A method and an apparatus are capable of automatically performing an operation of mounting shellfishes to a pin inserted in a vertical rope. Insertion holes are formed in ears of two shellfishes in parallel. While each pin is cut out one by one from a series of pins formed of a large number of continuous pins, the cut-out pins are inserted through the vertical rope at substantially equal intervals. A pipe-shaped guide is inserted through the insertion hole of each of the two shellfishes, and an end portion of the guide inserted through the insertion hole is put on each end portion of the pin. The pin and the two guides are arranged in a straight line. The shellfishes are transferred and mounted onto the pin by sliding the two shellfishes along the respective guides beyond shellfish locking protrusions of the pin.

The present invention is an anchor for an artificial structure for attracting fish within a body of water. The structure is comprised of a base and has a central attachment post, a central column configured to secure to the attachment post, and a protective plate.

A water treatment and recirculation system includes means to transport water flows at required pressures, a mechanical filter of approximately 100 microns to capture coarse particles, oxygen production means, autonomous electricity generation means, and variable control means using a PLC that administers parameters such as pressure, oxygen and CO.sub.2 levels, flows, pH, etc. The system also includes means to ultrafilter and remove particles of up to 0.02 microns, the purpose being removing organic material macromolecules, disinfecting bacteria and viruses with mechanical removal, and eliminate harmful contaminants such as ammonia, degasifying means to eliminate CO.sub.2 with a multitubular exchanger with membranes made of hydrophobic materials and micro perforations to take CO.sub.2 away to an extraction gas in atmospheric or vacuum conditions; and means to oxygenate water with a multitubular exchanger having membranes constituted by hydrophobic materials and microperforations that inject O.sub.2 into water of a gas under atmospheric conditions.

Embodiments of the present disclosure describe an aquaculture environment control system comprising one or more control apparatuses positioned within a vessel at an angle relative to a proximal vessel wall and configured for scouring of the vessel, wherein each control apparatus has a discharge conduit and each discharge conduit has one or more orifices; and a fluid source in fluid communication with each of the control apparatuses. Embodiments of the present disclosure describe a method of controlling an aquaculture environment comprising supplying one or more of a fluid and gas to a control apparatus positioned within a vessel at an angle relative to a proximal vessel wall; and discharging one or more of the fluid and gas from the control apparatus at a fluid velocity sufficient for scouring of the vessel.

Embodiments of the present disclosure describe an aquaculture environment control system comprising one or more control apparatuses positioned within a vessel at an angle relative to a proximal vessel wall and configured for scouring of the vessel, wherein each control apparatus has a discharge conduit and each discharge conduit has one or more orifices; and a fluid source in fluid communication with each of the control apparatuses. Embodiments of the present disclosure describe a method of controlling an aquaculture environment comprising supplying one or more of a fluid and gas to a control apparatus positioned within a vessel at an angle relative to a proximal vessel wall; and discharging one or more of the fluid and gas from the control apparatus at a fluid velocity sufficient for scouring of the vessel.

Provided is an aquaculture system, including a water tank holding seawater and housing shellfish or fish to be cultivated, a water intake unit for introducing the seawater into the water tank, a draining unit for draining the seawater in the water tank, a first bubble generator that generates and supplies microbubbles with a diameter of not less than 10 m and not more than 100 m in the water tank, and a second bubble generator that generates and supplies nanobubbles with a diameter of not more than 10 m in the water tank, wherein the seawater in the water tank is exchanged by simultaneously carrying out introduction of the seawater using the water intake unit and drainage of the seawater in the water tank using the draining unit.

System and methods for monitoring the growth of an aquatic plant culture and detecting real-time characteristics associated with the aquatic plant culture aquatic plants. The systems and methods may include a control unit configured to perform an analysis of at least one image of an aquatic plant culture. The analysis may include processing at least one collected image to determine at least one physical characteristic or state of an aquatic plant culture. Systems and methods for distributing aquatic plant cultures are also provided. The distribution systems and methods may track and control the distribution of an aquatic plant culture based on information received from various sources. Systems and methods for growing and harvesting aquatic plants in a controlled and compact environment are also provided. The systems may include a bioreactor having a plurality of vertically stacked modules designed to contain the aquatic plants and a liquid growth medium.

System and methods for monitoring the growth of an aquatic plant culture and detecting real-time characteristics associated with the aquatic plant culture aquatic plants. The systems and methods may include a control unit configured to perform an analysis of at least one image of an aquatic plant culture. The analysis may include processing at least one collected image to determine at least one physical characteristic or state of an aquatic plant culture. Systems and methods for distributing aquatic plant cultures are also provided. The distribution systems and methods may track and control the distribution of an aquatic plant culture based on information received from various sources. Systems and methods for growing and harvesting aquatic plants in a controlled and compact environment are also provided. The systems may include a bioreactor having a plurality of vertically stacked modules designed to contain the aquatic plants and a liquid growth medium.

Apparatus and methods for automatically feeding fish at predetermined intervals are disclosed herein. An automatic fish feeder can include a housing, at least one cover, a feeding track, and a valve. The housing can include a peripheral outer cover and at least one access hole. The food storage reservoir can be connected to the housing and configured to be accessible by an access hole. At least one cover can be removably attached to the peripheral outer cover and substantially seal the food storage reservoir. The feeding track can be coupleable to the food storage reservoir and configured to receive and distribute food from the food storage reservoir at individual rates. The valve can be coupleable to the feeding track and configured to control the flow of food from the feeding track. The valve can include a rod and a counter configured to move the rod relative to the feeding track.

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