An outboard motor for a marine vessel application, and related methods of making and operating same, are disclosed herein. In at least one embodiment, the outboard motor includes a horizontal-crankshaft engine in an upper portion of the outboard motor, positioned substantially positioned above a trimming axis of the outboard motor. In at least another embodiment, first, second and third transmission devices are employed to transmit rotational power from the engine to one or more propellers at a lower portion of the outboard motor. In at least a further embodiment, the outboard motor is made to include a rigid interior assembly formed by the engine, multiple transmission devices, and a further structural component. In further embodiments, the outboard motor includes numerous cooling, exhaust, and/or oil system components, as well as other transmission features.

A system for securing a submerged buoy including a signalling element floating on the surface and connected to the buoy by a link, said securing system being wherein it includes a reversible coupling device comprising an attachment member secured to the end of the link opposite the signalling element, a complementary attachment member rigidly connected to the buoy and capable of engaging with said attachment member in order to allow the link to be secured to or released from the buoy, a pressure sensor, a control unit associated with a timemeasurement unit, said control unit ordering said complementary attachment member to separate from said attachment member when a pressure variation, measured by associating said pressure sensor and said time-measurement unit, is higher than a set value.

A fishing pole caddy includes two or more risers arranged in parallel and multiple semicylindrical trays mounted perpendicular to the risers. The risers each have a first and a second attachment side and a base plate at one end from which a male coupling member extends to vertically attach the risers to a gunnel of a boat. The trays bear a fishing pole in a horizontal position. A customizable caddy includes a framework to which about four to sixteen adjustable length tubular housings are removably mounted. The framework includes a first and a second base plate with vertically extending risers. Each housing is perpendicular to the risers and has a longitudinal gap for a horizontally oriented fishing pole. Each housing extends from beneath the pole and rises to a longitudinal lip aligned with an upper portion of the pole. The caddy allows tangle-free storage and transport of fishing poles.

A position controller for electronically monitoring the position and speed of a dredge. The position controller consists of an electric powered line winding spool with an electric encoder to indicate line speed and position to a microprocessor. A drag control assembly with electric control is used to increase, decrease or set the drag at desired setting by microprocessor control. Touch screen microprocessor interface is the preferred method to enter settings into the system and allow display/control through multiple preexisting marine electronic devices throughout a fishing boat.

A position controller for electronically monitoring the position and speed of a dredge. The position controller consists of an electric powered line winding spool with an electric encoder to indicate line speed and position to a microprocessor. A drag control assembly with electric control is used to increase, decrease or set the drag at desired setting by microprocessor control. Touch screen microprocessor interface is the preferred method to enter settings into the system and allow display/control through multiple preexisting marine electronic devices throughout a fishing boat.

A posture control system for a hull, and a marine vessel including the posture control system, allows crew members to fish more comfortably and includes a posture control tab attached to a stern of the hull to control a posture of the hull, a driver to drive the posture control tab, and a controller to control the driver. When it is determined that the hull has changed to a fishing mode, the controller causes the driver to raise the posture control tab to a predetermined position.

This publication relates to a system and a method for hauling fish gear, such as longlines, gillnets or demersal seine nets, into a fishing vessel (10) and collecting and transporting catch (12) to a working station, using a hatch (16) in a part of a hull exposed to the sea and arranged in a water line region (27) of the vessel (10); a vertical well (18) for receipt of at least pa rt of the catch through the hatch (16); a transport device for transporting the catch to the deck; and with means for bringing the catch to flow towards the transport device. The transport device (24,25) used is arranged in a shaft (19), separated from the well (18), and a closeable opening or hatch (23) is arranged in a wall or bulkhead (21) between the well (18) and the shaft (19) 127 and with devices for opening and closing the opening or hatch (23), and a bottom (22) in the shaft (19).

This publication relates to a system and a method for hauling fish gear, such as longlines, gillnets or demersal seine nets, into a fishing vessel (10) and collecting and transporting catch (12) to a working station, using a hatch (16) in a part of a hull exposed to the sea and arranged in a water line region (27) of the vessel (10); a vertical well (18) for receipt of at least pa rt of the catch through the hatch (16); a transport device for transporting the catch to the deck; and with means for bringing the catch to flow towards the transport device. The transport device (24,25) used is arranged in a shaft (19), separated from the well (18), and a closeable opening or hatch (23) is arranged in a wall or bulkhead (21) between the well (18) and the shaft (19) 127 and with devices for opening and closing the opening or hatch (23), and a bottom (22) in the shaft (19).

An aquatic system configured for suspending a structure (2; 9; 20; 21) in a body of water (W), comprising at least two buoyancy control arrangements (15) configured for connection to the structure (2; 9; 20; 21) and to a seabed (B) below the body of water (W). The structure (2; 9; 20; 21) is moored to the seabed (B) via the at least two buoyancy control arrangements (15). Each buoyancy control arrangement (15) comprising a first buoyancy device (4) and a second buoyancy device (3), the buoyancy of each of the first buoyancy devices (4) and each of the second buoyancy devices (3) is independently controllable in order to adjust the vertical and horizontal position of the structure (2; 9; 20; 21) and vertical and horizontal restoring capacity of the aquatic system in the body of water (W).

An aquatic system configured for suspending a structure (2; 9; 20; 21) in a body of water (W), comprising at least two buoyancy control arrangements (15) configured for connection to the structure (2; 9; 20; 21) and to a seabed (B) below the body of water (W). The structure (2; 9; 20; 21) is moored to the seabed (B) via the at least two buoyancy control arrangements (15). Each buoyancy control arrangement (15) comprising a first buoyancy device (4) and a second buoyancy device (3), the buoyancy of each of the first buoyancy devices (4) and each of the second buoyancy devices (3) is independently controllable in order to adjust the vertical and horizontal position of the structure (2; 9; 20; 21) and vertical and horizontal restoring capacity of the aquatic system in the body of water (W).