The invention relates to an inductive power transfer device (10) for an inductive power transfer to a water-bound vehicle (60), with: —a power transfer part (12), comprising a primary conductor arrangement (54); and —a kinematic unit (14) for enabling a movement of the power transfer part (12); wherein the kinematic unit (14) comprises a linear guide (24) which is oriented so that, when the power transfer part (12) is displaced along a path (28) defined by the linear guide (24), a position of the power transfer part (12) along a vertical spatial axis (Z) is altered. Further, the invention relates to a system (1) for an inductive power transfer to a water-bound vehicle (60) and a method for operating an inductive power transfer device (10).

A docking/charging module for an undersea autonomous vehicle comprises a housing allowing the undersea autonomous vehicle to dock, thereby establishing both a data connection and a power connection between the module and the vehicle, the module being equipped with the battery which is charged from an undersea cable having a power conductor which may charge the undersea autonomous vehicle via the power connection when the undersea autonomous vehicle is docked with or in proximity to the docking/charging module.

There are provided a method and a device for feeding electric power to a vehicle, etc. installed with a solar photovoltaic power generation panel employing a multi-junction solar cell in a non-contact manner by irradiating light to the solar photovoltaic power generation panel. In the method, light containing a wavelength component absorbed by each of all solar cell layers laminated in a multi-junction solar cell of the vehicle, etc. is projected from a light-projecting device to the light receiving surface of the multi-junction solar cell; and electric power generated by the irradiation of light from the multi-junction solar cell is taken out. The device includes structures for emitting light containing a wavelength component absorbed by each solar cell layer laminated in the multi-junction solar cell, and for irradiating the light to a light receiving surface of the multi-junction solar cell.

A redundant power supply network includes an alternating voltage network and a first incoming-feed power converter with a first dc link and a second incoming-feed power converter with a second dc link. The first and second incoming-feed power converters are each connected on an alternating voltage side with the alternating voltage network. A first power source is connected to the first dc link and a second power source is connected to the second dc link. A mains switch is arranged between the first incoming-feed power converter and the alternating voltage network, and a dc link switch connects the first and second dc links. A connection to a terminal for an external network is arranged between the first incoming-feed power converter and the mains switch.

A system includes a source configured to provide power to a medium-voltage direct current (MVDC) bus. The system also includes a plurality of rotating electrical machines configured to receive the power from the MVDC bus. The rotating electrical machines are arranged in a cascaded configuration. One of the rotating electrical machines is configured to act as a slave to another of the rotating electrical machines. Each rotating electrical machine is mechanically connected to an inertial energy storage. The system further includes a plurality of isolated battery or ultra-capacitor subsystems electrically connected to each rotating electrical machine. The battery or ultra-capacitor subsystems are configured to receive electrical energy from and provide electrical energy to each rotating electrical machine and the connected inertial energy storage.

An energy supply system for a water-bound device and in particular to a corresponding method, including: a first DC voltage bus for a first DC voltage; a second DC voltage bus for a second DC voltage; and a first energy source which has at least two supplying electrical connections to the DC voltage buses, wherein at least one of the DC voltage buses has sections.

Systems, assemblies, and methods for operating a marine motor are provided herein. An example motor system includes a motor, a battery, and a processor. The processor is configured to receive a user input indicating a desired speed, determine a charge level of the battery, determine an optimized speed or propulsion of the marine motor based on the desired speed and the determined charge level of the battery, and transmit a signal to the motor to operate accordingly. The processor may generate a correction factor based on at least one of the determined charge level of the battery, a boat speed profile curve, and a boat travel distance curve; and determine the optimized speed or propulsion by applying the correction factor to the desired speed. Thus, an eco-mode can be provided to help maintain a high level of battery charge while still enabling desired use.

A fast charging station for a marine vessel battery on a marine vessel is provided. The fast charging station includes a dock battery, a charger that is operatively coupled to a power source and the dock battery, and an enclosure located on a dock structure in a body of water. The enclosure is configured to encapsulate the dock battery and the charger. The charger is configured to charge the dock battery using the power source when the marine vessel is not docked to the dock structure. The charger is further configured to charge the marine vessel battery using the power source and the dock battery when the marine vessel is docked to the dock structure.

Electrical power systems and methods of controlling electrical power systems are described. One such electrical power system comprises: a first ac bus and a first generator set configured to supply the first ac bus with ac electrical power; a second ac bus and a second generator set, configured to supply the second ac bus with ac electrical power; an interconnecting transformer connected between the first and second ac busses; a primary electrical load connected to both the first and second ac busses via a converter arrangement; an auxiliary load connected to the first ac bus; and a controller configured to control the first generator set according to a first droop control profile and to control the second generator set according to a second droop control profile, the first and second droop control profiles relating respective generator operating frequencies of the first and second generator sets to respective output powers of the first and second generator sets.

A subsea AC power supply device comprises a subsea transformer, having a primary winding arranged to be connected to a topside AC power supply via a subsea power supply cable, and a subsea shunt reactor, connected in parallel with the primary winding of the subsea transformer. The subsea transformer and the subsea shunt reactor are arranged within a common subsea watertight housing. A subsea AC power supply system comprises a topside AC power supply, a subsea power supply cable connected to the topside AC power supply, and a subsea AC power supply device connected to the subsea power supply cable.