A system for supplying electric power has at least one moving vehicle, a rotary element provided in the moving vehicle and rotatable by a wind when the moving vehicle is moving, at least one electrical battery provided in the moving vehicle and charging components of the moving vehicle, at least one electrical generator having a rotor connected with and rotatable by the rotary element when the rotary element is rotated during moving of the moving vehicle, so as to generate electric current, and an electrical connection for electrically connecting the electrical generator with the at least one electrical battery so that the at least one electrical battery is charged by the electric current generated by the electrical generator.

A power generating windmill having a plurality of blade extending radially outward from a central rotor in position to be engaged by a moving fluid stream is provided. Each blade partially overlaps the blade prior to and behind it to increase lift forces on the blades.

An inground geothermal system has an upper end extending above ground level at a height to support a wind turbine. The wind turbine generates an electrical current for use by the geothermal system or for storage in batteries.

An inground geothermal system has an upper end extending above ground level at a height to support a wind turbine. The wind turbine generates an electrical current for use by the geothermal system or for storage in batteries.

A floating heat pump system including a superstructure supporting a wind turbine and at least one electric generator mechanically connected to the wind turbine. Wind-induced rotation of the wind turbine causes the electric generator to generate electricity. The generated electricity may be supplied to a power grid, or a portion of the generated electricity may be used to power a heat pump also supported at least in part by the superstructure to extract heat from the ocean or another large body of water. The heat may be stored in transportable thermal storage medium. Heat stored in the thermal storage media may be used at the system or remotely for regional or district heating and cooling, industrial purposes, or to generate electricity.

A floating heat pump system including a superstructure supporting a wind turbine and at least one electric generator mechanically connected to the wind turbine. Wind-induced rotation of the wind turbine causes the electric generator to generate electricity. The generated electricity may be supplied to a power grid, or a portion of the generated electricity may be used to power a heat pump also supported at least in part by the superstructure to extract heat from the ocean or another large body of water. The heat may be stored in transportable thermal storage medium. Heat stored in the thermal storage media may be used at the system or remotely for regional or district heating and cooling, industrial purposes, or to generate electricity.

A wind turbine assembly including a rotor system, a generator, a first converter, a second converter, and a controller system. The first converter includes a first bridge circuit having a plurality of switch members each having a controllable switch. The second converter includes a second bridge circuit having a plurality of switch members each having a controllable switch. The controller system is adapted to provide a drying operation for second converter including short circuiting the second converter with the controllable switches of the second bridge in circuit, and supplying power from the generator through the first converter to the short circuited second converter for drying the second converter.

A waste heat recovery system of a wind turbine is provided. A wind turbine is disclosed, including an electrical installation to transform wind energy into electrical energy, whereby the electrical installation produces waste heat. The wind turbine includes a waste heat recovery system to transform at least a part of the waste heat into electrical energy.

A waste heat recovery system of a wind turbine is provided. A wind turbine is disclosed, including an electrical installation to transform wind energy into electrical energy, whereby the electrical installation produces waste heat. The wind turbine includes a waste heat recovery system to transform at least a part of the waste heat into electrical energy.

Provided is a method for operating wind energy converters, in particular of a wind farm. The power limitation mode in this case comprises the steps of turning off at least one of the wind energy converters and operating at least one wind energy converter different to the turned-off wind energy converter, activating a generator heating of the turned-off wind energy converter, turning off the working wind energy converter at or after occurrence of a predefined event, in particular after a predefined time period has elapsed or when a predefined instant is reached, and activating the generator heating of the wind energy converter turned off at or after the occurrence of the predefined event. Provided is a wind farm and to a wind energy converter for carrying out such a method.