A human powered electricity generation device, comprising: a mechanism for receiving energy provided by a user; a first generator for receiving the energy provided by the user from the mechanism and generating electricity power; a power meter for measuring the electricity power generated by the first generator to be transmitted to an electricity power grid; an input device for receiving an identity of the user; and a processor, configured for following: receiving the identity of the user from the input device before the power meter measuring the generated electricity power; receiving information of the measured electricity power from the power meter; and outputting the information of the measured electricity power associated with the identity.

Disclosed herein is a hydropower electric generator, in accordance with some embodiments. Accordingly, the hydropower electric generator may include a closed conduit. Further, the closed conduit may include a reservoir, two downward flow pipes, two horizontal pipes, and two upward flow pipes. Further, the downward flow pipes may include turbines configured to intercept the downward flow of the water and generate rotational force. Further, the upward flow pipe may include an airlift assembly configured to receive compressed air into the upward flow pipe. Further, the hydropower electric generator may include an air pump configured to generate the compressed air based on electrical energy. Further, the hydropower electric generator may include an energy storage device.

Platform tower assemblies for mounting wind turbine assemblies, as well as methods, systems and components related thereto. A central shaft may support a series of planar platforms along its length, each platform constructed to support a plurality of wind turbine assemblies. The wind turbine assemblies may be positioned to optimize production based on prevailing wind directions, and may include turbine assemblies optimized for different wind conditions. The platform tower may include a housing around a lower portion for storage of batteries and control circuitry. The uppermost platform may include one or more solar panels for additional power generation capability.

An airflow generator power supply of an embodiment supplies alternating-current voltage to a plurality of airflow generators on a blade of a wind turbine generator. The power supply has a frequency converter, a plurality of transformers, and a switch. The frequency converter generates alternating-current voltage. Each transformer amplifies the alternating-current voltage and applies the amplified voltage to the corresponding airflow generator. The switch outputs the alternating-current voltage from the frequency converter to one selected from the transformers.

A vibration suppression method and device of a wind power generator is provided. The method includes: calculating a specified value of a flux-weakening control parameter of the generator according to a preset value of an electromagnetic active power of the generator and a frequency of the generator; and controlling the generator according to the specified value of the flux-weakening control parameter of the generator. The method and device reduce the magnetic load of the generator by the flux-weakening control, thereby suppress vibration and noise of the generator.

A wind turbine panel is configured to distribute electricity to a load. The wind turbine panel includes a frame further includes a first slot having a first slot first end and a first slot second end. A first alternator is located in a first panel mount on the first slot first end. A second alternator is located in a second panel mount on the first slot second end. A first alternator shaft, connects the first alternator and the second alternator. A wind turbine is connected to the first alternator shaft. The load is electrically coupled to the first alternator and the second alternator. Wind traveling through the frame rotates the wind turbine and thus turns the alternator shafts that generates the electricity which is transferred to the load for use in downstream applications.

A modular HVDC platform and a method for constructing the same are disclosed herein. The modular HVDC platform has a topside disposed on a structural jacket. The topside includes a first rectifier module, a second rectifier module, and a utility module. The first and second rectifier modules have equipment for converting AC power to DC power disposed therein. The utility module contains equipment for supporting the operations of the rectifier modules. Each of the rectifier modules and the utility modules can be fabricated and commissioned onshore prior to installation on the structural jacket at an offshore location.

Platform tower assemblies for mounting wind turbine assemblies, as well as methods, systems and components related thereto. A central shaft may support a series of planar platforms along its length, each platform constructed to support a plurality of wind turbine assemblies. The wind turbine assemblies may be positioned to optimize production based on prevailing wind directions, and may include turbine assemblies optimized for different wind conditions. The platform tower may include a housing around a lower portion for storage of batteries and control circuitry. The uppermost platform may include one or more solar panels for additional power generation capability.

Systems and methods for operating an energy storage system in a wind turbine system are provided. A wind turbine system can include a wind turbine, a power conversion system operably coupled to the wind turbine and an AC line bus, and an energy storage system coupled to the AC line bus. The energy storage system can include a transformer, a power converter, and an energy storage device and can be configured to store and provide power generated by the wind turbine. The method can include operating the wind turbine system to generate power, determining one or more operating parameters for the wind turbine system, determining an operating mode based on the one or more operating parameters, and controlling the wind turbine system based at least in part on the operating mode. Controlling the wind turbine can control a power flow into or out of the energy storage system.

A nacelle for a wind turbine generator comprises a crane articulated on a base fixed to said nacelle. The crane includes a cantilevered telescopic boom, a principal winch with a lifting line and respective azimuth and elevation drive units for moving said boom in azimuth and in elevation relative to said nacelle. The crane has a deployed condition in which said boom is moveable in azimuth and in elevation and a stowed condition. The nacelle comprises a support structure against which said boom is brought to rest in said stowed condition thereof and wherein when in said stowed condition said boom is located into a predetermined position at which it is held to rest at a point along its length against said support structure and wherein said lifting line is in a reference position in relation to said nacelle when said crane is in its stowed condition. A method for operating a crane in a nacelle comprising operating said crane as a static hoist using a principal winch of said crane when in said stowed condition of said crane.