A system and method by which energy from ocean waves is converted into hydrogen, and that hydrogen is used to manifest electrical and mechanical energies by an energy consuming device. A portion of the generated electrical power is communicated to water electrolyzers which produce oxygen and hydrogen from water as gases. At least a portion of the generated hydrogen gas is transferred to a transportation ship via a hose-carrying, remotely operated (or otherwise unmanned) vehicle, and subsequently transferred to an energy-consuming module or infrastructure, where a portion of the hydrogen is consumed in order to manifest a generation of electrical energy, a mechanical motion, and/or a chemical reaction.

A method, system, and apparatus for managing variable, multi-phase on-site electric power and fluid conversion to output fuel and energy for providing customizable management for processing hydrogen-based fuels. In particular, the method, system and apparatus provide for automated feedback and control, directing inputs for conversion including electrolysis to create fuel products including gaseous hydrogen and liquid hydrogen to be used in clean-fuel vehicles onsite or transported to be used for vehicle delivery, according to settings or system parameters to meet demand quickly and efficiently for various products while making adjustments in real time.

The present invention belongs to the field of offshore wind power and, in particular, relates to system for transporting hydrogen produced from seawater and method based on an existing offshore wind power plant. The system comprises a wind generator, a seawater electrolytic cell device and a hydrogen transporting unit, wherein the wind generator is configured for converting wind energy into electric energy, the seawater electrolytic cell device is configured for electrolyzing seawater by making using of electric energy supplied by the wind generator and the hydrogen transporting unit is configured for transporting hydrogen produced by the seawater electrolytic cell device to a land. According to the present invention, by combining offshore wind power with seawater hydrogen production, resource advantages of the offshore wind power plant is utilized fully, so that the seawater hydrogen production cost is lowered.

Self-enabled means of sustainable energies generation and storage. Self-sufficiency in conversion of propulsion energies. Decarbonization of the global shipping industry. Empowering the blue ocean fleet of merchant liners with self-created propulsion power. Backed up by grid energy storage systems; and low carbon bunkers. To break free from the shackles of dirty energies; from being slaves of energy poverty. To achieve energy independence! Including: sustainable energies generation systems using wind-sails; pontoons; pliable; flexible semi-solid shrouds; made of plastics; polymers; etc. to capture fluids; channelling it through constricted tunnels to drive wind turbines; tidal turbines; etc. integrated with drones; robotic technologies for conversion into renewable electricity. An extremely scalable system, apparatus, equipment, techniques and ecosystem configured to produce renewable green energy with high productivity and efficiency.

The invention refers to a wind generator onboard of a road vehicle, the wind generator comprising: at least one wind wheel which is mounted onboard of a road vehicle to be rotatable around a rotational axis, the at least one wind wheel comprising at least one or more blade configured to convert flow energy of wind into rotational energy, at least one generator, the at least one generator being coupled to a hub or shaft of the at least one wind wheel or to an output shaft of a gear connected the at least one wind wheel, the at least one generator being configured to convert the rotational energy into electrical energy, wherein a center of gravity of the wind wheel, together with a hub and rotor shaft and rotatable parts of the generator or of the gear which are coupled to the hub or rotor shaft and rotate around the same rotational axis, is translationally movable in a horizontal or approximately horizontal direction together with the road vehicle in the direction of travel, wherein the at least one generator is either a direct current generator or is an alternating current generator with an output side of the at least one generator being coupled to a rectifier so as to provide the electrical energy as a direct current output, wherein at least one energy storage is coupled to the direct current output of the at least one generator or to the direct current output of the rectifier, for receiving and storing the electrical energy, wherein the extension of the at least one wind wheel parallel to its rotational axis is smaller than the extension of the at least one wind wheel transversely to its rotational axis, wherein, in the direction of travel of the road vehicle, there is no cascade of more than one wind wheel, i.e. no two wind wheels are arranged behind each other, and wherein the shape and size of the body of the vehicle are neither modified or increased by the wind generator nor affected by extensions fixed to the body of the vehicle housing the wind generator.

The invention refers to a wind generator onboard of a road vehicle, the wind generator comprising: at least one wind wheel which is mounted onboard of a road vehicle to be rotatable around a rotational axis, the at least one wind wheel comprising at least one or more blade configured to convert flow energy of wind into rotational energy, at least one generator, the at least one generator being coupled to a hub or shaft of the at least one wind wheel or to an output shaft of a gear connected the at least one wind wheel, the at least one generator being configured to convert the rotational energy into electrical energy, wherein a center of gravity of the wind wheel, together with a hub and rotor shaft and rotatable parts of the generator or of the gear which are coupled to the hub or rotor shaft and rotate around the same rotational axis, is translationally movable in a horizontal or approximately horizontal direction together with the road vehicle in the direction of travel, wherein the at least one generator is either a direct current generator or is an alternating current generator with an output side of the at least one generator being coupled to a rectifier so as to provide the electrical energy as a direct current output, wherein at least one energy storage is coupled to the direct current output of the at least one generator or to the direct current output of the rectifier, for receiving and storing the electrical energy, wherein the extension of the at least one wind wheel parallel to its rotational axis is smaller than the extension of the at least one wind wheel transversely to its rotational axis, wherein, in the direction of travel of the road vehicle, there is no cascade of more than one wind wheel, i.e. no two wind wheels are arranged behind each other, and wherein the shape and size of the body of the vehicle are neither modified or increased by the wind generator nor affected by extensions fixed to the body of the vehicle housing the wind generator.

A system and method by which energy from ocean waves is converted into hydrogen, and that hydrogen is used to manifest electrical and mechanical energies by an energy consuming device. A portion of the generated electrical power is communicated to water electrolyzers which produce oxygen and hydrogen from water as gases. At least a portion of the generated hydrogen gas is transferred to a transportation ship via a hose-carrying, remotely operated (or otherwise unmanned) vehicle, and subsequently transferred to an energy-consuming module or infrastructur, where a portion of the hydrogen is consumed in order to manifest a generation of electrical energy, a mechanical motion, and/or a chemical reaction.

The present disclosure discloses a wind-solar reactor system and a working method thereof. The wind-solar reactor system comprises a nuclear reactor system, a wind power generation system, a solar power storage system and a balance energy system, wherein the nuclear reactor system uses an integrated small modular reactor design, the solar power storage system uses a tower-type solar power storage system design, and a hydrogen production system uses a copper-chlorine cycle hydrogen production technology. A reactor keeps rated full-power operation, generated electricity is adjusted and distributed through a power controller, most of the electricity is used for smoothing the fluctuation of wind power generation, and the excess electricity is used for hydrogen storage of the hydrogen system. Solar power is used for heating saturated steam generated by the reactor into superheated steam through a heater, and then the superheated steam enters a high-pressure cylinder to do work by expansion.

A wind turbine is provided including a generator, an electrolytic unit, a system inlet and a system outlet, wherein the electrolytic unit is electrically powered by the generator to produce hydrogen from an input fluid, in particular water, wherein the hydrogen produced can be taken out of the wind turbine by the system outlet, wherein the wind turbine further includes a safety system controlled by a control unit configured to evacuate the hydrogen out of the wind turbine) by a plurality of gas outlets distributed on a platform of the wind turbine and configured to release the hydrogen to the atmosphere.

A wind turbine is provided including a generator, an electrolytic unit, a system inlet and a system outlet, wherein the electrolytic unit is electrically powered by the generator to produce hydrogen from an input fluid, in particular water, wherein the hydrogen produced can be taken out of the wind turbine by the system outlet, wherein the wind turbine further includes a safety system controlled by a control unit configured to evacuate the hydrogen out of the wind turbine) by a plurality of gas outlets distributed on a platform of the wind turbine and configured to release the hydrogen to the atmosphere.