A hydropower generator includes: a driving shaft installed along a path through which a fluid flows; a plurality of blade assemblies installed along a lengthwise direction of the driving shaft; a spinning supporter connected to rotatably support the driving shaft; a power generator receiving a spinning force of the driving shaft and generating electricity; and a flow pipeline internally provided with the driving shaft along a lengthwise direction thereof and formed with a channel through which a fluid flows.

The APPARATUSES, METHODS AND SYSTEMS FOR HARNESSING THE ENERGY OF FLUID FLOW TO GENERATE ELECTRICITY OR PUMP FLUID include a device which, when placed in fluid-flow, harnesses the kinetic energy of the flow to generate electricity or to perform useful mechanical work such as pumping. For example, the undulating mechanical action of traveling waves along flexible fins may be harnessed by summing the varying speeds and torques along the fins into a unified circulatory system for power take-off or fluid extraction. The device may include two fins, a chassis, and bellows/pistons/rotary vanes and the like which are connected via a circulatory system of tubes or conduits.

A transportable gravitational system and method for generating consistent electrical power and generating minimized pollution. The abstract of the disclosure is submitted herewith as required by 37 C.F.R. 1.72(b). As stated in 37 C.F.R. 1.72(b): A brief abstract of the technical disclosure in the specification must commence on a separate sheet, preferably following the claims, under the heading Abstract of the Disclosure. The purpose of the abstract is to enable the Patent and Trademark Office and the public generally to determine quickly from a cursory inspection the nature and gist of the technical disclosure. The abstract shall not be used for interpreting the scope of the claims. Therefore, any statements made relating to the abstract are not intended to limit the claims in any manner and should not be interpreted as limiting the claims in any manner.

Hydrostatic pressure turbine runners according to the present disclosure are designed for maximally exploiting the hydrostatic pressure of a flowing fluid, rather than maximizing extraction of kinetic energy from the flow. The design converts less kinetic energy of the flow into hydropower as compared with current run-of-river turbine runner technologies. However, hydrostatic pressure turbine runners according to the present disclosure convert substantially more potential energy into hydropower. As a result, the total amount of energy converted into hydropower is significantly higher than the hydropower available from conventional run-of-river turbine runner designs, and, without promising any particular utility, may be capable of surpassing the upper limit of converted energy as defined by Betz' law. In a run-of-river context, the total amount of converted energymainly converted potential energymay surpass the amount of kinetic energy of the flow engaged by the turbine runner.

A wave powered electricity generator is provided. Waves are separated from a floating platform unit by using a partition plate unit so that the floating platform unit enclosed by the partition plate unit is almost no wave. The waves outside the partition plate unit are to move many floating ball units up and down so that the racks provided on each of the floating ball units are capable of rotating the gears extending from the floating platform unit, and the rotational forces of gears are regulated through ratchets and consolidated to produce a power for driving generators. The racks on the floating ball units and the gears on the floating platform unit are pulled together by using springs. The resilient force of the two springs simultaneously helps the rack's up and down in smooth reciprocating motion. Then the gears directly and indirectly output a force to drive generators.

This system includes a belt drive system for a wind turbine generator comprising: a tower having a wind turbine wheel rotatably attached to the tower; a generator platform attached to the tower; a generator supported by the generator platform; and, a turbine drive belt adapted to engaged with the wind turbine wheel and the generator to transfer rotational energy from the wind turbine wheel to the generator to generate electricity.

A blade pitch drive comprising a driver sprocket, a driven sprocket, a toothed belt trained between the driver sprocket and driven sprocket, the toothed belt having a free span between the driver sprocket and driven sprocket, the free span having an arcuate form when the free span is in a slack condition, the toothed belt having a second span between the driver sprocket and driven sprocket in a tight condition when the free span is in a slack condition, and the free span operable as the second span and the second span operable as the free span according to an operating direction of the drive.

The present invention relates to a hydroelectric power generation device using a multistage cascade structure. The hydroelectric power generation device includes: a support (10) having a predetermined length and installed in a vertical direction; a plurality of waterwheels (20) each including a horizontal axle (21) rotatably installed on the support (10) and a plurality of buckets (22) radially arranged around the axle (21); upper and lower water tanks (30, 40) respectively installed on upper and lower portions of the support (10) and respectively containing predetermined amounts of water; a pump (50) installed in the lower water tank (40) to supply water from the lower water tank (40) to the upper water tank (30); generators (60) respectively installed on the axles (21) of the waterwheels (20); and a charging battery (70) configured to store electricity produced by the generators (60). Thus, according to the present invention, electricity can be stably and effectively produced.

A hydrokinetic generator including: a submersible housing defining a conduit therethrough for the flow of a fluid; a turbine mounted to the housing comprising at least one impeller located in the conduit for rotation by said flow; and at least one electrical generator coupled to the at least one turbine for converting mechanical energy from the turbine to electrical energy, the electrical generator including a plurality of elongate members bearing one or more magnetic regions, the elongate members being disposed about the at least one impeller and fast therewith; and a number of windings located within material of the housing and arranged for electromagnetic interaction with said magnetic regions whereby in use rotation of the impeller moves the magnetic regions past the windings to thereby induce an electrical current in the windings. The impeller may comprise a plurality of spiral, helical blades disposed about a common axle from a leading end thereof to a trailing end wherein a radius of the blades increases exponentially from the leading end to the trailing end.

A floating drum turbine is used for generating the electrical energy from the kinetic energy of a water stream (sea wave or river flow) that provides the mechanical energy needed to rotate an electrical generator for generating the electricity. The drum turbine is installed on a buoyant skid anchored to the seabed by some chains/ropes to keep it in a fixed position and direction along the water stream. The turbine is coupled to an electrical generator with a power transmission system, and generates the electricity that is transferred to the coast using a cable system floated on the water surface.