A wind turbine assembly for covering wind energy into electrical energy includes a housing that is positioned adjacent to a roadway. An intake chute is integrated into the housing and the intake chute is oriented to face oncoming traffic on the roadway thereby facilitating the intake chute to direct wind produced by the oncoming traffic into the housing. A wind turbine is rotatably disposed within the intake chute such that the wind turbine is rotated by the wind produced by the oncoming traffic. A generator is positioned in the housing and the generator is in mechanical communication with the wind turbine. The generator is rotated when the wind turbine rotates to convert wind energy into electrical energy.

A fluid-powered generator harvests the inherent energy in a flowing medium, such as wind or water, as it flows along a flexible sail, creating an undulating motion that causes rotation of a crankshaft. The generator comprises a plurality of ribs pivotably connected to a support shaft. Each rib is coupled to the sail and to a crank arm such that when the sail undulates, the ribs and crank arm pivot in the direction of the undulation, causing rotation of the crankshaft. The generator thus converts the linear motion of the fluid to circular motion to produce renewable energy.

A fluid-powered generator harvests the inherent energy in a flowing medium, such as wind or water, as it flows along a flexible sail, creating an undulating motion that causes rotation of a crankshaft. The generator comprises a plurality of ribs pivotably connected to a support shaft. Each rib is coupled to the sail and to a crank arm such that when the sail undulates, the ribs and crank arm pivot in the direction of the undulation, causing rotation of the crankshaft. The generator thus converts the linear motion of the fluid to circular motion to produce renewable energy.

The present invention concerns a device transforming the energy from fluid flows into mechanical and electrical energy. The sources of primary energy are wind for the wind turbine version, or hydraulic flows such as marine or river currents, waves and tides, etc. for the water or hydro turbine version.

The device consists of a fluid guidance system (1), a rotor comprising at least two regularly arranged blades (2), a protective structure (4), a structuring framework (6), a top box (5) and a bottom box (7).

The device will play the role not only of wind turbine/water turbine but also of noise barriers, wave barriers, safety barriers and wireless electrical charging systems along the transport networks.

This invention is intended for companies or organizations producing electricity and individuals wishing to produce electricity.

The present invention concerns a device transforming the energy from fluid flows into mechanical and electrical energy. The sources of primary energy are wind for the wind turbine version, or hydraulic flows such as marine or river currents, waves and tides, etc. for the water or hydro turbine version.

The device consists of a fluid guidance system (1), a rotor comprising at least two regularly arranged blades (2), a protective structure (4), a structuring framework (6), a top box (5) and a bottom box (7).

The device will play the role not only of wind turbine/water turbine but also of noise barriers, wave barriers, safety barriers and wireless electrical charging systems along the transport networks.

This invention is intended for companies or organizations producing electricity and individuals wishing to produce electricity.

This presents a Utility Model related to an improvement introduced in a piece of equipment conceived to capture wind power generated by the displacement of trains, subways, vehicles in generaloverall trucksalong railroads, roads, etc., and to convert it in electrical power, thus using such considerable energetic potential. Considering that the assembly of one or a plurality of wind rotors (P) and respective electricity generators (G) are assembled on semi-tows (K) of the type engaged and handled by a truck (mechanical horse), considering that the trailers (K) provided with means for storing the electrical power generated, such as batteries (B), or other means for electricity transmission and storage. Thus, the aerogenerators (P) may be displaced to the points with the biggest flow of passing vehicles, and may also be positioned on the direction where the natural (predominant) winds are favorable to the best use of the wind potential.

An energy harvesting system includes a barrier disposed adjacent to a first traffic lane, the barrier comprising an aperture and a turbine disposed within the aperture. The turbine may be configured to generate electrical power in response to airflow through the aperture and in response to horizontal airflow that is tangential to the barrier and the aperture. In some embodiments, the barrier is disposed between the first traffic lane and a second traffic lane and may function as a traffic median. Consequently, the first traffic lane and the second traffic lane are may be counter-flowing traffic lanes. A method and apparatus corresponding to the above system are also disclosed herein.

An energy harvesting system includes a barrier disposed adjacent to a first traffic lane, the barrier comprising an aperture and a turbine disposed within the aperture. The turbine may be configured to generate electrical power in response to airflow through the aperture and in response to horizontal airflow that is tangential to the barrier and the aperture. In some embodiments, the barrier is disposed between the first traffic lane and a second traffic lane and may function as a traffic median. Consequently, the first traffic lane and the second traffic lane are may be counter-flowing traffic lanes. A method and apparatus corresponding to the above system are also disclosed herein.

An energy harvesting system includes a barrier disposed adjacent to a first traffic lane, the barrier comprising an aperture and a turbine disposed within the aperture. The turbine may be configured to generate electrical power in response to airflow through the aperture and in response to horizontal airflow that is tangential to the barrier and the aperture. In some embodiments, the barrier is disposed between the first traffic lane and a second traffic lane and may function as a traffic median. Consequently, the first traffic lane and the second traffic lane are may be counter-flowing traffic lanes. A method and apparatus corresponding to the above system are also disclosed herein.

An energy harvesting system includes a barrier disposed adjacent to a first traffic lane, the barrier comprising an aperture and a turbine disposed within the aperture. The turbine may be configured to generate electrical power in response to airflow through the aperture and in response to horizontal airflow that is tangential to the barrier and the aperture. In some embodiments, the barrier is disposed between the first traffic lane and a second traffic lane and may function as a traffic median. Consequently, the first traffic lane and the second traffic lane are may be counter-flowing traffic lanes. A method and apparatus corresponding to the above system are also disclosed herein.