Disclosed is an apparatus for injecting a plurality of constituents by confining the constituents in one or more tubes. The apparatus includes an outer tube (1015D); a global positioning satellite (GPS) (1113C); a programmable logic controller (PLC) (1105C); an Artificial intelligence (AI) robot (1107C, and 1205); a computer (1111C); an encoder (1305B); a plurality of limit switches (1405, 1407, and 1409), and a spacer tube (1015D). The outer tube (1015D) includes a plurality of stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D). The stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D) are stackable either in cylinder segments or polygonal shapes. Constituents confined therein or the stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D) themselves may be ejected through apertures for injection purposes. Some constituent contents may be ejected vertically or laterally-through perforations in the tube wall sub-surface to enable constituent amendment or sequestration. The stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D) may have apertures that when closed protects the constituents from soil or water penetration. The stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D) may be ejected with Constituents partially sub-surface with the remaining length purposefully positioned above the surface. Living Organisms may be injected within specialty protective stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D) that also provide habitat support after placement.

Disclosed is an apparatus for injecting a plurality of constituents by confining the constituents in one or more tubes. The apparatus includes an outer tube (1015D); a global positioning satellite (GPS) (1113C); a programmable logic controller (PLC) (1105C); an Artificial intelligence (AI) robot (1107C, and 1205); a computer (1111C); an encoder (1305B); a plurality of limit switches (1405, 1407, and 1409), and a spacer tube (1015D). The outer tube (1015D) includes a plurality of stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D). The stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D) are stackable either in cylinder segments or polygonal shapes. Constituents confined therein or the stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D) themselves may be ejected through apertures for injection purposes. Some constituent contents may be ejected vertically or laterally-through perforations in the tube wall sub-surface to enable constituent amendment or sequestration. The stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D) may have apertures that when closed protects the constituents from soil or water penetration. The stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D) may be ejected with Constituents partially sub-surface with the remaining length purposefully positioned above the surface. Living Organisms may be injected within specialty protective stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D) that also provide habitat support after placement.

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.

A system for packaging growth medium pots onto propagation trays is provided. The system includes an apparatus adapted for producing a length of growth medium cut into growth medium pots of suitable size; and a distributor apparatus adapted for positioning growth medium pots into a propagation tray or the like. The distributor apparatus comprises a) a first apparatus, b) a conveyor unit, and c) a second apparatus. The first apparatus is configured for positioning growth medium pots onto said conveyor unit. The conveyor unit comprises an endless conveyor belt adapted for transporting the growth medium pots toward the second apparatus. The second apparatus is configured for moving said growth medium pots positioned on the said conveyor belt into a propagation tray or the like.

A system for packaging growth medium pots onto propagation trays is provided. The system includes an apparatus adapted for producing a length of growth medium cut into growth medium pots of suitable size; and a distributor apparatus adapted for positioning growth medium pots into a propagation tray or the like. The distributor apparatus comprises a) a first apparatus, b) a conveyor unit, and c) a second apparatus. The first apparatus is configured for positioning growth medium pots onto said conveyor unit. The conveyor unit comprises an endless conveyor belt adapted for transporting the growth medium pots toward the second apparatus. The second apparatus is configured for moving said growth medium pots positioned on the said conveyor belt into a propagation tray or the like.

A three-dimensional shape information generating system, a three-dimensional shape forming apparatus, a three-dimensional shape information generating method, and a program, each of which is capable of forming a three-dimensional-shaped object that has an arbitrary outer shape and is used to cultivate plants.

A three-dimensional shape information generating system, a three-dimensional shape forming apparatus, a three-dimensional shape information generating method, and a program, each of which is capable of forming a three-dimensional-shaped object that has an arbitrary outer shape and is used to cultivate plants.

Methods and equipment for high-speed production and improving quality of liquid and solid organic fertilizers from organic solid wastes by (1) pre-treatment system, for purification, size reduction, and slurry generation, (2) HiSAP recycling system using slurry generated to form soluble compounds of easily degradable organics, and insoluble compounds of moderately degradable organics of mainly lignocellulosic materials, and production of organic radicals, reactive oxygen species including superoxygen, hydroperoxyl radical, hydrogen peroxide, and hydroxyl radical to thermally decomposing easily degradable organic and curing remaining compounds therein, and (3) product refining system to produce organic fertilizers, to enhance 7 major functions and capabilities including moisture absorption and holding, nutrients adsorption and holding, soil particles holding and conserving, soil air ventilation, soil water transmission, soil thermal insulation, and generation of plant growth stimulation agents, and pollution elimination as sterilizing pathogens and parasites, detoxicating toxic organics, and removing heavy metals therefrom.

Methods and equipment for high-speed production and improving quality of liquid and solid organic fertilizers from organic solid wastes by (1) pre-treatment system, for purification, size reduction, and slurry generation, (2) HiSAP recycling system using slurry generated to form soluble compounds of easily degradable organics, and insoluble compounds of moderately degradable organics of mainly lignocellulosic materials, and production of organic radicals, reactive oxygen species including superoxygen, hydroperoxyl radical, hydrogen peroxide, and hydroxyl radical to thermally decomposing easily degradable organic and curing remaining compounds therein, and (3) product refining system to produce organic fertilizers, to enhance 7 major functions and capabilities including moisture absorption and holding, nutrients adsorption and holding, soil particles holding and conserving, soil air ventilation, soil water transmission, soil thermal insulation, and generation of plant growth stimulation agents, and pollution elimination as sterilizing pathogens and parasites, detoxicating toxic organics, and removing heavy metals therefrom.

Systems, methods, and kits for plant propagation are disclosed. In some embodiments, the systems, methods, and kits for plant propagation involve a plug, a wrap, and a container. The container is configured to house the plug with a plant growing therein, where the plug is encircled by the wrap within the container, and where the plug and the wrap may include the same material.