A customizable hydroponic growth system comprises a housing having a reservoir structure which is subdivided into a plurality of separate cells within each of which a different plant is receivable and hydroponically growable; and a cover covering the reservoir structure which is configured with a plurality of individually removable plant retainer sections, arranged such that each of said plant retainer sections is aligned with a corresponding one of said cells, wherein a first plant is removable from a first cell of the reservoir structure together with the plant retainer section with which is it retained while roots of the first plant are ensured of not being entangled with the roots of a second plant received in second cell of the reservoir structure which is adjacent to the first cell.

A customizable hydroponic growth system comprises a housing having a reservoir structure which is subdivided into a plurality of separate cells within each of which a different plant is receivable and hydroponically growable; and a cover covering the reservoir structure which is configured with a plurality of individually removable plant retainer sections, arranged such that each of said plant retainer sections is aligned with a corresponding one of said cells, wherein a first plant is removable from a first cell of the reservoir structure together with the plant retainer section with which is it retained while roots of the first plant are ensured of not being entangled with the roots of a second plant received in second cell of the reservoir structure which is adjacent to the first cell.

A system for the fertigation of a plant vessel and method of use for the same is disclosed. The system comprises a grow module containing a plurality of growing trays additionally containing plants, and/or shoots of plants in various stages of development. The growing trays are individually extracted from the grow module via a tray movement system and tray elevator controlled by a control system and precisely placed in a fertigation system, wherein they are aligned over and lowered onto an at least one nozzle which penetrate the plant vessels containing the plants and fertigate them with a combination of water, nutrients, and/or pressurized air. The individual growing tray is then replaced in the grow module and the process is repeated for all growing trays and plant vessels in the grow module.

A system for the fertigation of a plant vessel and method of use for the same is disclosed. The system comprises a grow module containing a plurality of growing trays additionally containing plants, and/or shoots of plants in various stages of development. The growing trays are individually extracted from the grow module via a tray movement system and tray elevator controlled by a control system and precisely placed in a fertigation system, wherein they are aligned over and lowered onto an at least one nozzle which penetrate the plant vessels containing the plants and fertigate them with a combination of water, nutrients, and/or pressurized air. The individual growing tray is then replaced in the grow module and the process is repeated for all growing trays and plant vessels in the grow module.

A hydroponic system is provided. One such system comprises a reservoir, flexible fluid table and support system. The reservoir comprising a first plurality of apertures. The flexible fluid table is substantially encapsulated by the reservoir. The support system comprises at least one flexible fluid table support and a coupling system. A first portion of the coupling system surrounds at least a portion of the reservoir and a second portion of the coupling system at least one of directly and indirectly couples the at least one flexible fluid table support to the flexible fluid table.

A hydroponic system is provided. One such system comprises a reservoir, flexible fluid table and support system. The reservoir comprising a first plurality of apertures. The flexible fluid table is substantially encapsulated by the reservoir. The support system comprises at least one flexible fluid table support and a coupling system. A first portion of the coupling system surrounds at least a portion of the reservoir and a second portion of the coupling system at least one of directly and indirectly couples the at least one flexible fluid table support to the flexible fluid table.

An irrigation device for promoting deep root growth of a plant. The irrigation device may comprise: a tube and a hose, wherein the hose may have one or more slits that allow liquid to seep out if the water pressure in the hose is too high. The water pressure may get too high if the pores of the soaker hose become temporarily clogged, which may happen if a fertilizer solution is put into the irrigation system.

The subject invention is an electrostatic plant watering system for the delivery of water and nutrients to the roots of plants. The system provides water or another fluid from a fluid source or container using a pump. The pump provides a pressurized fluid at a constant flow rate through a nozzle at a low pressure, which sprays a fine mist of particles through a conductive metallic ring that is electrically charged by a voltage source. As the fluid particles pass through the center of the electrically charged ring, the particles themselves become charged, allowing them to attach to the roots of a target plant positioned at a selected distance away from the electrostatic plant watering system.

The subject invention is an electrostatic plant watering system for the delivery of water and nutrients to the roots of plants. The system provides water or another fluid from a fluid source or container using a pump. The pump provides a pressurized fluid at a constant flow rate through a nozzle at a low pressure, which sprays a fine mist of particles through a conductive metallic ring that is electrically charged by a voltage source. As the fluid particles pass through the center of the electrically charged ring, the particles themselves become charged, allowing them to attach to the roots of a target plant positioned at a selected distance away from the electrostatic plant watering system.

The disclosed composition for fertilization and treating trees, shrubs and climbing plants with programmed release of the active substance is comprising the active substance stored in capsules made by nanoencapsulation or microencapsulation method and wherein based on capsule membrane the time of release of the active substance is adjusted. The active component stored in the nanocapsules or microcapsules can be such that it acidifies the surrounding soil in the range of pH 2,5 to pH 6,5. One example of such active component is the use of citric acid, which is completely ecological and does not create environmental pollution. Also, the active component in the nanocapsules can be such that it regulates the acidity of the soil in the range of pH 6,5 to pH 7,0. Furthermore, the active component in the special capsules can be an insecticide and/or in the special capsules fungicide, and/or in the special capsules acaricide and/or in the special capsules pheromone and/or in the special capsules repellent.