An aquaculture premix and a method of manufacturing a granulated or powdered aquaculture premix are provided.

An agricultural unit includes a tank system that is adapted to provide a combined aquatic environment for raising aquatic animals in aquaculture and for cultivating plants in hydroponic culture and an electrochemical device. The tank system releases excretions of the aquatic animals directly into the aquatic environment so as to produce nutrients for the plants while the electrochemical device is operable in an electrolysis mode to produce hydrogen and oxygen while consuming electrical energy provided by a source of electrical energy and is further operable in a fuel cell mode to produce electrical energy and heat by oxidizing the produced hydrogen. The electrochemical device is operatively coupled to the tank system so as to transfer at least part of the produced heat and the produced oxygen to the aquatic environment.

An agricultural unit includes a tank system that is adapted to provide a combined aquatic environment for raising aquatic animals in aquaculture and for cultivating plants in hydroponic culture and an electrochemical device. The tank system releases excretions of the aquatic animals directly into the aquatic environment so as to produce nutrients for the plants while the electrochemical device is operable in an electrolysis mode to produce hydrogen and oxygen while consuming electrical energy provided by a source of electrical energy and is further operable in a fuel cell mode to produce electrical energy and heat by oxidizing the produced hydrogen. The electrochemical device is operatively coupled to the tank system so as to transfer at least part of the produced heat and the produced oxygen to the aquatic environment.

A steel structure cage for marine crustacean aquaculture and integration thereof into a vertical fish-crustacean aquaculture system are disclosed. The steel structure cage includes a steel frame, top, side and bottom net systems, a ballast tank system, and steel grooves. The steel frame includes internal and external steel frames. The steel grooves are fixed on upper and lower ends of the internal steel frame. Edges of the top and bottom net systems are respectively fixed into the corresponding steel grooves. The side net is welded on the internal steel frame. The ballast tank system is arranged between the internal and external steel frames. A HDPE cage is moored to the steel structure cage to form a vertical aquaculture system. Whereby, an ideal culturing environment for marine crustaceans is given and the objective of vertical aquaculture culturing fish at top water layers and culturing prawns (crabs or cowries) at bottom water layers can be fulfilled.

A method for incubating an aquatic species includes introducing fertilized eggs of the aquatic species into a screened incubation container, introducing the screened incubation container into a vessel of an incubation module, circulating clean oxygenated water through the incubation module vessel, transferring successfully fertilized eggs from the incubation module vessel to an upweller of a hatching module, circulating clean oxygenated water through the upweller, transferring larvae that swim out of the upweller into a tray of a larvae holding module, circulating clean oxygenated water through the larvae holding module, transferring larvae that grow into a juvenile growth stage from the larvae holding module to a tray of a juvenile holding module, circulating clean oxygenated water through the juvenile holding module, and releasing juveniles from the juvenile holding module after a predefined growth period or after the juveniles grow to a predetermined size.

It is disclosed a system for producing methanol/methane, said system comprising an electrolysis section (1) producing hydrogen and oxygen from the cleaving of water molecules, and said system further comprising a closed cultivation/breeding container/pond (5) for aquatic organisms creating CO.sub.2 through their metabolism to be liberated into the water surrounding said organisms forming CO2-rich water, said CO.sub.2-rich water being transported to a CO.sub.2-liberating section forming gaseous CO.sub.2 and CO.sub.2-poor water, said liberated gaseous CO.sub.2 being transported to a reactor (6,6) and being combined with said hydrogen from said electrolysis plant (1) for creating methanol and/or methane as an end product, said methanol/methane being isolated and exited from said system.

It is disclosed a system for producing methanol/methane, said system comprising an electrolysis section (1) producing hydrogen and oxygen from the cleaving of water molecules, and said system further comprising a closed cultivation/breeding container/pond (5) for aquatic organisms creating CO.sub.2 through their metabolism to be liberated into the water surrounding said organisms forming CO2-rich water, said CO.sub.2-rich water being transported to a CO.sub.2-liberating section forming gaseous CO.sub.2 and CO.sub.2-poor water, said liberated gaseous CO.sub.2 being transported to a reactor (6,6) and being combined with said hydrogen from said electrolysis plant (1) for creating methanol and/or methane as an end product, said methanol/methane being isolated and exited from said system.

A marine bioproduction facility for farming of sessile marine organisms in a body of water is disclosed. The facility comprises an array of at least two production modules in contiguous geometrical relationship to each other, where each of the at least two production modules is adapted to be arranged within a vertical column with a predefined horizontal cross section and extending downwards from the water surface, where at least one of the at least two production modules comprises at least one growth surface for sessile marine organisms, and an upper part comprising at least one opening adapted to allow access to the vertical column. Further, a method for growth and harvesting of marine sessile organisms using the marine bioproduction facility is presented.

Provided is a multi-tube nozzle for use in eradicating harmful aquatic organisms, which physically kills harmful aquatic organisms while feeding water and thus allows intake water to be fed directly into a culture tank or a ballast tank without the need for a pretreatment tank, chemicals, neutralizers, etc. A multi-tube nozzle (A) for use in eradicating harmful aquatic organisms includes at least three nozzle tubes (1) that are provided adjacent to each other. The nozzle tubes (1) each includes: an inlet-side opening section (2) having an inner diameter that decreases from an inlet opening toward a throat section (3) located in the middle of the tube; an outlet-side opening section (4) having an inner diameter that increases from the throat section (3) toward an outlet opening; and the throat section (3) having a smallest inner diameter. The adjacent nozzle tubes (1) are spaced apart by a distance such that the adjacent inlet-side opening sections (2) overlap each other. A wall (5) of an overlapping portion (6) of the inlet-side opening sections (2) is cut in a U shape. An uncut portion (5a) between the adjacent U-shaped cut portions (5b) forms a sword-like pointed tip.

Provided is a multi-tube nozzle for use in eradicating harmful aquatic organisms, which physically kills harmful aquatic organisms while feeding water and thus allows intake water to be fed directly into a culture tank or a ballast tank without the need for a pretreatment tank, chemicals, neutralizers, etc. A multi-tube nozzle (A) for use in eradicating harmful aquatic organisms includes at least three nozzle tubes (1) that are provided adjacent to each other. The nozzle tubes (1) each includes: an inlet-side opening section (2) having an inner diameter that decreases from an inlet opening toward a throat section (3) located in the middle of the tube; an outlet-side opening section (4) having an inner diameter that increases from the throat section (3) toward an outlet opening; and the throat section (3) having a smallest inner diameter. The adjacent nozzle tubes (1) are spaced apart by a distance such that the adjacent inlet-side opening sections (2) overlap each other. A wall (5) of an overlapping portion (6) of the inlet-side opening sections (2) is cut in a U shape. An uncut portion (5a) between the adjacent U-shaped cut portions (5b) forms a sword-like pointed tip.