RU2775945C1 - Wave unit - Google Patents

Abstract

FIELD: hydraulics.

SUBSTANCE: invention relates to the field of hydraulic power engineering, in particular, to wave units. Wave unit comprises two vertically secured risers 2, a floating hydraulic generator 1 including a turbine 2 and two same-type first blocks 4 installed on the risers 2, second blocks 7, a third block, a controlled pump 10, cables 11 or chains. The blocks 4 are secured at the ends of the turbine 2 through bearings. Generators and float chambers are placed in the sealed compartments of the blocks 4. The blocks 7 include a reducer gearbox with an input pulley 8 and a generator. The third block includes electrical equipment and is connected by cables with blocks 4 and 7 and with electricity consumers. The pump 10 is connected by hoses with the float chambers of blocks 4 and with the cavities of loads 6 placed in the risers 2, made in the form of a pipe, configured to move therein. Cables 11 or chains are secured on blocks 4 bypassing the pulleys 8 of the blocks 7, and secured on the loads 6 in the risers 5.

EFFECT: efficient use of wind, water flow and wave energy.

3 cl, 4 dwg

Description

The field of technology.

The present invention relates to hydropower, in particular to wave installations.

The level of technology.

Due to the limited reserves of hydrocarbons on the planet, the efforts of many companies are currently directed to the development of devices that convert the renewable energy of wind and water into available useful energy.

From the existing prior art, a surf hydroelectric power plant is known, patent RU 2478826 C1, containing a platform with a slot fixed on the surface of the sea in its coastal strip, a rotary installation placed in the slot of the platform with part of it under water and consisting of two rotors mirrored on a common a shaft mechanically connected to the shaft of the electric generator, each of which is made in the form of a disk with blades in the form of aerodynamic wings located with a gap relative to the common shaft, two fairings, each of which is installed on a common shaft in front of the corresponding rotor and covers the gap between the inner edges of the blades, and two confusers, and an additional submerged platform fixed in front of the platform from the sea side, moreover, the ends of the rotor blades are made beveled to the axis of the common shaft, and the confusers are installed on the peripheral parts of the ends of the rotor blades with the formation of a gap with the corresponding fairing.

The invention relates to energy, in particular to surf hydro wind power plants, and is intended to generate electricity by converting the energy of the surf flow and the energy of low tides off the coast of seas, oceans and large bodies of water, as well as the energy of the air flow.

Known hydroelectric power plant has the following disadvantages:

In a hydro wind power station, there is no possibility of orienting it in the direction of wind and waves, as a result, the efficiency of its use is reduced. The flows of water and wind behind the rotor blades rest against the transverse disk of the rotor, so the speed of these flows decreases, and the counterpressure of water and air in front of the rotor increases, which reduces the efficiency of the rotor. The platform with the equipment and the submerged platform are rigidly fixed, therefore, at sea ebb and flow, the water level can be either under the rotors or above the rotors, which also reduces the efficiency of the rotors. The rotor is immersed in water by about one third of its diameter and operates from water flows formed by the working and submerged platforms, and at the same time from wind flows. Therefore, the design of this rotor is not adapted to work with large waves. The hydro wind power plant is not protected from large waves during storms, which reduces its reliability.

Known wave power plant, patent RU 2443900 C1. The invention relates to renewable energy sources, in particular for generating electricity by using the energy of sea waves due to the resulting vertical rises and falls of waves. The wave power plant includes an energy converter containing a system of gears enclosed in a housing fixed on a support above the water surface with the possibility of rotation around a vertical axis, a lever, which at one end is connected to the gear system through a one-way rotation mechanism, and at the other end to a cylindrical float. The float is equipped with a wave plumage for orientation in the direction of the waves and freely rotates on the axis of the lever, compensating for differences in wave forces at the ends of the float. The generator is fixed on a support above the water surface and is connected to an energy converter. The invention makes it possible to orient the float in the direction of the waves and more efficiently convert the energy of sea waves, and is also distinguished by its simple design.

The known invention has the following disadvantages:

For a float to oscillate synchronously with low waves, it must be light and therefore small in size, but at the same time it will perceive only a small part of the wave energy, i.e. the power plant will be small and inefficient. The energy of the translational motion of the wave is practically not used. The high kinetic energy of low waves with a long wavelength is also practically not used due to the small amplitude of the float movement, while the operation of the generator requires a bulky gearbox with a large gear ratio of revolutions. Due to these shortcomings, the known wave power plant does not effectively convert the energy of sea waves.

The closest set of features to the claimed invention is a wave installation for generating electrical energy, patent RU 2410566 C2. The invention relates to the field of hydropower and is intended to produce electrical energy by converting the kinetic energy of sea waves into electrical energy. The wave installation contains an impeller, a generator and a wave receiver located behind the impeller in the direction of the waves. Wave receiver at one end is pivotally connected to the support on the shore, and the other end is rigidly connected to the pontoon with the help of holders. The impeller is rigidly fixed to the pontoon by means of holders.

The objective of the invention is the most complete use of the kinetic energy of sea waves in the production of electricity.

The incoming wave rises with the help of a pontoon onto the impeller, which gives it a rotational motion. Then the wave passes to the wave collector, moves to its end and rolls in the opposite direction along the wave collector to the lower part of the impeller, causing it to rotate.

The known invention has the following disadvantages:

Wave installation can be used with a narrow range of wave heights. A high wave will cover the entire installation. The crest of the wave after the collapse on the wave receiver will press the oscillating part of the installation to the support. In this case, the installation will be subjected to significant force effects. Storm protection for the installation is not provided. The energy of low waves that do not cover the impeller is practically not used. During the return stroke, the wave spreads from the wave receiver, and its energy decreases significantly. In addition, due to the ebb and flow of the tides, the wave receiver, when lowering or rising, can be installed almost across the wave, thereby losing its functional purpose.

Due to these shortcomings, the known wave installation does not efficiently convert the energy of a moving sea wave and is not sufficiently reliable.

When studying the distinguishing features of analogues of the invention, no solutions have been identified that allow simultaneously converting the kinetic energy of wind, water flows and horizontal movement of waves into electrical energy on a fairly simple and reliable installation.

Disclosure of the essence of the invention.

The technical problem is to simultaneously convert the kinetic energy of the wind, water flows and horizontal movement of waves into electrical energy.

The technical result of solving the proposed problem is to increase the output power of the wave installation due to the simultaneous conversion of the kinetic energy of the wind, water flows and the horizontal movement of waves into electrical energy in a fairly simple and reliable installation.

The specified technical result, in the implementation of the invention, is achieved by the fact that the wave installation contains two risers fixed vertically; a floating hydrogenerator, including a turbine and two identical first blocks, fixed through bearings at the ends of the turbine, in the hermetic compartments of which generators are placed, and float chambers; second blocks installed on the risers, including a gearbox with an input pulley and a generator; the third block, including electrical equipment and connected by cables with the first blocks, the second blocks and consumers of electricity; a controlled pump connected by hoses to the float chambers of the first blocks and to the cavities of the goods placed in the risers, made in the form of a pipe with the possibility of movement in it; cables or chains fixed on the first blocks, bending around the pulleys of the second blocks and fixed on the loads in the risers.

The specified technical result in the implementation of the invention is achieved by the fact that in the wave installation, the rotation of the turbine blades around their axes is limited by stops, and the working part of the blade is floating, and the opposite part of the blade is used as a load.

The specified technical result in the implementation of the invention is achieved by the fact that in the wave installation the float chambers of the hydrogenerator and the load cavity on the cable are connected by hoses to a controlled pump.

The solution to the problem of converting the kinetic energy of wind and water flow into electrical energy is implemented in the proposed wave plant, the auxiliary equipment of which is located on two risers fixed on the seabed, and which contains a floating hydro generator with a rotating turbine.

In the proposed installation, waves, water flows and wind pass freely between two risers, act on the upper blades of the hydro generator turbine and rotate it. The rotation of the turbine is transmitted to the gearboxes and generators located in the sealed compartments of the hydrogenerator.

The conversion of the kinetic energy of the horizontal movement of waves into electrical energy is realized due to the displacement of the hydrogenerator when the wave runs on it. With horizontal movement, the wave acts on the turbine, accelerates its rotation and drags the hydrogenerator along with it. The reverse movement of the hydrogenerator is carried out under the action of loads placed in tubular risers and cables connected to the hydrogenerators, while the speed of rotation of the turbine also increases. The reciprocating motion of the cables is transmitted to the gearboxes and generators placed on the risers.

The resistance of water to the rotation of the turbine is reduced due to the rotary blades.

Immersion of the hydrogenerator, depending on the height of the waves, is carried out by changing its weight due to the injection of water into the sealed compartments of the turbine or the discharge of water from its compartments. During a storm, the hydro generator can be lowered to the bottom of the sea.

The optimal stroke of the hydrogenerator at different wave heights is controlled by changing the weight of the cargo in the risers by filling the cargo cavities with water to a certain level.

The essence of the invention is illustrated in the drawings of one of the variants of the wave installation containing two risers, which is given as an example to explain the principle of operation of the claimed wave installation.

Figure 1 shows the installation diagram, top view.

figure 2 shows a diagram of the installation, side view.

figure 3 shows a diagram of the turbine, a cross section.

figure 4 shows a diagram of the turbine, top view.

The wave installation contains a floating hydrogenerator 1, which includes a turbine 2 with blades 3 and the first two blocks 4. A gearbox, a generator and a float chamber are mounted in the hermetic compartments of the blocks 4. Blocks 4 are connected through bearings to the turbine shaft 2 at its ends. The installation contains two risers 5. Each riser is fixed vertically and is a pipe in which the load 6 moves. The second blocks 7 are mounted on the risers, containing a gearbox with an input pulley 8 and a generator; the third block 9 containing the necessary electrical equipment and connected by cables to the blocks 4 of the hydrogenerator 1, blocks 7 and consumers of electricity; controlled pump 10, connected by hoses to the float chambers of blocks 4 and to the cavity of loads 6. Cables 11 or chains are fixed at one end on the first blocks 4, at the other end are fixed on loads 6 in risers 5 and envelope pulleys 8 of the second blocks 7.

The rotation of the blades 3 of the turbine 2 around their axes is limited by stops, and the working part of the blade is floating, and the opposite part of the blade is used as a load.

The weight of the hydrogenerator 1 and load 6 on the cable 11 is quickly regulated by the supply of water from the pump 10 to the float cavity of the hydrogenerator and into the cargo cavity.

The operation of the wave installation is carried out as follows:

When the turbine 2 rotates, its upper blades 3 rotate around its axis in such a way that the weighted part of the blade goes down, and the working part of the blade floats up and is installed across the movement of wind or water, and further rotation of the blade is limited by a stop. When a wave runs on the hydrogenerator 1, its crest, overflowing the turbine 2 from above, increases the speed of rotation of the turbine, and at the same time the wave carries the hydrogenerator 1 along with it. The rotation of the turbine through the gearboxes is transmitted to the generators in the first blocks 4 of the hydro generator 1. The displacement of the hydro generator 1 through the chains or cables 11, the enveloping pulleys 8 of the blocks 7, is transmitted to the loads 6. The loads 6, rising from the water, smoothly stop the hydro generator 1 by increasing their weight and then, lowering, return it to its original position. Before stopping, the loads 6 are lowered onto the movable platform 12, slow down and stop smoothly. Alternating movements of cables 11 through pulleys 8 and gearboxes are transmitted to generators in blocks 7. Electricity flows from blocks 4 and blocks 6 are converted in block 9 and transmitted by cable to the consumer. The pumps 10 can be remotely controlled by cable signals. Based on these signals, pumps regulate the amount of water in the float chamber of blocks 4, which makes it possible to deepen the hydrogenerator 1, depending on the height of the waves, as well as lowering it to the bottom before a storm and lifting it after a storm. In addition, with the help of pumps 10, it is possible to adjust the weight of loads 6 in pipes 5 by filling the cavities of the loads with water, which makes it possible to maintain the optimal running of the hydro generator 1 at different wave heights.

As a result, the energy of a tail wind, waves and the energy of the horizontal movement of waves are used to generate electrical energy.

Information confirming the possibility of carrying out the invention with obtaining the specified result is as follows:

The proposed version of the wave installation may be preferable if it is oriented along the most probable direction of wind and waves. When the wind and waves shift relative to the most probable direction, the reliability of the joint operation of the cable and pulleys is ensured by a pair of vertical rollers installed in front of the pulley 8 on both sides of the cable. The wind generator takes a stable position relative to the water level when the float chambers are placed at the ends of the hydro generator. In the proposed version of the wave installation, the cable to the generator and the hose with water for the hydroelectric generator chamber can be laid directly along the seabed.

The stability of the riser 5 can be increased by installing an additional pulley at its base. To do this, the cable 11 coming from the hydro generator 1 goes around an additional pulley, then goes around the pulley 8 and is attached to the load 6 in the pipe 5.

When waves act on the hydrogenerator, its movement should begin with increased acceleration in order to keep up with the wave, and the end of the movement should begin with increased deceleration. Its reverse movement to its original state should begin with great acceleration in order to have time to take its original position and then smoothly end. For this purpose, the movement of a load in a pipe partially filled with water was used. The beginning of lifting the load upwards is facilitated by the movement of the load in the water, with a free flow of water into the lower part of the pipe. Before the end of the lift, the load leaves the water and stops the hydro generator with increased force, and then pulls it to its original position with increased acceleration. Before stopping, the load is lowered onto the movable platform 12, dampens the speed and stops smoothly.

When operating a wave installation on a river, equipment is used that is associated with the rotation of a turbine. The first unit 4 can be mounted on a platform and connected to a chain driven turbine.

Claims (3)

1. A wave plant containing a riser fixed vertically and a floating hydro generator, including a turbine and a first block fixed through bearings at the end of the turbine and including a generator, characterized in that the installation is equipped with a second riser, and the floating hydro generator is equipped with an additional first block of the same type, including a generator fixed through bearings at the other end of the turbine, and float chambers included in the first blocks; second blocks installed on the risers, including a gearbox with an input pulley and a generator; the third block, including electrical equipment and connected by cables with the first blocks, the second blocks and consumers of electricity; a controlled pump connected by hoses to the float chambers of the first blocks and to the cavities of the goods placed in the risers, made in the form of a pipe with the possibility of movement in it; cables or chains fixed on the first blocks, bending around the pulleys of the second blocks and fixed on the loads in the risers. 2. Wave installation according to claim 1, characterized in that the rotation of the turbine blades around their axes is limited by stops, and the working part of the blade is floating, and the opposite part of the blade is used as a load. 3. Wave installation according to claim 1, characterized in that the float chambers of the hydrogenerator and the load cavity on the cable are connected by hoses to a controlled pump.

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