The present invention relates to a method and apparatus for providing a dynamic decision-making process in relation to feeding animals in water. More particularly, the present invention relates to a method and apparatus for improving feeding and/or farming strategies used in a fish farm. According to a first aspect, there is provided a computer-implemented method for feeding one or more aquatic animals, the method comprising the steps of: receiving pre-processed sensor data in relation to the one or more aquatic animals; inputting the pre-processed sensor data into one or more learned decision-making models, wherein the one or more learned decision-making models has been trained to substantially optimise the rate and amount of food provided to the aquatic animals; determining, by the one or more learned decision-making models using the received pre-processed sensor data, feeding instructions for the one or more aquatic animals; and outputting the feeding instructions from the one or more learned decision-making models.

A farming tank includes a closed, rigid shell generally containing a farming body for aquaculture animals such as fish or shellfish, the shell being essentially ellipsoidal or egg-shaped and arranged to have a generally vertical main axis, and at least one internal ballast tank is arranged within the shell and at an upper section of the shell. The ballast tank has a radially outer wall which follows along a higher-lying section of the shell or is formed by a high-lying section of the shell itself, and a ballast pump arranged to fill or empty the ballast tank partially or completely with water via a ballast water pipe.

A farming tank includes a closed, rigid shell generally containing a farming body for aquaculture animals such as fish or shellfish, the shell being essentially ellipsoidal or egg-shaped and arranged to have a generally vertical main axis, and at least one internal ballast tank is arranged within the shell and at an upper section of the shell. The ballast tank has a radially outer wall which follows along a higher-lying section of the shell or is formed by a high-lying section of the shell itself, and a ballast pump arranged to fill or empty the ballast tank partially or completely with water via a ballast water pipe.

An aquaculture system which has a pen, a control system, a water pumping mechanism coupled to the pen, and a set of buoyancy tanks coupled to the pen. The pen can be disposed in a body of water and at least temporarily stores aquatic animals during development. The control system receives electric power from a power source and provides electric power to the water pumping mechanism to provides a flow of water through the pen. A portion of the control system is in fluid communication with the set of buoyancy tanks and adjusts a volume of fluid in at least one buoyancy tank to move the pen from a first position in which the pen is partially submerged in the body of water to a second position in which the pen is fully submerged in the body of water.

An aquaculture system which has a pen, a control system, a water pumping mechanism coupled to the pen, and a set of buoyancy tanks coupled to the pen. The pen can be disposed in a body of water and at least temporarily stores aquatic animals during development. The control system receives electric power from a power source and provides electric power to the water pumping mechanism to provides a flow of water through the pen. A portion of the control system is in fluid communication with the set of buoyancy tanks and adjusts a volume of fluid in at least one buoyancy tank to move the pen from a first position in which the pen is partially submerged in the body of water to a second position in which the pen is fully submerged in the body of water.

The present invention provides an eco-friendly underwater buoy and a manufacturing method therefor, the underwater buoy comprising: a liner main body of which the inside is hollow; a winding member which is melt welded on the outer surface of the liner main body by winding, and which absorbs external shock; and buoy couplers embedded in both ends of the liner main body so as to couple adjacent underwater buoys to each other. The present invention winds, through filament winding, a wire, in which a glass fiber, a resin and the like are mixed, around the outside of a liner structure so as to manufacture an underwater buoy, and thus, since the underwater buoy is made of a composite material, the appearance of the buoy structure can be stably maintained for a long time without damage caused by various underwater shocks, so that underwater environmental pollution caused by buoy structure damage can be minimized, thereby maximizing the eco-friendliness of the underwater buoy.

A movable aquafarming system is provided, including a vessel and a plurality of connected fish pens. The plurality of fish pens are arranged in a line, with a first fish pen of the plurality of fish pens being disposed closest to the vessel. The vessel is configured to be moored, and when moored the first fish pen is attached proximate to the vessel, and when the vessel is not moored the first fish pen is configured to attach to the vessel with a length of a tow line, whereby the vessel can tow the plurality of fish pens to a different location.

An edge finishing for a mesh formed by interlacing adjacent wire pickets, each picket formed in a zig-zag manner, the edge finishing comprising two interlinked loops where a first loop is formed from a first picket of the adjacent pickets and a second loop is formed from a second picket of the adjacent pickets, wherein the first loop and the second loop are interlocked together, via first and second loop-ends, at an intersection of the first picket and the second picket.

An edge finishing for a mesh formed by interlacing adjacent wire pickets, each picket formed in a zig-zag manner, the edge finishing comprising two interlinked loops where a first loop is formed from a first picket of the adjacent pickets and a second loop is formed from a second picket of the adjacent pickets, wherein the first loop and the second loop are interlocked together, via first and second loop-ends, at an intersection of the first picket and the second picket.

A tank for farming of marine organisms is described, where the tank includes a main chamber to hold the marine organisms and where the tank has further chambers to treat the water before it is circulated back to the main chamber.