A water distribution assembly includes a water capture cup adapted to hold a volume of water, the capture cup including an open recess disposed centrally thereon extending upward into the internal volume thereof, a location spike having a fin configuration, the location spike having a bottom portion and a top portion, the top portion culminating at a central stem, the bottom and top portion separated by a flange, the location spike fitted into the recess of the capture cup extending orthogonally below and above the bottom of the capture cup, and a water regulator with a central emitter valve disposed centrally above the capture cup, the regulator cup connected to a water inlet line via a feed stem and to a vertical feeder tube below center, the feeder tube extending downward and connected at the remaining end over the central stem of the location spike.

A water distribution assembly includes a water capture cup adapted to hold a volume of water, the capture cup including an open recess disposed centrally thereon extending upward into the internal volume thereof, a location spike having a fin configuration, the location spike having a bottom portion and a top portion, the top portion culminating at a central stem, the bottom and top portion separated by a flange, the location spike fitted into the recess of the capture cup extending orthogonally below and above the bottom of the capture cup, and a water regulator with a central emitter valve disposed centrally above the capture cup, the regulator cup connected to a water inlet line via a feed stem and to a vertical feeder tube below center, the feeder tube extending downward and connected at the remaining end over the central stem of the location spike.

A plant treatment system configured to provide improved growth for hydroponically grown plants. The plant treatment system includes an air treatment apparatus that is configured to provide temperature controlled and sterilized air to the root ball of a plant. The air treatment apparatus includes an air pump operable to draw air in from the surroundings and move through the air treatment apparatus. The air treatment apparatus includes an air ionizer and a dehumidifier wherein the air from the air pump passes through both. A temperature control unit provides the ability to control the temperature of the air as the air exits the air treatment apparatus. The air treatment apparatus further includes an oxygen concentrator that is operable to provide an air flow exiting from the air treatment apparatus that has a higher oxygen concentration. A dosing unit to deliver liquid nutrients is further included.

A plant treatment system configured to provide improved growth for hydroponically grown plants. The plant treatment system includes an air treatment apparatus that is configured to provide temperature controlled and sterilized air to the root ball of a plant. The air treatment apparatus includes an air pump operable to draw air in from the surroundings and move through the air treatment apparatus. The air treatment apparatus includes an air ionizer and a dehumidifier wherein the air from the air pump passes through both. A temperature control unit provides the ability to control the temperature of the air as the air exits the air treatment apparatus. The air treatment apparatus further includes an oxygen concentrator that is operable to provide an air flow exiting from the air treatment apparatus that has a higher oxygen concentration. A dosing unit to deliver liquid nutrients is further included.

A water-circulation irrigation system includes a water supply device and a planting device. The planting device includes a water storage container, an irrigation pipeline, a nozzle and a recycling pipeline. One end of the irrigation pipeline is in communication with the water storage container and has a water supply end. The planting device includes a water collection container, a planting tray and a shunting element. The water collection container has a water dispensing post. The planting tray is disposed at an opening of the water collection container. The planting tray has a fitting portion and a through hole and corresponds in position to a water collection space of the water collection container. The shunting element includes a fertilizer chamber and is disposed at the rim of the through hole of the fitting portion. Therefore, a fertilizer solution is produced in a manpower-efficient manner and thus conveniently.

A water-circulation irrigation system includes a water supply device and a planting device. The planting device includes a water storage container, an irrigation pipeline, a nozzle and a recycling pipeline. One end of the irrigation pipeline is in communication with the water storage container and has a water supply end. The planting device includes a water collection container, a planting tray and a shunting element. The water collection container has a water dispensing post. The planting tray is disposed at an opening of the water collection container. The planting tray has a fitting portion and a through hole and corresponds in position to a water collection space of the water collection container. The shunting element includes a fertilizer chamber and is disposed at the rim of the through hole of the fitting portion. Therefore, a fertilizer solution is produced in a manpower-efficient manner and thus conveniently.

This invention relates to a modular, scalable fogponic plant growth system for growing plants individually with roots physically and fluidly isolated from one another. A high-pressure fluid delivery system operates above 150 psi and is configured for fluidly connecting at least one spray nozzle positioned within each root enclosure to simultaneously deliver fluid to the roots of each plant within a zone of root enclosures. A passive drain system continuously removes any unabsorbed fluid, such that the roots of each and every plant are physically and fluidly isolated from one another.

This invention relates to a modular, scalable fogponic plant growth system for growing plants individually with roots physically and fluidly isolated from one another. A high-pressure fluid delivery system operates above 150 psi and is configured for fluidly connecting at least one spray nozzle positioned within each root enclosure to simultaneously deliver fluid to the roots of each plant within a zone of root enclosures. A passive drain system continuously removes any unabsorbed fluid, such that the roots of each and every plant are physically and fluidly isolated from one another.

The present application relates to agriculture productions system that allows tor the controlled release of beneficial agents into a plant root mass, and more particularly it is beneficial for agriculture production where control of infusion of micro-nutrient, infusion macronutrient, root temperature control agents, nutrients and/or elements are applied to the root zone of a plant.

The present application relates to agriculture productions system that allows tor the controlled release of beneficial agents into a plant root mass, and more particularly it is beneficial for agriculture production where control of infusion of micro-nutrient, infusion macronutrient, root temperature control agents, nutrients and/or elements are applied to the root zone of a plant.