Systems and methods for vertical farming that reduce the deployment cost, operational costs of human labor, and overall use of energy intensive processes, such as lighting, heating and cooling, and ventilation, while increasing crop quality and yield. This reduction is achieved through a hybrid system that alternates natural light, temperature, and ventilation sources with system-controlled lighting, temperature, and ventilation means. The system includes a germination module that allows seeds to germinal on a horizontal substrate, a growth module that provides optimal growth conditions to the germinated seed on the substrate in a vertical position, and a dosing module that controls the micronutrient mixture supplied to the growing plants.

Embodiments of the present invention provide hydroponics farming apparatus, and systems including the same. The farming apparatus comprises a frame, a plurality of functional systems, a first plurality of sensors configured to monitor conditions associated with farming of the one or more plants, and one or more modular storage cabinets removably attached to the frame. The one or more modular storages include electronics that are pre-assembled and configured to communicate with one or more of the first plurality of sensors and the plurality of functional systems. The electronics includes a main controller configured to collect data from the first plurality of sensors.

The specification discloses a large scale hydroponic system including a plurality of grow tanks interconnected in a subsystem, and a reservoir. The reservoir is connected to the grow tanks through a pump that outputs nutrient fluid through a nutrient supply line. The nutrient supply line is connected to the grow tanks through a subsystem supply line. The subsystem supply line supplies fresh nutrient fluid to each of the grow tanks in the subsystem at substantially the same time. Excess nutrient fluid is exits the grow tanks through an overflow line, which is connected to the reservoir and returns the excess nutrient fluid to the reservoir. A drain line may be connected to the grow tanks to allow the nutrient fluid to be removed from the grow tanks. The drain line is connected to the reservoir and returns the removed nutrient fluid to the reservoir.

An aquaponic grow system includes a plurality of sensors for sensing nutrient levels in liquid provided to a grow chamber, and to adjust nutrient levels based on the sensed levels. In some embodiments the system includes a plurality of sensors configured to sense nutrient levels in a common chamber, with the system configured to calibrate the sensors.

An indoor gardening appliance includes a liner defining a grow chamber and a grow module rotatably mounted within the grow chamber for receiving a plurality of plant pods. A grow module is provided for receiving pods within apertures of the grow module, which includes locking tabs configured for slidably engaging with slots, which are defined in each pod. The grow module and the pods have complementary tapered interfaces that form a seal when the locking tabs are slidably engaged with the slots.

There is a modular, insulated, all-in-one, plug-and-play (MIAP) aquaponics unit that includes a framework having a single base and plural walls; an aquaculture tank defined by a first portion of the single base and a first set of the plural walls; a clarifier tank defined by a second portion of the single base and a second set of the plural walls; a bio-reactor tank defined by a third portion of the single base and a third set of the plural walls; a hydroponics tank defined by a fourth portion of the single base and a fourth set of the plural walls; and piping extending through the plural walls between each two adjacent tanks for allowing water from the aquaculture tank to flow into the clarifier tank and then into the bio-reactor tank and then into the hydroponics tank and back to the aquaculture tank.

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.

A hydroponic planter for indoors is a system comprising two or more sheets of plastic film or waterproof fabric panels heat-sealed together to form ducts and channels for nutritive water to circulate and feed plants. Plant holders enable placement of plants in varying positions in openings in the system. A pump in a reservoir circulates water through the system. The panels' flexible material enables portability.

The disclosure relates to technology for housing a hydroponic system. A hydroponic system is supported by a frame and includes a water re-circulation system that provides water and other nutrients to a set of plants housed within the frame and supported by the hydroponic system. A light source is also included to illuminate the set of plants. An external plant extension is connected to the frame and extends outside of the frame, thereby providing support for an external plant placed outside of the frame and enabling illumination of the external plant by the light source of the hydroponic system. In some embodiments, the external plant may also receive water from the hydroponic system through a wick or pump coupled to the frame (directly or indirectly) in a manner the draws water from the hydroponic system and delivers the water to the external plant.

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.