RU2085759C1 - Wave hydroelectric station - Google Patents

Abstract

FIELD: hydraulic power engineering; wave hydroelectric stations. SUBSTANCE: wave hydroelectric station has equal arm lever with floats at ends rocking about horizontal axle placed in its middle, and electric generator coupled with lever through connecting members. Level is made of variable length by means of power hydraulic cylinder on axle of which at least two different length levers can be installed. EFFECT: enlarged operating capabilities. 2 cl, 5 dwg

Description

 The invention relates to hydropower, in particular to hydropower plants using the energy of waves that occur on the surface of the seas, oceans and other large reservoirs of natural or artificial origin.

 Hydroelectric power plants using wave energy are known.

 The well-known wave hydroelectric power station (USSR patent N 4950, class F 03 B 13/12, 1928) has spherical-shaped floats that are pivotally attached to brackets mounted on a frame moved along the dam. The floats set in motion spring-loaded pistons moving in cylinders also connected to the frame and equipped with holes for filling them with water and telescopic discharge pipes for supplying pressure water to the turbine. The latter is mounted on the crest of the dam, and the frame on its wall facing the open sea. In the initial position, the cylinders are filled with water, and the pistons and the floats connected with them pivotally using the levers are in the leftmost position. Under the influence of the incident wave, the floats approach the dam wall and, compressing the water in the cylinders with the pistons, pump it upward through the telescopic tubes to the turbine, which, rotating, drives the electric generator.

 The wave energy converter is mounted on a special dam, which also serves to install a hydraulic turbine and an associated electric generator, which leads to design complexity.

 The specified disadvantage is eliminated in wave hydroelectric power plants without dams.

 The well-known wave hydroelectric power station (Japanese patent N 55-46510, class E 03 B 13/12, 1980) consists of a float floating on the surface of the water, a single-cylinder reciprocating compressor and a turbine connected to it, mounted above the water on a stationary platform.

 The float is equipped with a vertical rod moving in guides, the upper end of which is pivotally connected to a swinging unequal arm, whose axis in the form of a spherical hinge, in turn, can move in horizontal guides.

 The second end of the unequal lever is pivotally connected to the piston rod moving reciprocatingly in the compressor cylinder. The vertical piston rod is also provided with guides.

 Compressed air from the compressor is directed to a turbine, which drives a working machine, such as an electric generator.

 The complexity of the kinematic connection between the float and the compressor installed on the platform leads to the complexity of the design.

 Unreliability of work arises as a result of the possibility of jamming of the rod in the guides on a wave.

 Closest to the invention is a wave power station described in the application of France N 2467999, CL. F 03 B 13/12, 1981, and comprising a lever with floats at the ends, swinging around a horizontal axis mounted in the middle of the axis and connected to it through the connecting elements by an electric generator.

 When changing the wavelength, the greatest efficiency of the wave hydroelectric power station is not always ensured when one of the lever floats is on the wave crest and the other in the cavity.

 The objective of the invention is the ability to obtain maximum efficiency in a wide range of wavelengths used.

 This is achieved due to the fact that the lever is made of variable length using a power hydraulic cylinder, while at least two levers of different lengths can be installed on the axis of the lever.

 In FIG. 1 shows a general view of a wave hydroelectric power station in a starting position in front; in FIG. 2, the plan of FIG. one; in FIG. 3, view A in FIG. 2; in FIG. 4 is a perspective view of a piston pump; in FIG. 5 view B in FIG. 4.

 The wave hydroelectric power station consists of two vertical supports 1, which are mounted in the wave zone at a certain distance from each other and partially protrude above the water surface with a horizontal axis 2 installed between them in the upper part of the supports, around which two equal-arm levers 3 and 4 of different lengths can swing with floats 5 at the ends and power cylinders 6 and 7 in the center.

 On the platform above the water level, piston pumps 9 are installed on the frames 8, which, on the one hand, are connected to the latter with the help of rods, as well as clamps 10 and trunnions 11, located on the floats 5, and with the help of compensators 12, an intake manifold 13 and a pressure head the collector 14 is connected to the sea and a hydraulic turbine 15, which, in turn, is connected to an electric generator 16.

 The direction of the alignment in which both supports are located is perpendicular to the direction of wave movement prevailing at the installation site of the hydroelectric power station.

 Vertical supports 1 are designed for mounting the axis 2 and are piles of arbitrary cross-section, for example square, in the upper part of which there is one through hole for the axis to pass.

 Axis 2 is used for the possibility of rolling equal-arm levers 3 and 4 with floats 5 and power hydraulic cylinders 6 and 7 in accordance with the frequency of the waves and is fixed horizontally in the upper part of the supports 1 located at the ends of the axis using fasteners.

 The height of the axis 2 from the level of the calm surface of the sea (in calm) is equal to the difference between the radius of the floats and the height of their waterline.

 The equal-arm levers 3 and 4 are designed for fixed adjustable connection of the floats 5 to each other and their independent rolling around axis 2 with a wave frequency.

 The length of each lever is determined by the length of the calculated wave of the sinusoidal profile, in which one of its floats is on top of the wave crest, the other in the middle of the cavity, and the piston stroke of the corresponding piston pumps is maximum.

 The levers have a telescopic design and consist of a tubular central part with an opening in the middle for passing the axis 2 and two symmetrically located side rods entering it from the ends, on the outer ends of which floats 5 are installed.

 Above, on the central parts of equal arms levers 3 and 4, there are brackets for fastening the power hydraulic cylinders 6 and 7, the rods of which, in turn, are attached to the side rods.

 The floats 5 are used to create buoyancy forces and adhesion forces with the liquid. In addition, when rolling equal arms levers 3 and 4, the floats move reciprocating in the horizontal direction.

 The floats 5 are closed hollow containers of arbitrary, for example spherical, shape, which are attached to the ends of the levers.

 To transfer the arising forces to the piston pump rods 9, each float has two horizontally arranged trunnions 11 pivotally connected to an arc-shaped clamp 10.

 Power hydraulic cylinders 6 and 7 with two pistons and rods each are designed to change the length of the equal-arm levers 3 and 4 by simultaneous symmetrical longitudinal movement of the side rods in the tubular central parts of the levers, which makes it possible to stabilize the load of the wave hydroelectric power station when the wave force changes.

 Cases of hydraulic cylinders are fixedly mounted from above on the central parts of the levers using brackets, and the ends of the rods with pistons to the side rods.

 The dimensions of the power hydraulic cylinders 6 and 7 are determined by the length of the equal-arm levers and the degree of its regulation.

 Frames 8 are used for movable mounting of piston pumps 9 at a site above the water level in order to compensate for the reciprocating movement in the horizontal direction of the floats 5 when they swing on the levers 3 and 4 around axis 2 during the operation of the wave hydroelectric station and are each two U-shaped structures facing the platform with cross members and interconnected in the upper part with lateral plates with two horizontal grooves for the passage of the trunnions of piston pumps.

 Piston pumps are installed between the U-shaped structures, and in the area below them there are grooves for the passage of the rods connecting the pumps to the floats.

 Piston pumps 9 are movably mounted on pins between the U-shaped structures of the frames 8 with the possibility of reciprocating movement in the horizontal direction and consist of each cylinder 17 with pins 18 and a cover 19, a piston 20 with a rod 21, bodies 22 and 23 of valve boxes with covers 24 and 25, pipelines 26 29, poppet suction valves 30 and 31, and pressure valves 32 and 33, springs 34 and 35, a suction manifold 36, and a pressure manifold 37.

 In the vertically located cylinder 17, the bottom end is open and provided with a flange for attaching the cover 19, and on the lateral surface outside in the middle there are two horizontally spaced axles 18 for movable mounting of the cylinder in the grooves of the frame 8.

At an angle of 90 ^o in plan, two windows are made on the side surface for connecting its inner cavity to the valve box bodies 22 and 23, and on the opposite side there are brackets for mounting the suction manifold 36 and the pressure manifold 37.

 For mounting the piston 20 with the stem 21 on the cylinder there is a flange cover 19. The stem is passed into the cylinder 17 through an opening with an oil seal located in the center of the cover.

 The cylinder for alternating connection with the suction manifold 36 and the discharge of pressurized water into the pressure manifold 37 is equipped with two valve boxes located in the window area.

 Cases 22 and 23 of the valve boxes are made in the form of vertically arranged rectangular prisms, which have a bottom on the side of the windows, and on the opposite side are open and divided into two equal parts by horizontal partitions.

 The open and closed ends of the housings are provided with flanges for attaching the covers 24 and 25 and connecting to the cylinder 17.

 For mounting the suction valves 30 and 31, the discharge valves 32 and 33 and the springs 34 and 35 in the bodies 22 and 23 there are flange covers 24 and 25.

 All flange connections along the perimeter of the abutment and horizontal partitions from the side of the covers are sealed with elastic gaskets.

 In the front side walls of the housings 22 and 23 above the horizontal partitions, there is one hole for connecting by pipelines 26 and 27 to the suction pipe 36, and in the bottom with the inner cavity of the cylinder.

 Similar openings in predetermined side walls and the bottom are below the horizontal partitions and respectively serve to connect the valve boxes using pipelines 28 and 29 to the pressure manifold 37 and drain water under pressure from the inner cavity of the cylinder 17.

 The holes in the bottom of the valve body housings are closed by poppet suction valves 30 and 31 and discharge valves 32 and 33.

 The suction valves are pressed against the inlet by means of springs 34 fixed at one end with washers and cotter pins on the valve stems 30 and 31, and the other resting against the bottom of the housings 22 and 23.

 The pressure valves are pressed against the outlet openings by means of springs 35 resting against one end of the valve plates 32 and 33, and the other by the covers 24 and 25 of the valve boxes.

 Inside the cylinder 17 there is a piston 20, which is fixedly fixed in the middle of the upper thickened part of the rod 21 and can move reciprocating in the vertical direction (working stroke), while simultaneously making small reciprocating movements in the horizontal direction under the action of one of the floats 5, swinging on the corresponding lever around axis 2.

 Thickened parts of the rod on both sides of the piston are stops that limit the movement of the piston 20 in the area of the windows.

Outside the cylinder 17, on the side surface at an angle of 150 ^o in plan with respect to the windows, there is a suction collector 36, which is connected to the suction collector 13 of the wave hydroelectric power station by means of a compensator 12, and the latter to the sea.

 The suction manifold is designed to supply water into the internal cavity of the cylinder and is a vertical pipe closed from both ends, which is attached to the brackets 17 on the brackets and has holes and a pipe in the lower part.

 The holes are used to connect using pipelines 26 and 27 to the valve body housings 22 and 23, and a pipe for articulation with a compensator.

Outside the cylinder 17, on the lateral surface at an angle of 180 ^° in the plan relative to the axis of the windows, there is a pressure collector 37, which is connected to a pressure collector of a wave hydroelectric power station by means of a compensator 12, and the latter with a turbine 15.

 The pressure header is designed to collect water under pressure from the internal cavity of the cylinder and is a vertical pipe closed at both ends, which is attached to the brackets 17 on the brackets and has two holes and a pipe in the lower part.

 The holes are used to connect using pipelines 28 and 29 to the valve body housings 22 and 23, and a pipe for articulation with a compensator.

 The clamps 10 are designed to connect the rods 21 of the piston pumps 9 with the floats 5. The clamps are made in the form of rigid arc-shaped structures, which are fixedly attached to the rods in the middle and pivotally connected to the trunnions 11 of the floats.

 Compensators 12 serve to swivel the suction collector 35 and the pressure manifold 37 of the piston pumps 9 with the suction collector 13 and the pressure collector 14 of the wave hydroelectric station, and with the help of the sea and the turbine 15, respectively.

 Compensators are 3-hinged pipelines with two end and one intermediate hinges.

 The pipes of the compensators 12 are located at certain sharp angles, at the tops of which there are intermediate hinges, so that they can rotate around the hinges and, changing the angles, and at the same time the distance between the end hinges, which are attached to the nozzles of the manifolds 36 and 37 of the movable piston pumps 9 or fixed manifolds 13 and 14 wave hydroelectric power station.

 The suction collector 13 of the wave hydroelectric power station is designed to supply water from the sea to the suction manifolds 36 of the piston pumps 9 using compensators 12 and are a pipeline with nozzles to which end hinges of the corresponding compensators are attached.

 The pressure collector 14 of the wave hydroelectric power station serves to collect the pressurized water coming from the pressure collectors 37 of the piston pumps 9 using compensators 12, as well as supply it to the hydraulic turbine 15 and is a pipeline with nozzles to which the end hinges of the corresponding compensators are attached.

 The turbine 15 is connected to an electric generator 16, which is designed to produce electricity.

 Hydroelectric power works as follows.

 In the initial position, the piston pumps 9, the collectors 36 and 37 of the pumps, the collectors 13 and 14 of the hydroelectric power station, the expansion joints 12 and the turbine 15 are filled with water.

 Let us consider the operation of an equal-arm lever 3 with floats 5 at the ends and piston pumps 9 connected to them at a wave with a wavelength calculated for this lever, at which the left float is at the top of the wave crest, the right one in the middle of the cavity, and the piston stroke of the pumps is maximum.

 In this case, the side rods of the lever 3 are partially extended from the tubular central part by an amount equal to half the stroke of each of the pistons of the power hydraulic cylinder 6, and the trunnions of the bodies of the piston pumps 9 in the longitudinal grooves of the frames 8 are in the middle position.

 During the passage of the wave from right to left, the equal-arm lever 4 begins to rotate around the axis 2 counterclockwise as a result of the fact that the left float 5 lowers along the wave slope from the ridge into the cavity along a circular arc with a radius equal to the distance between the centers of the axis and the float to a height equal to the height of the calculated wave, and the right float 5 at this time rises from the cavity to the crest of the incident wave along the same path.

 At the same time, both floats make small reciprocating movements in the horizontal direction.

 The piston 19 located in the extreme upper position with the rod 20 of the piston pump 9 connected to the left float 5 starts to lower, and the pump on the pins moves along the grooves of the frame 8 from the middle position to the extreme left (at the time the float passes the calm sea level) and back making a reciprocating motion. In this case, as the pressure increases in the lower part of the cylinder 17, the spring 35 of the pressure valve 33 is compressed, the valve opens and water under pressure through the valve box body 23, the pipeline 29, the pressure manifold 37, the compensator 12, and the pressure manifold 14 enters the turbine 15, causing rotation hydraulic turbines and associated electric generator 16.

 At the same time, the spring 34 of the suction valve 30 is compressed in the upper part of the cylinder under the action of rarefaction, the valve opens, and water from the sea through the suction manifold 13, compensator 12, the suction manifold 36, the pipeline 26 and the valve box body 22 enters the cylinder 17.

 When lowering the left float 5 along the slope of the wave from the ridge to the cavity, the sharp angles between the movable pipes at the tops of the compensators 12 first increase and then decrease again to the initial value, compensating for periodic changes in the distances between the collectors 36 and 37 of the piston pump 9, pivotally connected to the left float and fixed reservoirs 13 and 14 of the wave hydroelectric power station.

 During the passage of the wave from right to left, the equal-arm lever 3 begins to rotate around the axis 2 counterclockwise as a result of the fact that the right float 5 rises along the wave slope from the depression to the crest along an arc of a circle with a radius equal to the distance between the centers of the axis and the float to a height equal to the height of the calculated wave, and the left float 5 at this time descends from the ridge into the cavity of the incident wave along the same path.

 At the same time, both floats make small reciprocating movements in the horizontal direction.

 The piston 19 located in the lowermost position with the piston pump rod 21 connected to the right float 5 starts to rise, and the pump on the pins moves along the grooves of the frame 8 from the middle position to the extreme right (at the time the float passes the level of the calm sea) and back making reciprocating movements.

 In this case, as the pressure increases in the upper part of the cylinder 17, the spring 35 of the discharge valve 32 is compressed, the valve opens and water under pressure through the valve box housing 22, the pipeline 28, the pressure collector 37, the compensator 12, and the pressure manifold 14 enters the turbine 15, causing the rotation of the turbine and associated hydrogenerator 16.

 At the same time, the spring 34 of the suction valve 31 is compressed in the lower part of the cylinder under the action of vacuum, the valve opens, and water from the sea through the suction manifold 13, compensator 12, the suction manifold 36, the pipeline 27 and the valve box body 23 enters the cylinder 17.

 When lifting the right float 5 along the slope of the wave from the depression to the crest, the sharp angles between the movable pipes at the tops of the compensators 12 first increase and then decrease again to the initial value, compensating for periodic changes in the distances between the collectors 36 and 37 of the piston pump 9, pivotally connected to the right float and fixed reservoirs 13 and 14 of the wave hydroelectric power station.

 Further, the above cycle is repeated continuously.

 When the wavelength increases above the calculated for the equal-arm lever 3, the side rods begin to move inside the tubular cylindrical part with the help of pistons and rods of the power hydraulic cylinder 6, the swing amplitude of the lever decreases and vice versa.

 In both cases, the load of the wave of the hydroelectric power station is stabilized.

 The equal-arm lever 4 with the floats 5 at the ends and the piston pumps 9 connected to them works in a wave with the wavelength calculated for this lever, at which the left float is at the top of the wave crest, the right one in the middle of the cavity, and the piston stroke of the pumps works the same way.

 The levers 3 and 4 swing about an axis 2 simultaneously and independently from each other with a wave frequency.

 Depending on the ratio of the lengths of the equal-arm levers, their floats of the same name 5 (left or right) can work in one phase (on the crests of the waves) or in opposite phases (one on the crest and the second in the cavity).

 All piston pumps 9 are connected in parallel and work on the collectors 13 and 14 of the wave hydroelectric power station.

 The arrangement of at least two floats at the ends of an equal-arm lever swinging around a horizontal axis allows to simplify the design and increase reliability.

 The implementation of a variable-length lever using a power hydraulic cylinder stabilizes the load of the wave hydroelectric power station when the wave strength changes.

 The installation on the axis of at least two equal arms of different lengths makes it possible to extend the lengths of the waves used.

Claims (2)

 1. A wave hydroelectric power station containing an equal arm with floats at the ends, swinging around a horizontal axis mounted in the middle and connected through an connecting element by an electric generator, characterized in that the lever is made of variable length using a power hydraulic cylinder.  2. Hydroelectric power station according to claim 1, characterized in that at least two levers of different lengths are installed on the axis.

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