A smart hydroponic vase system, a method for growing a plant in a smart hydroponic vase, and a method of assembling a smart hydroponic vas is described. The smart hydroponic vase includes a housing having a plurality of chambers; a submersible pump located in each of the plurality of chambers; a plurality of pipes, wherein each pipe connects a different chamber to the first chamber, wherein each pipe is connected to a respective submersible pump; a plurality of measurement sensors including ultrasonic level sensors and a temperature sensor, and a microprocessor connected to receive measurement signals and the level signals and generate drive signals to actuate the plurality of pumps based on sensor signals. A wireless communications unit is connected to the microprocessor. The smart hydroponic vase communicates with a plant manager through a server.

A smart hydroponic vase system, a method for growing a plant in a smart hydroponic vase, and a method of assembling a smart hydroponic vas is described. The smart hydroponic vase includes a housing having a plurality of chambers; a submersible pump located in each of the plurality of chambers; a plurality of pipes, wherein each pipe connects a different chamber to the first chamber, wherein each pipe is connected to a respective submersible pump; a plurality of measurement sensors including ultrasonic level sensors and a temperature sensor, and a microprocessor connected to receive measurement signals and the level signals and generate drive signals to actuate the plurality of pumps based on sensor signals. A wireless communications unit is connected to the microprocessor. The smart hydroponic vase communicates with a plant manager through a server.

An extended term hydroponic cultivation apparatus and method provide a growth environment for a plant to develop an oxygen root structure and a water root structure as the plant matures. The root structure of the plant is carried in a growth chamber containing an initial water level with an air gap defined above the water level for development of the oxygen root structure in the air gap. Water root structure development progresses downwardly to a bottom of the growth chamber as the plant consumes water contained within the system until reaching a terminal growth length in a terminal water level. A float valve maintains the water in the system at the terminal water level to sustain plant growth for an extended temporal duration. A drain valve allows for evacuation of water for replenishment with a fresh source of water to the terminal water level.

An extended term hydroponic cultivation apparatus and method provide a growth environment for a plant to develop an oxygen root structure and a water root structure as the plant matures. The root structure of the plant is carried in a growth chamber containing an initial water level with an air gap defined above the water level for development of the oxygen root structure in the air gap. Water root structure development progresses downwardly to a bottom of the growth chamber as the plant consumes water contained within the system until reaching a terminal growth length in a terminal water level. A float valve maintains the water in the system at the terminal water level to sustain plant growth for an extended temporal duration. A drain valve allows for evacuation of water for replenishment with a fresh source of water to the terminal water level.

A vertical hydroponic plant production apparatus for allowing vertical hydroponic greenhouse crop production is provided. The apparatus comprises a hollow grow tube having a front face, a back face, an open first end, and an open second end. A slot is formed in the front face of the grow tube with the slot having a width equal to only a portion of a width of the front face. A media material is insertable into the grow tube. The slot allows the front face to expand outward during insertion of the media material and biased inward against the media material once the media material is inserted. The grow tube is positionable in either a horizontal position, vertical position, or any position between the horizontal position and the vertical position allowing inclined, multi-angled crop production and multi-storied conveyor style crop production.

A vertical hydroponic plant production apparatus for allowing vertical hydroponic greenhouse crop production is provided. The apparatus comprises a hollow grow tube having a front face, a back face, an open first end, and an open second end. A slot is formed in the front face of the grow tube with the slot having a width equal to only a portion of a width of the front face. A media material is insertable into the grow tube. The slot allows the front face to expand outward during insertion of the media material and biased inward against the media material once the media material is inserted. The grow tube is positionable in either a horizontal position, vertical position, or any position between the horizontal position and the vertical position allowing inclined, multi-angled crop production and multi-storied conveyor style crop production.

A plant growth system for a microgravity environment includes a root chamber configured to prevent liquid from escaping from the root chamber in the microgravity environment and to enable recovery of liquid from within the root chamber. In some embodiments, the root chamber may be configured to provide water and/or nutrients to the plants, via ebb/flow and/or spray delivery. In some embodiments, the root chamber includes a main body and a root/shoot interface coupled to the main body. The root/shoot interface can be configured to hold a plant having a root system extending outward from one side of the root/shoot interface into the root chamber and a chute system extending outward from another side of the root/shoot interface outside of the root chamber. The root/shoot interface may be configured to provide water and/or nutrients to the plants.

A plant growth system for a microgravity environment includes a root chamber configured to prevent liquid from escaping from the root chamber in the microgravity environment and to enable recovery of liquid from within the root chamber. In some embodiments, the root chamber may be configured to provide water and/or nutrients to the plants, via ebb/flow and/or spray delivery. In some embodiments, the root chamber includes a main body and a root/shoot interface coupled to the main body. The root/shoot interface can be configured to hold a plant having a root system extending outward from one side of the root/shoot interface into the root chamber and a chute system extending outward from another side of the root/shoot interface outside of the root chamber. The root/shoot interface may be configured to provide water and/or nutrients to the plants.

Disclosed is a system and method for a smart hydroponic system. The system includes a central controller and one or more smart hydroponic system modules. The smart hydroponic system modules automate a number of tasks required to maintain hydroponic agriculture. Further, these tasks are localized to provide greater precision to the agriculture, as even indoor environments can vary. The central controller sends commands which affect every smart hydroponic system module. This provides an efficient mix of central and local control.

Disclosed is a system and method for a smart hydroponic system. The system includes a central controller and one or more smart hydroponic system modules. The smart hydroponic system modules automate a number of tasks required to maintain hydroponic agriculture. Further, these tasks are localized to provide greater precision to the agriculture, as even indoor environments can vary. The central controller sends commands which affect every smart hydroponic system module. This provides an efficient mix of central and local control.