A power surfboard includes a surfboard body defining a first side, a supporting piece including at least one first fastener, and a power assembly. An accommodating groove is defined on the first side of the surfboard body. The supporting piece is arranged in the accommodating groove. The power assembly includes a power housing, an operating assembly, and a power source. The operating assembly includes an operating body, at least one second fastener connected to inner side walls of the operating body, and at least one operating piece arranged on the operating body. The power assembly is detachably arranged in the accommodating groove. When each operating piece is in a first state, each second fastener is connected to a corresponding first fastener. When each operating piece is in a second state, each second fastener is separated from the corresponding first fastener.

A power system for a marine vessel comprises an engine and a controllable pitch thruster drivably coupled to the engine. A speed of the controllable pitch thruster various with a speed of the engine. A control unit receives a thrust command value indicating a thrust required from controllable pitch thruster. The control unit determines a current speed of the controllable pitch thruster and calculates a pitch of the controllable pitch thruster that produces thrust in accordance with the thrust command value at the current speed of the controllable pitch thruster. The power system allows for operating the engine at variable speeds to allow for a reduction of the engine speed under partial load conditions.

A system for limiting power to a plurality of on-line consumers includes an operating characteristic sensor associated with each of a plurality of prime movers and a controller. The controller is configured to determine a maximum torque capability of each of the plurality of prime movers, determine the available electrical power response of each of the plurality of generators, determine a total available electrical power response, and determine a total maximum power demand. The controller then compares the total available electrical power response to the total maximum power demand, and upon the total maximum power demand exceeding the total available electrical power response, limits power to the plurality of on-line consumers to no more than the total available electrical power response.

Structures, systems and methods are disclosed for navigating a vessel, typically through the waterways of a single urban region (e.g., San Francisco Bay), that can be used as a floating structure for residences or offices, for independent parties. Also disclosed are structures, systems and methods for navigating such a vessel that minimize energy use while satisfying the logistical needs of parties using the vessel, as well as satisfying laws that restrict the movement and location of navigable structures. Also disclosed are structures, systems and methods for navigating such a vessel that satisfy laws that regulate the environmental impact of a such vessel, and that ensures the safety and health of people using this vessel.

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.

A motorized board similar to a surf board is presented for use on a water surface. The motorized board includes a base board having a front end and a back end, a foot pedal on the base board, wherein the foot pedal is rotatable on the base board, and a motor coupled to the base board and connected to a propeller at the back end, the motor being controlled by the foot pedal. A user can stand on the board and turn the motor on with his foot, as well as control the speed with his foot to ride on a water surface with or without waves.

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.

This automatic setting device for automatically setting control devices for a plurality of ship propulsion apparatuses for generating ship propulsion forces is provided with: an input operation setting unit that sets an input operation for a ship; a target behavior acquisition unit that acquires a target behavior of the ship corresponding to the input operation set by the input operation setting unit; a ship information acquisition unit that acquires ship information about the position and/or the bearing of the ship; an actual behavior calculation unit that calculates the actual behavior of the ship on the basis of the ship information acquired by the ship information acquisition unit; and a propulsion force setting unit that sets the magnitudes and the directions of the propulsion forces generated by the respective ship propulsion apparatuses on the basis of the actual behavior of the ship acquired by the actual behavior calculation unit and the target behavior of the ship acquired by the target behavior acquisition unit.

A marine propulsion system includes a marine propulsion device, a battery, and a controller. The marine propulsion device includes a propeller shaft, an engine, and an electric motor. The marine propulsion device transmits mechanical power from at least one of the engine and the electric motor to the propeller shaft. The battery supplies electric power to the electric motor. The controller controls the marine propulsion device such that the marine propulsion device is switchable among drive modes including a first drive mode and a second drive mode. In the first drive mode, mechanical power is transmitted from only the engine to the propeller shaft. In the second drive mode, mechanical power is transmitted from only the electric motor to the propeller shaft when the engine is in an idling state.

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).