The system, apparatus and method of the present invention provides for the cultivation of shellfish in subtidal environments. A key aspect of the invention is the use of specially configured baskets, into which the shellfish to be grown is seeded. In particular, the baskets are configured with a support bracket through which a cable passes. The mounting of the support bracket permits the rotation of the basket and allows a shellfish cultivator to replicate the growing conditions of intertidal ecosystems despite the invention being used in a subtidal environment.

The system, apparatus and method of the present invention provides for the cultivation of shellfish in subtidal environments. A key aspect of the invention is the use of specially configured baskets, into which the shellfish to be grown is seeded. In particular, the baskets are configured with a support bracket through which a cable passes. The mounting of the support bracket permits the rotation of the basket and allows a shellfish cultivator to replicate the growing conditions of intertidal ecosystems despite the invention being used in a subtidal environment.

An aquaculture system can include an aquafarm with one or more aquatic pods of aquatic organisms and a remote device to manage the aquafarm. An aquatic pod may be associated with an aquatic structure with a buoyancy system and a control device to automatically perform daily farming functions. The aquatic structure may include an enclosure to hold the aquatic organisms. The control device may be configured to use a smart buoyancy assistant to control the buoyancy system and to determine the farming task to perform in response to environmental stimuli. The remote device can receive data representing crop metrics, harvest results, and sensor data. The remote device can aggregate data from multiple aquatic pods and correlate the data to generate aquaculture models to improve the harvest results. The remote device can generate overview and maintenance reports for the aquafarm.

A system for cultivating a large quantity of oysters is disclosed herein. The system includes a device that can be placed either on the seabed or the surface of a water environment. The device may be placed at either location and may also be placed further offshore and still be safe from extreme weather conditions. As a result, the benefits of each location are implemented into the system. The system includes an oyster cultivating device including a rectangular frame holding various crates with multiple internal baffles or dividers, and an attached buoyant member for keeping the cultivating frame at or near the surface of the water. The crates are placed such that they fill the volume within the rectangular frame. A buoyant member is then placed on the top end of the rectangular frame. The system provides increased agitation capabilities for oysters to provide a larger and rounder cultivated oyster.

A system for cultivating a large quantity of oysters is disclosed herein. The system includes a device that can be placed either on the seabed or the surface of a water environment. The device may be placed at either location and may also be placed further offshore and still be safe from extreme weather conditions. As a result, the benefits of each location are implemented into the system. The system includes an oyster cultivating device including a rectangular frame holding various crates with multiple internal baffles or dividers, and an attached buoyant member for keeping the cultivating frame at or near the surface of the water. The crates are placed such that they fill the volume within the rectangular frame. A buoyant member is then placed on the top end of the rectangular frame. The system provides increased agitation capabilities for oysters to provide a larger and rounder cultivated oyster.

An oyster farming device comprising containers configured to contain oysters and linked to at least one ballast. The device comprises a horizontal pivot axis, parallel to a longitudinal direction, and at least two rigid arms that ling the pivot axis and the ballast, parallel to the longitudinal direction, such that the filling or emptying of the ballast causes the arm to rotate about the pivot axis and results in the emergence and rolling of the oysters in the containers.

An oyster farming device comprising containers configured to contain oysters and linked to at least one ballast. The device comprises a horizontal pivot axis, parallel to a longitudinal direction, and at least two rigid arms that ling the pivot axis and the ballast, parallel to the longitudinal direction, such that the filling or emptying of the ballast causes the arm to rotate about the pivot axis and results in the emergence and rolling of the oysters in the containers.

A method for polycultivating clams with oysters in subtidal zones in an oyster growing-out bag at a low density, then placing the bags in the upper layer of the water by floating system including floating cage or floats. The clam could be Mya arenaria, and all other economic bivalve species that require burrowing in sand to ensure their growth.

A method for polycultivating clams with oysters in subtidal zones in an oyster growing-out bag at a low density, then placing the bags in the upper layer of the water by floating system including floating cage or floats. The clam could be Mya arenaria, and all other economic bivalve species that require burrowing in sand to ensure their growth.

The system, apparatus and method of the present invention provides for the cultivation of shellfish in subtidal environments. A key aspect of the invention is the use of specially configured baskets, into which the shellfish to be grown is seeded. In particular, the baskets are configured with a support bracket through which a cable passes. The mounting of the support bracket permits the rotation of the basket and allows a shellfish cultivator to replicate the growing conditions of intertidal ecosystems despite the invention being used in a subtidal environment.