An energy-producing system comprising an axle configured to be driven by an electric vehicle's wheels when in motion. The axle supports a series of wind-catching cups contained within an aerodynamic housing configured to direct air to the cups while also increasing the air speed. During vehicle motion, the cups are acted upon by rushing air causing the rotation of the axle such that the rotation may be transferred into energy via a generator/alternator linked thereto. A series of similarly polarized magnets integrated on said cups and/or spacers and/or housing proximate thereto further maintain the axle in motion during short vehicle stops. The system extends the life of the batteries between charges as well the distance the vehicle can travel between charges. A bracket supporting a series of permanent magnets assists with driving the axle.

An electricity generator includes a wind tunnel positioned on the vehicle. The wind tunnel has an open first end and an open second end. The open first end is in communication with ambient air. A turbine chamber is fluidly coupled to the open second end of the wind tunnel. At least one wind turbine is positioned in the turbine chamber. The at least one wind turbine includes a housing. A rotor is positioned in the housing along an axis that is substantially perpendicular to an axis of the wind tunnel.

A system and method for enhanced operation of an electric vehicle having a main battery for powering an electric drive motor by which the vehicle is drivable, including at least one air intake device operable, in forward motion of the vehicle or when the vehicle is stationary, to capture and channel air in flow through the intake device to at least one turbine adjacent to an outlet end of the air intake device to drive the turbine(s) to generate a first electrical energy at a first energy level and/or including one or more photovoltaic solar panels integrated with or adjacent to one or more body components of the electric vehicle and the one or more photovoltaic solar panels is/are adapted to generate a/the first energy at a/the first energy level. A secondary battery pack connected to an electrical energy outlet of the turbine(s) and/or photovoltaic panels receives the electrical energy generated by the turbine(s) and/or photovoltaic panels. A first auxiliary electric motor is drivable by the secondary battery pack for rotating an output shaft of the first auxiliary electric motor. A second auxiliary electric motor having an input shaft connected to the output shaft of the first auxiliary electric motor has an output terminal connectable to the main battery of the vehicle. A transmission couples the output and input shafts and provides a rotational speed step up from the first to the second of the auxiliary electric motors, whereby the second auxiliary electric motor is drivable to generate a second electrical energy, at a second energy level higher than the first energy level, able to be supplied from the output terminal of the second auxiliary electric motor to the main battery and/or the drive motor of the vehicle.

Methods and systems for substantially continual electrical power generation for a moving vehicle are disclosed herein. According to the various embodiments discussed herein, the battery range can be increased significantly using a variety of energy sources. The energy sources are configured to facilitate continual electricity generation based on: (i) one or more generators positioned around predetermined vehicle parts; (ii) wind energy created by the motion of the vehicle in relation to the surrounding medium, and (iii) solar energy. According to an embodiment, the system for continual electrical power generation in a moving vehicle comprises a generator having a coil-and-magnet arrangement around one or more vehicle components/modified components. In another embodiment, the system comprises an energy generator for converting solar energy and wind energy into electricity.

An energy-producing system comprising an axle configured to be driven by an electric vehicle's wheels when in motion. The axle supports a series of wind-catching cups contained within an aerodynamic housing configured to direct air to the cups while also increasing the air speed. During vehicle motion, the cups are acted upon by rushing air causing the rotation of the axle such that the rotation may be transferred into energy via a generator/alternator linked thereto. A series of similarly polarized magnets integrated on said cups and/or spacers and/or housing proximate thereto further maintain the axle in motion during short vehicle stops. The system extends the life of the batteries between charges as well the distance the vehicle can travel between charges. A power controller is configured to distribute power from said generator to an axle drive motor, vehicle drive motor and/or start-up battery pack.

A vehicle mounted energy generator and storage system includes: a screened air inlet facing a front of the vehicle through which air enters when the vehicle is moving forward; a pneumatic barrel impeller assembly including one or more integral impeller air vanes positioned such that air flowing through the air inlet applies positive pressure to the one or more impeller air vanes to turn the pneumatic barrel impeller assembly and drive one or more generator/transmission assemblies; one or more batteries receiving energy generated by the pneumatic barrel impeller assembly; and an evacuation blower applying negative pressure to the rear of the impeller air vanes by evacuating air through one or more screened outlets not facing the front of the vehicle.

A multimodal renewable energy generation system for generating electric power from more than one renewable energy source is disclosed herein. The system includes two or more spinner units configured on a vertical pillar. The spinner units are configured for rotation under influence of a stream of a corresponding fluid. A set of electric power generators is operatively coupled to each of the two or more spinner units to generate electric power when the corresponding spinner unit rotates. At least one of the two or more spinner units is configured close to a base portion of the pillar to harness power from sea waves and remaining of the two or more spinner units are configured with an upper portion of the pillar for harnessing power from wind. The spinner units are configured for rotation in a horizontal plane even at less powerful winds or water streams.

An ecological system for use in land or marine vehicles is provided, which uses wasted airmass making it to pass through two subsystems which allow lighten the load of the moving vehicle and generates electrical energy. Therefore, showing an economy in fuel, tires, and general maintenance savings, as well as a decrease of contaminants thrown to the environment.

A vehicle mounted energy generator and storage system includes: a screened air inlet facing a front of the vehicle through which air enters when the vehicle is moving forward; a pneumatic barrel impeller assembly including one or more integral impeller air vanes positioned such that air flowing through the air inlet applies positive pressure to the one or more impeller air vanes to turn the pneumatic barrel impeller assembly and drive one or more generator/transmission assemblies; one or more batteries receiving energy generated by the pneumatic barrel impeller assembly; and an evacuation blower applying negative pressure to the rear of the impeller air vanes by evacuating air through one or more screened outlets not facing the front of the vehicle.

This invention provides for a multi-disciplinary energy harnessing mechanism for outfitting a vehicle. Accordingly, sub-systems for harnessing energy from various sources of renewable energy occurring in vicinity of/incidental to the vehicle, such as 5 solar, waste heat, miming water, flowing wind, mechanical impacts, heat from the road surface being traversed are integrated into a vehicle whereby the effective range of the vehicle is increased while reducing the frequency and amount of charging otherwise required from the electric grid.