An electromechanical lockout device for a remote control on a marine vessel includes an electric actuator and a locking pin having an engagement end and a second end. The locking pin is arranged with respect to a control lever such that the locking pin is positionable in a locked position, where the engagement end of the locking pin prevents rotation of the control lever into a reverse position, and in a retracted position, where the engagement end of the locking pin allows rotation of the control lever into the reverse position. A method of controlling lockout for a remote control includes sensing a position of a control lever, calculating a rate of change of the position, and engaging a lockout to prevent a gear system from shifting into reverse gear if the rate of change exceeds a threshold rate of change.

A control device for controlling an electric motor. The control device includes a twist grip that is rotatably mounted on a carrier such that the twist grip is user-twistable in a first direction from a neutral position to a first operating position, and in a second direction from the neutral position to a second operating position. The control device further includes a force element for producing a return force. The force element operatively couples to the twist grip via a force transmission element and at least one deflection element such that the force element applies the return force to the twist grip thereby twisting the twist grip to the neutral position.

An outboard motor is provided with: an encoder which detects the rotational speed of an engine; a position sensor which detects an operating position of a shift lever; and a state quantity detection unit which detects a state quantity of a shift actuator. A control device of the outboard motor determines whether the state quantity is more than or equal to a stop-initiating threshold value when the operating position has been switched. If the state quantity is more than or equal to the stop-initiating threshold value, the control device implements a stop control to stop ignition and/or fuel injection in the engine.

A tiller is for an outboard motor. The tiller has a base bracket that is configured to be rotationally fixed with respect to the outboard motor, a chassis bracket that is coupled to the base bracket, and a locking arrangement. The locking arrangement is movable into and between a locked position, wherein the chassis bracket is locked to and rotates together with the base bracket, and an unlocked position, wherein the chassis bracket is freely rotatable with respect to the base bracket about a vertical axis when the tiller is in a horizontal position.

A tiller is for an outboard motor. The tiller comprises a supporting chassis having a first end and an opposite, second end. A rotatable throttle grip is supported on the first end and a pivot joint is located at the second end. The pivot joint is configured to facilitate pivoting of the tiller at least into and between a horizontal position wherein the supporting chassis extends horizontally and a vertical position wherein the supporting chassis extends vertically. A top cover is located on the supporting chassis. The top cover and the supporting chassis together define an interior of the tiller. The top cover is located vertically on top of the supporting chassis when the tiller is in the horizontal position.

A system for controlling a marine vessel having first and second waterjets, corresponding first and second steering nozzles and corresponding first and second reversing buckets. The system comprises a speed control device for providing a first vessel control signal that corresponds to a speed to be provided to the marine vessel, a processor configured to receive the first vessel control signal and that is configured to provide at least one first actuator control signal coupled to the first and second waterjets, and at least one second actuator control signal coupled to the first and second steering nozzles and the first and second reversing buckets. The system any of improves upon turns provided by conventional waterjet propulsion systems, improves upon slowing down or stopping marine vessels as is done by conventional waterjet propulsion systems, and improves upon the controllability of the waterjet propulsed marine vessel at low vessel speeds.

Control device for generating auxiliary controls for a boat for controlling and regulating a boat handling auxiliary functionality, including an intermediate switch, changeover switch, or switch device located below the steering control member of the boat, which is connected to a drive unit for a steering actuator through a drive shaft; and a housing case shaped as an arm having at one end a member controlling the control device, which is provided with a terminal removably fastening alternatively to the casing holding the drive unit for the steering actuator, to a part thereof, or to a wall of a bridge or of a dashboard adjacently to the region for mounting the casing holding the drive unit for the steering actuator to the bridge or to the dashboard.

One embodiment of the invention comprises a method for controlling a marine vessel having a first steerable propulsor, a corresponding first reversing device, a second steerable propulsor and a corresponding second reversing device. The method comprises receiving a first vessel control signal corresponding to a rotational movement and no translational movement command, generating at least a first actuator control signal and a second actuator control signal in response to the first vessel control signal, coupling the first actuator control signal to and controlling the first steerable propulsor and the second steerable propulsor, and coupling the second actuator control signal to and controlling the first reversing device and to the second reversing device. The method creates rotational forces on the marine vessel with substantially no translational forces on the marine vessel.

The present invention relates to a device (1) for setting the drive position of an electric drive of a boat, having a housing (14) with two receiving elements (15a, 15b) arranged on two opposing side walls (140) of the housing (14) for defining a pivot axis (17) and a drive lever (10) that can be pivoted around this pivot axis (17), wherein the drive lever (10) is received by two receiving elements (15a. 15b).

Disclosed is a method for controlling a hydrofoil board powered by a motor driven propeller. The motor is controlled by a hand controller configured with user selectable operating pre-sets including a first operating pre-set, wherein the board is accelerated to a first speed which is less than that required for the board to hydrofoil, and a second operating pre-set, wherein the board is accelerated to a second speed sufficient for the board to hydrofoil. Alternatively, the operating pre-sets may limit the motor power. A system for operating a hydrofoil board is also disclosed, which includes a propulsion control unit comprising a propulsion source, and a hand controller configured to receive a first user input and a second user input and to transmit the user inputs to the propulsion control unit.