An ocean wave-crest powered electrical generator comprises a buoyant vessel anchored to the sea floor by mooring chains. The vessel defines a substantial opening at the bow leading to a paddle wheel such that ocean wave crests flow past the paddle wheel while passing through the generator thereby capturing the power of the continuous wave crests passing through the bow opening. The paddle wheel transforms energy from the breaking wave crests into kinetic energy that in turn activates an electric power generator. The wave crest electrical generator is permanently moored near the beach and allowed to rise and fall with the tide thus allowing for a continuous flow of ocean waves to be converted into power. Pumped storage provides a sustained flow of energy that is easy to regulate and this can be accomplished in combination with energetic marinas by constructing a reservoir on top of a near-by cliff, hill or tall building.

A testing device for a model of a floating gate, the device including: a towing carriage including a platform and a moon pool; a square support mechanism including two upper transversal beams, two upper longitudinal beams, two I-shaped longitudinal beams, four lower beams, and straight plates disposed on two of the four lower beams; a dynamometric mechanism including a longitudinal tensiometer, a transversal tensiometer, and a signal transmitting terminal; a data acquisition mechanism including a computer and a signal receiving terminal; a casing mechanism including two stepped shafts and two rolling wheels; and a guide rod mechanism including an inner sleeve, an outer sleeve, and a connecting plate. One end of the connecting plate is connected to the lower end of the inner sleeve, and the other end thereof is connected to a deck of the floating gate.

A water-flow power device includes a carrier, a first sprocket component, a second sprocket component, a first chain, a second chain, a plurality of blade structures, and an energy conversion unit. The carrier has a first end portion and a second end portion opposite to the first end portion. The first sprocket component is disposed at the first end portion of the carrier. The second sprocket component is disposed at the second end portion of the carrier. The first chain is configured to surround the first sprocket component and the second sprocket component. The second chain is configured to surround the first sprocket component and the second sprocket component. Two ends of each of the blade structures are respectively connected to the first chain and the second chain. The energy conversion unit is connected to the first sprocket component or the second sprocket component.

A system and method of extracting the rotational energy of water waves and converting this energy into the rotating torque of a drive axle. This system and method incorporates the use of a wave amplification channel using an array of one way valves surrounding a wave energy collection mechanism (WECM). The WECM is a conveyor, using hinged, curved paddled wave wheels attached to a pinion and rack system causing the waves to drive the conveyor. The WECM is supported by two movable connected walls. These walls are either structure-mounted or ship-mounted with a permanent anchoring system. Two possible ways of automating the conveyer to accommodate variations in wave period are also given.

A piezoelectric element for power generation and a power generation device using the same according to the present invention can maximize an electromotive force generated by the piezoelectric element by converting an external force (a natural force or a load force of a person/vehicle or the like) transferred from the outside into an instantaneous impact force and transferring the impact force to the piezoelectric element.