In the field of hydroponic production of plants, a system is provided for line production of hydroponic systems. In addition, the hydroponic systems produced by the system for line production of hydroponic systems are also provided herein.

The invention taught is a method and apparatus to mix a special polymer, hot water or other hot water material containing additives and a special mixture of dry growing substances mixed in a particular way so that they may be applied to structures such as to ceilings, walls, and any grade of vertical slants, commercial roofs, courtyards, indoor and outdoor applications. The purpose is to coat any surface and grow any plant for any reason be it erosion control, beautification of an area. The invention would help in reforestation after fires and such. This invention has a wide range of applications and so it is impossible to limit it to just one of these applications. Green parking lots and green areas that before could not be made green is just one area for the invention.

A plant container conditioning system is provided including a growing pot having a top, bottom, sides and inner volume enabled to support and grow a plant. A cover is provided and enabled to completely contain a plant growing pot. A growing medium is contained within the pot and at least one layer of mulch, at least one layer of fertilizer and at least one layer of compost is applied on top of the growing medium in the pot, wherein at the end of a growing cycle of the plant, the at least one layers of the mulch, fertilizer and compost is applied on top of 10 the growing medium, the cover is placed over the pot and secured around the bottom surface, the pot and cover then remains outdoors for a time period between three and seven months.

A plant container conditioning system is provided including a growing pot having a top, bottom, sides and inner volume enabled to support and grow a plant. A cover is provided and enabled to completely contain a plant growing pot. A growing medium is contained within the pot and at least one layer of mulch, at least one layer of fertilizer and at least one layer of compost is applied on top of the growing medium in the pot, wherein at the end of a growing cycle of the plant, the at least one layers of the mulch, fertilizer and compost is applied on top of 10 the growing medium, the cover is placed over the pot and secured around the bottom surface, the pot and cover then remains outdoors for a time period between three and seven months.

Growing devices, systems and methods for promoting growth of seedlings may include at least one energy output device; at least one growing environment that includes a first growing environment; a nutrient solution container within the first growing environment, the nutrient solution container for supporting seedlings during growth; at least one growth assist device (GAD) associated with the first growing environment; and a controller. The controller may generate consumption data regarding operation of the at least one GAD and generation data regarding operation of the at least one energy output device. The controller may determine, based on at least one predetermined constraint, as well as consumption data and generation data, a consumption-generation plan and may control energy output to at least one GAD based on the determined consumption-generation plan. The controller may control energy generation, by at least one energy output device, based on the determined consumption-generation plan.

Growing devices, systems and methods for promoting growth of seedlings may include at least one energy output device; at least one growing environment that includes a first growing environment; a nutrient solution container within the first growing environment, the nutrient solution container for supporting seedlings during growth; at least one growth assist device (GAD) associated with the first growing environment; and a controller. The controller may generate consumption data regarding operation of the at least one GAD and generation data regarding operation of the at least one energy output device. The controller may determine, based on at least one predetermined constraint, as well as consumption data and generation data, a consumption-generation plan and may control energy output to at least one GAD based on the determined consumption-generation plan. The controller may control energy generation, by at least one energy output device, based on the determined consumption-generation plan.

A method and system for use therein for providing O.sub.2 and H.sub.2 gases directly to the soil proximal to the roots of plants via electrolysis is described. The method employs at least one electrolyzer disposed adjacent to, or inline with, the irrigation waterline of the plant grow operation to facilitate the introduction of the gases to the soil. A power source is used to provide the electrolytic conversion, and gases remain in a micro-bubbled form to flow through the waterline more easily to the plants where they are needed the most. A venturi is used to channel the dissolved gases in the waterline from the electrolyzer in embodiments having an external HyGrO unit. The inline embodiment electrolyzes the water without need of a venturi to reintroduce the gases to the waterline.

The present disclosure belongs to the technical field of ecological environmental protection, resource development and utilization and new materials, and particularly relates to a method and device for rapidly forming artificial clay and artificial organic ecological mud. The method comprises the following steps: raw material and water storage preparation; preparing nutrient aqueous solution; preparing mineral muddy water; preparing flocculent mineral solution; and reacting and dehydrating to form artificial clay or artificial organic ecological mud. The device comprises a grinding mill, a feeding system, a silo, a belt conveyor, an agitator, a dehydration system and a reservoir. In accordance with the present disclosure, the formation period of natural clay is greatly shortened by artificial means, making the clay become a renewable resource.

The present disclosure belongs to the technical field of ecological environmental protection, resource development and utilization and new materials, and particularly relates to a method and device for rapidly forming artificial clay and artificial organic ecological mud. The method comprises the following steps: raw material and water storage preparation; preparing nutrient aqueous solution; preparing mineral muddy water; preparing flocculent mineral solution; and reacting and dehydrating to form artificial clay or artificial organic ecological mud. The device comprises a grinding mill, a feeding system, a silo, a belt conveyor, an agitator, a dehydration system and a reservoir. In accordance with the present disclosure, the formation period of natural clay is greatly shortened by artificial means, making the clay become a renewable resource.

The invention relates to a method for producing a stabilized growing medium for cultivation of a plant or seedling. The method comprises the steps of providing a receiving unit for containing the rooting plug to be formed and placing a root structure of a plant or seedling in the receiving unit. Further, the method includes the steps of filling the receiving unit with slurry material forming a stabilized growing medium and curing the slurry material in the receiving unit while holding the root structure of the plant or seedling in the receiving unit.