An indoor gardening appliance includes a liner defining a grow chamber and a grow module mounted within the grow chamber for receiving a plurality of plant pods. A nutrient dosing system is positioned within a root chamber and includes a plurality of nozzles. A nutrient cartridge and a water supply are fluidly coupled to a dilution tank and are independently regulated to control the flow rate of nutrients and water that are mixed to create a flow of diluted nutrient mixture. A pump system selectively discharges the flow of diluted nutrient mixture to desired locations within the root chamber.

Disclosed herein is a hydroponic system comprising a water container, a gas pump disposed within the water container, and an air chamber disposed around the gas pump. The hydroponic system also includes an air line extending into the air chamber to drive air into the air chamber water within the water container, and an air bell disposed within the water container to capture the air from the air line, wherein the air bell maximizes the surface area of the water with the captured air. Also disclosed is a system and a method for implementing the system.

A plant system with structural frame and water storage chamber which allows for the collection of surface water emanating from impervious surface for retrieval and re-use.

A plant system with structural frame and water storage chamber which allows for the collection of surface water emanating from impervious surface for retrieval and re-use.

A hydroponic growing system is presented. The system can include multiple growing trays in a vertical arrangement, where a pump supplies the top-most tray and each lower tray is supplied by the overlying tray, and where the plumbing elements for supply and drainage are arranged to one side of the system. The system includes variations to support different crop types within the same system, including removable growing structures for root vegetable, microgreens and supports for vining crops. The system can monitor and adjust the nutrients and other features of the systems water profile to concurrently group multiple crops in differing developing stages.

The disclosure relates to technology for hydroponics. An aspect includes a hydroponic system comprising a tray having a drain opening in a bottom of the tray. The hydroponic system comprises a water re-circulation system configured to re-circulate water containing plant nutrients through the hydroponic system. The water re-circulation system is configured to provide the water containing the plant nutrients to the tray. The tray is configured to convey the water along the bottom the tray to the drain opening, the drain opening configured to drain the water from the tray. The hydroponic system comprises different types of removable growing structures that are configured to provide corresponding different vertical distances between a top of a hydroponic growing medium and the bottom of the tray.

The disclosure relates to technology for hydroponics. One aspect includes a computing system comprising a network interface, and a processor coupled to the network interface. The processor is configured to receive plant observations over the network interface from a plurality of electronic devices. The plant observations are for a type of crop being grown in respective hydroponic systems. The processor is configured is modify a technique for determining a water profile based on the plant observations, the water profile for growing the type of crop in a hydroponic system. The processor is configured to determine a target water profile for growing crops in a target hydroponic system based on the modified technique, the crops in the target hydroponic system include the type of crop. The processor is configured to provide the target water profile over the network interface to a requesting electronic device.

A hydroponic growing system is presented. The system can include multiple growing trays in a vertical arrangement, where a pump supplies the top-most tray and each lower tray is supplied by the overlying tray, and where the plumbing elements for supply and drainage are arranged to one side of the system. The system includes variations to support different crop types within the same system, including removable growing structures for root vegetable, microgreens and supports for vining crops. The system can monitor and adjust the nutrients and other features of the systems water profile to concurrently group multiple crops in differing developing stages.

An in-ground water distribution assembly includes a ground water capture cup with a top rim defining an open end, a location spike fitted to the bottom of the ground water capture cup, the location spike extending downward orthogonally from the bottom of the capture cup, a plurality of vertical support risers connected or seated in riser seats distributed about the inside wall of the capture cup, the vertical risers extending upward and at angle inward toward center of the capture cup and fitted to a vertical feeder tube, and a water pressure flow regulator having an inline feeder nozzle and an egress pressure valve mechanism connected to the feeder tube at top center of the assembly.

An in-ground water distribution assembly includes a ground water capture cup with a top rim defining an open end, a location spike fitted to the bottom of the ground water capture cup, the location spike extending downward orthogonally from the bottom of the capture cup, a plurality of vertical support risers connected or seated in riser seats distributed about the inside wall of the capture cup, the vertical risers extending upward and at angle inward toward center of the capture cup and fitted to a vertical feeder tube, and a water pressure flow regulator having an inline feeder nozzle and an egress pressure valve mechanism connected to the feeder tube at top center of the assembly.