An outboard motor includes: an outboard motor body including a propeller driven by an internal combustion engine; a mounting portion configured to mount the outboard motor body to a hull so as to be movable relative to the hull; and an operation mechanism provided between the outboard motor body and the mounting portion and configured to adjust a relative position of the outboard motor body with respect to the hull. The operation mechanism is a link-type operation mechanism including a hydraulic cylinder as an actuator.

An outboard motor includes an outboard motor main body, a support including a tilt shaft and that supports the outboard motor main body, and a trim cylinder including a first trim cylinder shaft disposed below the tilt shaft along an outer surface of a transom of a hull. A distance between the tilt shaft and the first trim cylinder shaft is adjustable.

An outboard motor includes an outboard motor main body, a support including a tilt shaft and that supports the outboard motor main body, and a trim cylinder including a first trim cylinder shaft disposed below the tilt shaft along an outer surface of a transom of a hull. A distance between the tilt shaft and the first trim cylinder shaft is adjustable.

A method of controlling tilt-trim position of a trimmable device on a marine vessel includes determining a trim rate based on rotational speed of a propulsion device on the marine vessel, the vessel speed of the marine vessel, the vessel pitch of the marine vessel, and/or the vessel acceleration of the marine vessel. The trim rate specifies a rate of rotation of the trimmable device about a horizontal axis, and the trim rate is determined such that the rate of rotation is minimized at high vessel speeds and high rotational speeds and the rate of rotation is maximized at low vessel speeds and low rotational speeds. A variable speed trim actuator is then controlled to rotate the trimmable device based on the trim rate so as to adjust a trim position of the trimmable device.

A method of controlling tilt-trim position of a trimmable device on a marine vessel includes determining a trim rate based on rotational speed of a propulsion device on the marine vessel, the vessel speed of the marine vessel, the vessel pitch of the marine vessel, and/or the vessel acceleration of the marine vessel. The trim rate specifies a rate of rotation of the trimmable device about a horizontal axis, and the trim rate is determined such that the rate of rotation is minimized at high vessel speeds and high rotational speeds and the rate of rotation is maximized at low vessel speeds and low rotational speeds. A variable speed trim actuator is then controlled to rotate the trimmable device based on the trim rate so as to adjust a trim position of the trimmable device.

A method of controlling at least one marine drive on a marine vessel includes determining that a trim position sensor has failed for a first marine drive, determining an allowable steering angle range for the first marine drive based on a first assumed trim position, and determining a steering position adjustment based on the allowable steering angle range. A steering actuator is controlled to automatically adjust the steering position of the marine drive based on the steering position adjustment. A trim position adjustment is determined based on a second assumed trim position for the marine drive and a trim actuator is controlled to adjust the trim position of the first marine drive based on the trim position adjustment.

A method of controlling at least one marine drive on a marine vessel includes determining that a trim position sensor has failed for a first marine drive, determining an allowable steering angle range for the first marine drive based on a first assumed trim position, and determining a steering position adjustment based on the allowable steering angle range. A steering actuator is controlled to automatically adjust the steering position of the marine drive based on the steering position adjustment. A trim position adjustment is determined based on a second assumed trim position for the marine drive and a trim actuator is controlled to adjust the trim position of the first marine drive based on the trim position adjustment.

According to at least one embodiment, an electric actuator for a marine steering system is disclosed. The electric actuator includes a housing, an output shaft, a screw assembly coupled to the output shaft, a rotor coupled to the screw assembly, and a motor configured to rotate the rotor. Rotation of the rotor causes the output shaft to translate axially relative to the housing.

According to at least one embodiment, an electric actuator for a marine steering system is disclosed. The electric actuator includes a housing, an output shaft, a screw assembly coupled to the output shaft, a rotor coupled to the screw assembly, and a motor configured to rotate the rotor. Rotation of the rotor causes the output shaft to translate axially relative to the housing.

The invention relates to a platform arrangement (110) mounted to a stern portion of a marine vessel (100). The platform arrangement comprises at least one first platform section (111) with a first transverse pivot joint (113) mounted adjacent a transom (105); at least one propulsion unit (101) mounted to a lower surface of the first platform section (111), wherein the at least one propulsion unit (101) and its first platform section (111) are tiltable between a drive position and an upwards tilted position. A second platform section (112) is located in front of the at least one first platform section (111), which second platform section (112) has a second transverse pivot joint (114) mounted adjoining the first transverse pivot joint (113) of a corresponding first platform section (111). The first and second platform sections (112) are foldable relative to each other about their respective first and second pivot joints (113; 114). The invention further relates to a vessel comprising the platform arrangement.