A wave barrier or wave terminator type ocean wave energy converter (WEC) utilizing one or multiple adjacent floats together forming an elongated wave front parallel (EWFP) float rotatably connected by at least one swing or drive arm to a secondary floating or shore or seabed fixed body or frame, such that the at least one swing arm is rotating about a submerged pivot point or axle on such body or frame and constraining the motion of the float(s) relative to the body or frame when wave forces are applied against the float(s). Relative to the direction of oncoming wave fronts and relative to the still water line (SWL), the at least one EWFP float is substantially forward of, and above, the pivot point such that the float concurrently moves both upward and rearward on wave crests and returns both forward and downward on ensuing wave troughs. The rear surface of the EWFP float is substantially arcuate and concave with a radius approximating its distance from the pivot point such that the float produces minimal energy consuming back waves when it is being moved by oncoming wave forces. The lower rear arcuate surface of the float can extend below the bottom of the float deeper into the water column to capture additional wave energy.

A wave energy converter has blades (54, 56, 57, 59) on frames (51, 52) rotating about a pivot joint (53) on a structure (4, 52, 502, 505, 86). There is reciprocating rotary motion of the frame with respect to the structure, providing reciprocating rotary input power to a mechanism (73, 94, 98). The mechanism (98) may be arranged so that the reciprocating input power is transferred to uni-directional power via pulleys (101, 106) and sprag clutches (102, 107).

Described is an infrastructure for recovering and storing energy received from wave motion of lakes or sea water basins, comprising a floating or fixed quay, jetty or pier (10) substantially consisting of a platform (11) in the lower part of which are fixed walls (12, 13, 14) equipped with openings (17) for the passage of the wave motion towards inner chambers (15, 16), wherein the inner chambers comprise units for recovering the energy from the wave motion, comprising floats (18) connected by kinematic means (19, 20) to at least one transmission shaft (22) in turn associated with a unit (24) which transforms the mechanical energy into directly usable or storable electricity, the kinematic means (19, 20) being capable of converting the sussultatory motion of the floats (18) into rotary motion of the shaft (22) allowing the recovery of electricity from the relative transformation unit (24).

A floating power generation station comprises a floating hull with a shelter structure containing photovoltaic solar panels are arranged on a chain of floats, each hinged one to the next. The system can be deployed onto a large flat area, e.g., surface of inlet or bay, where the solar panel chain(s) can be extended out. The power generation station may include air displacement tubes that have a lower end immersed in water, and which feed into a plenum where check valves direct air unidirectionally to an air turbine that powers an electric generator. Air turbines or wind turbines on the barge can be raised or tipped up for collection of wind energy. The captured energy is stored on a bank of on-board storage batteries. Energy can be collected and stored, and the barge can be brought to shore when and where needed. This arrangement can be configured for ground-based deployment. The power generation station can be configured for use on dry land.

A wave energy conversion system is provided including a pod, multi-radius energy transmission mechanism, and an electrical generating device. The pod is rotatably supported by a platform structure and the multi-radius energy transmission mechanism is in mechanical communication with the pod. The multi-radius energy transmission mechanism is configured to transmit a variable torque over a range of motion and is in mechanical communication with the electrical generating device.

A float operated lever device for wave energy conversion comprising at least one force amplifying lever, a pivot secured on a secured platform, a buoyant float attached to said lever and a latch means secured in position for obstructing the motion of said force amplifying lever for a fraction of half wave's period, when said float is nearly at its highest and lowest positions whereby said force amplifying lever travels downward or upward respectively, at a greater velocity and for a greater distance than in the case of free floating thus producing an amplified output force, pivoting speed and angular displacement. A method for thermal energy storage and retrieval of electricity in phase change material.

The present invention is related generally to electric energy production and storage and more particularly to three devices that can work independently or as a system for generating, storing and retrieving of significant volume of green electric energy from sea and ocean waves. The present invention comprises of three module systems for wave power amplifying, wave power harnessing and conversion to electric energy, and energy storage. The system could double the height and quadruple the power of any wave, harness and convert all the wave power to electrical energy, store it without loss for as long as needed, and release it when and as needed.

Disclosed is an energy harvesting system for ocean waves. The energy harvesting system includes each of a buoyant platform and a plurality of wave energy harvesting units. The buoyant platform is configured to float above the ocean bed. Further, each wave energy harvesting unit may be tethered between the buoyant platform and the ocean bed. Additionally, a wave energy harvesting unit may be configured to be actuated by motion of the buoyant platform. Accordingly, the wave energy harvesting unit may absorb energy from the buoyant platform's movement resulted from the ocean waves.

Provided is a wave energy power generation device, comprising a working platform, and a wave energy conversion mechanism, a wave energy storage mechanism and a wave energy power generation mechanism, which are arranged on the working platform. By means of the structures, such as a buoyancy tank, a lever, a gear set and a flywheel, the wave energy conversion mechanism converts wave energy, which is generated by wave fluctuation, into mechanical energy ensuring the continuous rotation of the flywheel. The wave energy storage mechanism, by means of compressed gas, collects and stores the wave energy.

An energy conversion system includes a power takeoff system, a fin connected to the power takeoff system, and a control system on board the fin. The fin is submerged below a surface of the sea, and the fin is configured to use subsurface wave motions to extract energy.