of the hollow elongated cylindrical member which is inserted into a plant root zone. The hollow elongated cylindrical member of the invention being structured to receive at least one aqueous liquid from at least one aqueous liquid source.

A plant watering device designed and configured to efficiently provide water to either potted plants or to in-ground garden plants. The plant watering device having a hollow elongated cylindrical member and at least one series of linearly aligned apertures having sequential decreasing diameters along a length of a lower section of the hollow elongated cylindrical member which is inserted into a plant root zone. The hollow elongated cylindrical member of the invention being structured to receive at least one aqueous liquid from at least one aqueous liquid source.

A cabinet for growing plants has a divider. The divider hermetically separates a plant space of the cabinet from a control space of the cabinet. The divider has a plant side, a control side, and electro-magnetic radiation (EMR) emitters, mounted on the plant side of the divider. The EMR emitters are adapted to EMR frequencies primarily at or near visible light. There is a vent in the divider. A fan pulls air through the vent. A microprocessor controls the fan and the EMR emitters.

A cabinet for growing plants has a divider. The divider hermetically separates a plant space of the cabinet from a control space of the cabinet. The divider has a plant side, a control side, and electro-magnetic radiation (EMR) emitters, mounted on the plant side of the divider. The EMR emitters are adapted to EMR frequencies primarily at or near visible light. There is a vent in the divider. A fan pulls air through the vent. A microprocessor controls the fan and the EMR emitters.

A hydration system for an indoor gardening appliance includes sump for collecting water used to hydrate plants and a water supply containing fresh water. The sump and the water supply are fluidly coupled to a supply conduit and a pump assembly urges a flow of liquid through the supply conduit. A diverter assembly controls the amount of liquid recirculated from the sump and the flow of fresh water from the water supply. The hydration system further includes a drain valve that selectively discharges liquid from the sump to an external drain.

A hydration system for an indoor gardening appliance includes sump for collecting water used to hydrate plants and a water supply containing fresh water. The sump and the water supply are fluidly coupled to a supply conduit and a pump assembly urges a flow of liquid through the supply conduit. A diverter assembly controls the amount of liquid recirculated from the sump and the flow of fresh water from the water supply. The hydration system further includes a drain valve that selectively discharges liquid from the sump to an external drain.

A smart root watering system is disclosed. The system includes a controller, configured to control the system using artificial neural networks. The system further comprises vertical tubes, inserted into the soil proximity to the roots of trees and configured to deliver water to the roots of trees. The vertical tubes include a motion sensor, configured to detect variation in water flow and wirelessly send data to the controller, thereby indicating faults of the vertical tubes to the user via a handheld electronic device. The vertical tube further includes a mechanical valve with a floater, configured to regulate input water to the system with respect to the soil absorption. The system further comprises a sensor device, configured to detect the humidity level and send to the controller. The controller is further configured to estimate the required volume of water and open an electric valve for supplying water to the roots of trees.

A smart root watering system is disclosed. The system includes a controller, configured to control the system using artificial neural networks. The system further comprises vertical tubes, inserted into the soil proximity to the roots of trees and configured to deliver water to the roots of trees. The vertical tubes include a motion sensor, configured to detect variation in water flow and wirelessly send data to the controller, thereby indicating faults of the vertical tubes to the user via a handheld electronic device. The vertical tube further includes a mechanical valve with a floater, configured to regulate input water to the system with respect to the soil absorption. The system further comprises a sensor device, configured to detect the humidity level and send to the controller. The controller is further configured to estimate the required volume of water and open an electric valve for supplying water to the roots of trees.

A non-interconnected growth system. The system includes a plurality of plant growth units. Each plant growth unit in the plurality of plant growth units is water and nutrient isolated from any other plant growth unit. The system also includes a dynamic nutrient manager configured to collect data from the one or more plant growth units and calculate a customized nutrient plan for each plant growth unit based on the collected data. The system also includes a central fertilizing system configured to receive the nutrient plan for each plant growth unit and deliver nutrients to each plant growth unit based on their respective nutrient plan.

A non-interconnected growth system. The system includes a plurality of plant growth units. Each plant growth unit in the plurality of plant growth units is water and nutrient isolated from any other plant growth unit. The system also includes a dynamic nutrient manager configured to collect data from the one or more plant growth units and calculate a customized nutrient plan for each plant growth unit based on the collected data. The system also includes a central fertilizing system configured to receive the nutrient plan for each plant growth unit and deliver nutrients to each plant growth unit based on their respective nutrient plan.