The present invention is a wind turbine system with multiple generator modules that maximize the use of the mast of a wind turbine by implementing an electrical generator module with a magnetic assembly. In some embodiments, the system includes a set of blades adapted to rotate on a horizontal axis and coupled to a first rotor. A first generator is coupled to the first rotor and disposed within a housing. The mast of the system extends from the housing and encloses a second generator module. A gearbox module is adapted to engage the first rotor through a first gear shaft and engage the second rotor through a second gear shaft. The gearbox module may be adapted to selectively engage the second generator module when a windspeed exceeds a threshold windspeed. A magnetic assembly disposed within the mast is adapted to induce an electric current.

The method of erecting a wind turbine, comprising pivotably mounting the lower end of a mast on a side or end of a container, connecting a first wire, rope, cable, or chain to the upper end of the mast and to the top end of an intermediate truss, connecting a second wire, rope, cable, or chain to the top end of the intermediate truss and to a winch, pivotably fixing a lower end of the intermediate truss to the container, operating the winch to support a portion of the weight of the mast, assembly the wind turbine on the mast, operate the winch to move the mast and wind turbine to the vertical position, engage a second connection to fix the mast in the vertical position, and releasing the wire, rope cable or chain from the upper end of the truss.

The present invention is a wind turbine system with multiple generator modules that maximize the use of the mast of a wind turbine by implementing an electrical generator module with a magnetic assembly. In some embodiments, the system includes a set of blades adapted to rotate on a horizontal axis and coupled to a first rotor. A first generator is coupled to the first rotor and disposed within a housing. The mast of the system extends from the housing and encloses a second generator module. A gearbox module is adapted to engage the first rotor through a first gear shaft and engage the second rotor through a second gear shaft. The gearbox module may be adapted to selectively engage the second generator module when a windspeed exceeds a threshold windspeed. A magnetic assembly disposed within the mast is adapted to induce an electric current.

A wind powered generator comprising; a mast having a plurality of tower outlets positioned along on a low pressure portion of a length of the mast; one or more inlets positioned on a high pressure portion of the mast; an internal fluid flow path between the inlet and the tower outlets; a turbine in the fluid flow path; wherein the inlet and tower outlets are arranged such that wind creates air flow through the fluid flow path for motivating a turbine.

An apparatus for deployment of a wind turbine includes a wind turbine coupled to a first end of an extendable arm, one or more turbine blades coupled to the wind turbine, wherein the one or more turbine blades are collapsible about the turbine wind turbine, and a housing coupled to a second end of the extendable arm, wherein the wind turbine is extendable from and retractable to the housing via the extendable arm.

The present invention relates to a vertical axis multi-stage wind turbine generator in which multiple stages are provided in a vertical axis to construct a plurality of power generating devices in one power generation facility so that backwind power is enhanced to the maximum, and headwind power is minimized to achieve an economical and efficient power generation function.

The method of erecting a wind turbine, comprising pivotably mounting the lower end of a mast on a side or end of a container, connecting a first wire, rope, cable, or chain to the upper end of the mast and to the top end of an intermediate truss, connecting a second wire, rope, cable, or chain to the top end of the intermediate truss and to a winch, pivotably fixing a lower end of the intermediate truss to the container, operating the winch to support a portion of the weight of the mast, assembly the wind turbine on the mast, operate the winch to move the mast and wind turbine to the vertical position, engage a second connection to fix the mast in the vertical position, and releasing the wire, rope cable or chain from the upper end of the truss.

Wind energy assemblies and deployment methods are provided that include a telescoping mast, an energy conversion system, and a carriage assembly. The telescoping mast has a top and a bottom, a mast roller system, and a plurality of mast sections. At least one of the mast sections is an internal mast section, and at least one of the mast sections is an external mast section. The energy conversion system is mounted to the top of the telescoping mast and includes a steering system, a wind instrument mast, a drive assembly, a rotor hub, a disc brake, and a plurality of blades extending from the rotor hub. The carriage assembly supports the telescoping mast. The mast roller system enables the at least one internal mast section to be pulled out from the at least one external mast section, thereby facilitating extension of the telescoping mast. A hydraulic ram assembly may be provided to rotate the telescoping mast to a vertical position.