A Tidal Electricity Generator device and system providing a simple and effective way to generate electricity by harnessing tidal motion. The device has no parts to churn up the water, and does not actively force water through blades or screens. The device works passively to extract energy from the water by capturing the buoyancy of a bobber which rises and falls with the tides and/or gravity. Thus the kinetic energy of the tides is converted into mechanical energy which can then be transferred through a series of gears and other components to power an electric generator or other electric power grid. With this system, there is nothing to harm the environment or any sea life.

A floating platform generating energy produced from wave energy. In one embodiment, the platform may be used to support a roadway to build a floating bridge. The platform may also include a wave break mechanism for additional stability and may submerge for storm survival. The platform may be constructed in modules to permit reconfiguration and management of resources. In other embodiments, the platform may support communities. The bridge may also provide transmission lines for conducting wave generated electricity back to the mainland. In further embodiments, the platform may generate pressurized air from wave energy and may store the pressurized air at depth in a plurality of air tanks arranged in sequence at different depths.

Methods, systems, and devices are disclosed for wave power generation. In one aspect, a wave power generator device includes a stator assembly and a rotor assembly encased within a tube frame. The stator assembly includes an array of inductor coils in a fixed position within a cavity of the tube frame and a plurality of bearings coupled to the tube frame. The rotor assembly includes a turbine rotor having a central hub and peripheral blades coupled to a high inertia annular flywheel that is moveably engaged with the bearings of the stator assembly, and an array of magnets arranged to be evenly spaced and of alternating axial polarity from one another extending from the annular flywheel into the cavity between the array of inductor coils, such that electric currents are produced based on magnetic field interaction of the magnets with the inductor coils during the rotation of the annular flywheel.

A wave energy conversion cylinder includes an outer cylinder and a center rod disposed along an axis of the outer cylinder. A plurality of electrically-conductive windings are disposed about an inner circumference of the outer cylinder. A magnet is slidably disposed on the center rod. A buoyancy cylinder is disposed outwardly of the outer cylinder. A first moveable ring weight may be slidably disposed along the axis of the center rod and a second moveable ring weight may be slidably disposed along the axis of the center rod. The first moveable ring weight and the second moveable ring weight facilitate control to tune a mass moment of inertia of the wave energy conversion cylinder.

An apparatus for generating energy from ocean waves, the apparatus including a first or outer section arranged to be coupled to a sea floor and a second or inner section that is at least partially received by and slidably moveable within the first section. The first section includes a float housing arranged to be located toward or at a sea surface and an armature housing extending from the float housing toward the sea floor, the float housing having one or more apertures so that a water level within the float housing is substantially similar to or follows that of the sea surface. The second section includes a float slidably received by the float housing and a stem carrying a magnetic element that extends from the float so as to be receivable by the armature housing. The arrangement is such that the float travels in substantially vertical direction within the float housing in response to movement of the sea surface thereby the armature housing being moved relative to the magnetic element to generate energy.

A system for obtaining energy from surface waves is disclosed. The system can include an array of buoys. The array of buoys can include a framework having a plurality of vertical members. The array of buoys can also include a base buoy coupled to the framework to support the framework in a body of water and maintain the vertical members in a vertical orientation. The array of buoys can further include a plurality of movable buoys. Each of the plurality of movable buoys can be movably disposed about a different one of the vertical members and configured to move relative to the respective vertical members and the base buoy in response to a wave in the body of water. Additionally, the array of buoys can include an energy conversion device operable with each of the plurality of movable buoys to generate power from movement of the movable buoys relative to the vertical members.

A wave powered hydraulic piston generator assembly for powering a generator by a hydraulic turbine and piston assembly includes a container being positioned adjacent to the shoreline of a body of water. The container has an opening having an interior surface where a piston is positioned against. A rod protrudes out from a back surface of the piston wherein an end of the rod has a first seal being moving within a cylinder. The cylinder has an inlet positioned proximate to the first end of the cylinder, whereas an outlet is positioned on a second end of the cylinder. A first conduit of a tank is connected with the outlet of the cylinder. A turbine is connected with a second conduit of the tank. The turbine has a drive shaft in mechanical communication with a generator. Furthermore, the turbine is in fluid communication with the inlet of the cylinder.

A wave energy absorption and conversion device and a power generation system includes a floating body, a guiding shaft, a damping plate and a counteracting mechanism placed in a movement range of the damping plate. The guiding shaft is connected to the bottom of the floating body and passes through the center of the damping plate. The damping plate may slide on the guiding shaft. A counterforce generated by the counteracting mechanism is opposite to a natural moving direction of the damping plate, so that the damping plate can be kept in a relatively static state under a synergistic effect of the counteracting mechanism, and thereby, colliding of damping plate with constraint structures above and below can be prevented when floating body is moving up and down following waves. The power generation system includes the wave energy absorption and conversion device and a power generation system.

The present invention relates, in part, to a wave powered electrical generator having a core electrically generating component that spins in one direction with the rise and fall of a wave. In certain aspects, it includes an apparatus, system, and method for converting wave energy into electricity. The apparatus includes a housing; an inner core within the housing that rotates in at least one direction; a first set of electrically conductive wire coils coupled to a peripheral wall of the inner core; a second set of electrically conductive wire coils adjacent to the inner core; a plurality of sliding elements coupled to a housing wall and slidable along a least a portion of the housing wall; and a buoy coupled to the sliding elements on an external side of the housing.

A power-take-off system for use in a wave energy converter buoy employs a meshing nut and screw shaft assembly for motion conversion. That is, the motion of the buoy float is coupled to drive the nut along the screw shaft on which it is mounted. The linear movement of the nut along the shaft causes the shaft to rotate and this rotational motion is then coupled to rotate an electrical generator.