A method for controlling steering alignment in a marine vessel includes detecting a rotational position of a steering device and detecting a rotational addition of a steerable component, wherein the steerable component is couplable to a marine vessel and steerable to a plurality of positions so as to vary the direction of movement of the marine vessel. The rotational position of the steering device and the rotational position of the steerable component are then compared. The operation between the steering device and the steerable component is then automatically adjusted while the steering device is moved by a user until alignment between the steering device and the steerable component is reached.

A controller receives a signal indicating an operating amount and an operating direction of a steering member. When the operating amount of the steering member is greater than or equal to a steering threshold, the controller causes right and left propulsion devices to generate thrusts oriented in opposite directions in a back-and-forth direction such that a vessel body is turned in a corresponding direction to the operating direction of the steering member.

A hydraulic steering system for vehicles includes a steering control member; a hydraulic pump provided with a rotatable driving shaft on which the control member is fitted; a hydraulic actuating cylinder connected with two ports of the pump alternately operating as delivery side and return side of the pump and mechanically connected with a direction changing member, which determines a change in the direction by modifying orientation via an actuating cylinder as a function of the supply of hydraulic fluid to the cylinder from the pump by the steering control member. The driving shaft is dynamically connected with an electric motor/transmission assembly, which is activated alternatively by generating a rotational force auxiliary to the movement manually exerted on the steering control member or opposing the manually exerted movement, or by driving to rotate the driving shaft of the pump in place of the manual action driving the steering control member.

A boat includes: a propulsion device configured to generate propulsion force for a vessel body from driving force from an engine; a detection unit configured to detect a current position, a bow direction, and a movement speed of the vessel body; a steering device configured to change a cruising direction of the vessel body; a steering sensor configured to detect an operation amount of the steering device; and a control device that is connected to the propulsion device, the detection unit, and the steering sensor, and is configured to acquire an operating status of the propulsion device and a detection result obtained by the detection unit and the steering sensor, and to control the propulsion device based on the detection result. The control device executes a turning operation with the propulsion device, when the operation amount of the steering device detected by the steering sensor exceeds a threshold.

The invention relates to a steering control device for boats that includes a drive shaft, the rotation of which in one direction or in the opposite direction, by way of a control member, such as a steering wheel or helm mounted or mountable thereon, causes a steering input for an outboard motor or rudder. The steering input is generated by a transmission member, housed into a case, configured to transmit the rotational motion of the shaft to an actuator, associated or associable to the motor or rudder, through a transmission circuit. The device includes a first stationary part configured to be fastened on the bridge of the boat and a second movable part integral with the case of the transmission member. The drive shaft and the transmission member are coupled such that the change in the tilt of the shaft by a given angle causes a change in the tilt of the transmission member by the same angle with a corresponding change in the tilt of the case of the transmission member with respect to the stationary part of the device.

A system and method are for controlling handling of a marine vessel having a steerable component that is steerable to a plurality of positions to vary a direction of movement of the vessel. A controller is communicatively connected to an actuator of the steerable component and a user input device provides to the controller an operator-initiated steering command to steer the steerable component to one of the plurality of positions. A sensor provides to the controller an indication of an undesired course change of the marine vessel. The controller has a vessel direction control section that outputs a command to the actuator to change a position of the steerable component from the one of the plurality of positions so as to automatically counteract the undesired course change. The vessel direction control section is active only when the operator-initiated steering command is less than or equal to a predetermined threshold.

A method of controlling a steering system on a marine vessel includes, in response to receiving a user input to engage a quick steer mode, employing a reduced steering ratio to translate positions of a steering wheel to desired steering angles of a marine drive. A vessel speed of a marine vessel is determined and then compared to a threshold vessel speed. An output limit is determined to prevent the marine vessel from further exceeding the threshold vessel speed while the quick steer mode is engaged. The marine drive is automatically controlled based on the output limit and a steering actuator associated with the marine drive is controlled based on the reduced steering ratio.

A method for positioning two or more trimmable marine propulsion devices coupled to a transom of a marine vessel includes identifying two propulsion devices located one on each of a port side and a starboard side of a centerline of the transom and spaced symmetrically with respect to the centerline. The two propulsion devices are defined as a first set and are associated with a first target trim position. The method also includes defining a second set of propulsion devices and associating the second set with a second target trim position. When in auto-trim mode, each propulsion device in a set of propulsion devices is actuated to its target trim position only if the actual trim positions of all propulsion devices in the set differ from the target trim position by at least a given amount. The propulsion devices may be actuated individually in response to a user sync command.

A steering device includes a sensor and a rotor, each of which rotates together with a steering wheel around a rotational axis, and a stator whose position in a circumferential direction is stationary. The steering device includes a harness that connects a target component and the sensor together, a first fastener that fixes the harness to the rotor, and a second fastener that fixes the harness to the stator. An intermediate portion between the first fastener and the second fastener in the harness includes a first extension and a second extension each of which extends along the circumferential direction and a connector that connects the first extension and the second extension together.

A boat maneuvering support device supports maneuvering of a boat including a first propulsion device having a variable turning angle, a second propulsion device for generating a propulsive force for moving the boat in a left-right direction, and a steering mechanism for changing a turning angle of the first propulsion device and an output of the second propulsion device. The boat maneuvering support device includes a control unit which controls the turning angle of the first propulsion device and/or the output of the second propulsion device, a detection unit which detects a rotational speed of a propeller of the first propulsion device, and a calculation unit which obtains a rotational power of the boat based on the turning angle designated by the operation of the steering mechanism and the rotational speed. The control unit controls the output of the second propulsion device based on the rotational power.