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.

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.

Systems and methods effective to reduce a drag coefficient in a vehicle are described. A system methods may receive first air directed towards an air intake structure at a first speed. The air intake structure may transform the first air into second air of a second speed. The system may direct the second air from the air intake structure to a tunnel structure. The tunnel structure may include an entrance and an exit, where a cross-sectional area of the entrance may be less than a cross-sectional area of the exit. The tunnel structure may expand the second air into expanded air. A third speed of the expanded air may be less than the second speed of the second air. The system may create a second drag coefficient, where the second drag coefficient may be less than the first drag coefficient.

A compact side-by-side motor gearbox unit is provided. The motor gearbox unit includes two independent electric motors and gearboxes with motor drive shafts and gearbox power output shafts mounted in opposite directions, the motors are held in a shared housing. The drive shafts of each electric motor in the motor gearbox unit are offset from one another and not colinear with one another. The power output shafts of the gearboxes are aligned along a common power output axis providing a half-shaft connection to a drive wheel on one side of the motor gearbox unit and a different half-shaft connection to another drive wheel on the other side of the motor gearbox unit.

A rotary device comprises a frame with a guide for flowing medium, a rotor with a number of blades, whereby a relation is obtained between the flowing medium and the rotation of the rotor, and energy converting means, the one part of which is connected to the frame and the other part to the rotor. The device has the feature that the end zones of the blades are connected to a ring, the ring has a radial section with the shape of an isosceles triangle or trapezium, the medium guide has an encircling recess, the form of which corresponds to the form of the ring and the ring fits with clearance into the recess, permanent magnets are added to the truncated conical surfaces, electromagnets debouch on both the corresponding surfaces of the recess, this such that the ring and the frame together form an annular induction motor or an electric generator.

A rotary device comprises a frame with a guide for flowing medium, a rotor with a number of blades, whereby a relation is obtained between the flowing medium and the rotation of the rotor, and energy converting means, the one part of which is connected to the frame and the other part to the rotor. The device has the feature that the end zones of the blades are connected to a ring, the ring has a radial section with the shape of an isosceles triangle or trapezium, the medium guide has an encircling recess, the form of which corresponds to the form of the ring and the ring fits with clearance into the recess, permanent magnets are added to the truncated conical surfaces, electromagnets debouch on both the corresponding surfaces of the recess, this such that the ring and the frame together form an annular induction motor or an electric generator.

Provided is a wind powered system which includes a plurality of wind tunnels, a plurality of rotary fans provided in each wind tunnel, a plurality of alternators connected to the plurality of rotary fans to generate electricity, a transformer connected to the plurality of alternators, electric components connected to the transformer, and a battery connected to the transformer and the electric components. The transformer is supplied with the electricity generated by the alternators and outputs electrical energy with a voltage to be supplied to at least one of the electric components and the battery. The plurality of wind tunnels have a plurality of intake inlets which are separated and apart from each other and a single outlet shared by the plurality of wind tunnels.

Described herein are apparatuses, systems, and methods for a solar car. The exterior of the solar car is comprised of smoothly curved and continuous photovoltaic cells. The exterior car parts, e.g., roof, doors, hood, trunk and so forth, may include integrated photovoltaic cells, all manufactured in the shape of the corresponding car parts. The photovoltaic cells are meta-encapsulated in an edgeless manner, and may utilize superconducting anodes. A first encapsulate may be polychlorotrifluoroethylene, an extreme water barrier. A second encapsulate, e.g., silicone, may be a water barrier and shock absorber. A third encapsulate may be UV stabilized polycarbonate or low iron glass. A street legal solar car may be constructed upon an electric car chassis. A competition solar car has one or more hyper-efficient electric motors, that may utilize superconducting wire in their armatures. Superconducting wire may also be used in the vehicle chassis.

Described herein are apparatuses, systems, and methods for a solar car. The exterior of the solar car is comprised of smoothly curved and continuous photovoltaic cells. The exterior car parts, e.g., roof, doors, hood, trunk and so forth, may include integrated photovoltaic cells, all manufactured in the shape of the corresponding car parts. The photovoltaic cells are meta-encapsulated in an edgeless manner, and may utilize superconducting anodes. A first encapsulate may be polychlorotrifluoroethylene, an extreme water barrier. A second encapsulate, e.g., silicone, may be a water barrier and shock absorber. A third encapsulate may be UV stabilized polycarbonate or low iron glass. A street legal solar car may be constructed upon an electric car chassis. A competition solar car has one or more hyper-efficient electric motors, that may utilize superconducting wire in their armatures. Superconducting wire may also be used in the vehicle chassis.

A drag reducing, solar panel vehicle cover is fastened onto the exterior parts of a vehicle namely the roof, hood, doors, fenders, and trunk. The vehicle cover has a generally indented shell made of thin wall metal with a thin film solar panel outer surface; the vehicle cover having a shape that conforms to the respective exterior part of the vehicle so that it mates with and overlaps the part. The surface of the vehicle cover is polished and plasma is generated above the surface through judiciously positioned plasma actuators which inhibit the separation of airflow when the vehicle is in motion, thereby reducing drag. The vehicle cover serves three objectives. It charges the onboard battery rack through a thin film solar panel outer surface without altering the original form, shape or contour of the vehicle. It reduces drag through judiciously positioned plasma actuators on its surface. It gives the vehicle the appearance of having a solar panel like surface.