RU2791367C1 - Wave plant - Google Patents

Abstract

FIELD: hydropower.

SUBSTANCE: invention relates to the field of hydropower, in particular to wave installations. The installation contains a support 1 with a cavity in which a load 2 with a cavity for water and an individual controlled pump is placed with the possibility of movement, a turntable 3, including the first block 4, containing the input pulley 5 and the cable drum 6 with the current collector 8, fixed on one shaft, and a gearbox with a generator, a second block 10 with electrical equipment, from the output of which a cable is led through the current collector 9 to the consumer of electricity, the third block 11, installed on a turntable at sea level and containing a pulley 13 for a cable 25 and a drum 16 placed under it for a cable 26, a hydrogenerator 19, two turbines 20 of which are fixed on one shaft 21, two float chambers 22 mounted on the ends of the shaft 21, a fourth block 23 mounted on the shaft 21 between the turbines 20 and containing a gearbox, a generator and a controlled pump 24 connected to the inlets of the chambers 22. A cable 26 and a cable 25 are attached to the hydrogenerator 19 and carried under the pulley 13, above the pulley 5 and the second end is attached to the load 2. The cable 26 is led under the drum 16, wound on the drum 6 and through the current collector 8 is brought into the block 10.

EFFECT: efficient use of wind energy, water flows and waves.

1 cl, 3 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 coastal hydroelectric installation is known (patent RU 2644793 C2) for generating electrical energy. The installation is located above the flow and contains a body section, a water wheel section, a movable power transmission section connected to the water wheel, and an electric power generation section. The body section contains a platform located above the flow at a certain distance from it. The water wheel section contains a support device, one end of which is held on the platform, a water wheel connected to the support device at a distance from the specified one end, and a float device connected to the support device with the possibility of separation from it and located under the water wheel. The movable section is connected to the water wheel and adapted to the position of the water wheel to transfer the flow energy. The generating section contains a generator connected to the movable section. The kinetic energy of the flow is extracted by the water wheel section and transferred to the generation section, which is adjusted to the height of the water level by the movable section. The invention is aimed at increasing the output power and reducing the risk of damage by the flow of the river.

The known installation has disadvantages:

In the installation, the wind flow and the horizontal pressure of the waves are not used. The installation works with a certain direction of water flow, when the direction of which changes, the efficiency of the installation drops sharply. When large waves run up, the water wheel may be under water and its rotation will slow down. There is no storm protection for the installation.

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:

The energy of the translational motion of the wave is 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. With weak waves, the force from the float plumage may not be sufficient to turn the hull on the support. Due to these shortcomings, the known wave power plant does not effectively convert the energy of sea waves.

Known surf hydroelectric (Patent 2478826 C1, prototype).

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 stream 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 stream. The surf hydro wind power plant contains a platform with a slot fixed on the sea surface in its coastal strip, a rotor installation placed in the slot of the platform with its part under water and consisting of two rotors mirrored on a common shaft mechanically connected to the electric generator shaft, each of which made in the form of a disk with blades in the form of aerodynamic wings located with a gap relative to a common shaft, two fairings, each of which is mounted 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 platform from the sea. The ends of the rotor blades are made beveled to the axis of the common shaft. 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 is aimed at increasing the completeness of the joint use of the energy of the surf flow, low tide and air flow, as well as simplifying the design of the surf wind power plant and its operation.

Known surf hydroelectric power plant has the following disadvantages:

The rotor, mounted on a fixed platform, does not track the direction of the wind and waves, as well as the water level at high and low tides, as a result, the efficiency of the hydro wind power plant is reduced. The rotor, installed across the movement of the waves, and the auxiliary equipment on the platform during a storm will experience large destructive loads. The diameter of the rotor with fixed blades is limited by the fact that with an increase in the depth of its immersion, the water flow rate decreases sharply and the water begins to slow down the rotor, so the proposed rotor can be used for a low-power hydro wind power plant. In front of the disk, a counter pressure is created on the rotor for the water and air flows, reducing the speed of rotation of the rotor.

In the study of the distinctive features of analogues of the invention, sufficiently simple solutions have not been identified that allow simultaneously converting the kinetic energy of wind, water flows and horizontal movement of waves into electrical energy.

Disclosure of the essence of the invention.

The solution of the task of converting the kinetic energy of wind, water flow and wave motion into electrical energy is implemented in the proposed wave installation, which is a support fixed on the seabed, containing a cavity in which a load hanging on a rope with a cavity for water and an individual controlled pump; a turntable mounted on top of the support and containing the first block, in which the input pulley of the gearbox connected to the generator is fixed on the shaft, and the cable drum with the current collector, and the gearbox with the generator, as well as the second block with electrical equipment, the cable from the output of which is passed through the current collector to the consumer of electricity; a third block placed on the turntable at sea level, containing a cable pulley and a cable drum placed under it; a hydrogenerator containing two turbines mounted on one shaft, two float chambers, which are placed through bearings at the ends of the shaft; the fourth block through the bearings mounted on the shaft between the turbines, containing a gearbox, a generator and a controlled pump connected to the inputs of the float chambers; a cable and a cable are attached to the hydroelectric generator, which is carried under the pulley of the third block, above the pulley of the first block and the second end is attached to the load in the support; the cable is led under the drum of the third block, wound on the drum of the first block and through the current collector is brought into the second block.

The wind and water flows rotate the turbines in the hydroelectric generator and the gearbox and generator associated with them. The voltage obtained at the output of the generator is transmitted through the cable through the current collector to the second unit. 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 turbines, accelerates the rotation of the turbines and drags the hydrogenerator along with it. The reverse movement of the hydro generator is carried out under the action of a load placed in a tubular support and connected to the hydro generator by a cable, while the speed of rotation of the turbine also increases. The reciprocating motion of the cable through the pulleys is transmitted to the gearbox and generator placed on the support in the first block.

Immersion of the hydrogenerator, depending on the height of the waves, is carried out by changing its weight by pumping water into the float chambers of the hydroelectric generator or draining water from them. During a storm, the hydroelectric generator can be lowered to the bottom of the sea on a stand hanging under it.

The optimal stroke of the hydrogenerator at different wave heights is controlled by changing the weight of the load in the riser by filling its cavity with water.

As a result, the energy of a tailwind, water flow and the energy of horizontal wave movement are used to generate electrical energy.

The essence of the invention is illustrated in the drawings of one of the options for a wave installation containing a support, which is given as an example to explain the principle of operation of the claimed wave installation.

In FIG. 1 shows the scheme of the installation, side view.

in fig. 2 shows the setup diagram, top view.

in fig. 3 shows the layout of the cable and cable in the third block.

Implementation of the invention.

Wave set contains:

Tubular support 1, fixed on the sea bottom, in the cavity of which the load 2 moves on a rope with a cavity for water and containing an individual controlled pump (not shown in the diagram). At the top of the support 1, a turntable 3 is mounted, on which the first block 4 is installed, containing the input pulley 5 and the cable drum 6 fixed on the same shaft and made with the same diameters, the gearbox with the generator 7, the first current collector 8, the second current collector 9 and the second block 10, containing electrical equipment. In the lower part of the platform at sea level, the third block 11 is installed, containing the first shaft 12 mounted in parallel with the pulleys 13 and 14 fixed on it and the second shaft 15 with the drum 16 and the pulley 17 fixed on it. The pulley 14 and the pulley 17 are covered by a flexible transmission 18 .Pulleys and drums rotate synchronously. The circumferential speeds of the pulley 13 and the drum 15 are the same. The rotation of the turntable around the support is carried out using a controlled electric motor through a worm-gear transmission (not shown in the diagram). Floating hydrogenerator 19 contains two turbines 20 of the same type with rotary blades mounted on one shaft 21, float chambers 22, through bearings mounted on the ends of the shaft 21, the fourth unit 23, located between the turbines 20 and through the bearings mounted on the shaft 21, containing a gearbox, a generator and a controlled pump 24, as well as a stand 27 located under the hydro generator 19. The cable 25, which at one end is attached to the fourth block 23, is held under the pulley 13 of the third block 11, above the pulley 5 of the first block 4 and the second end is attached to the load 2 in the support 1. Cable 26, connected to the output of the generator in the fourth block 23, goes around the drum 16, wound around the drum 6 and through the current collector 8 is brought into the block 10. The turntable 3 is connected to the support 1 through bearings and can be rotated around the support using a worm-gear transmission from a controlled electric motor (not shown in the diagram).

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

The incident wave penetrates through the holes in the wall of the support into its cavity. The load on the cable begins to float. The wave, having reached the hydrogenerator 19, overflows the top of the turbine 20, increases the speed of rotation of the turbines, and at the same time the wave drags the hydrogenerator 19 along with it. The rotation of the turbines 20 through the gearbox of the fourth block 23 is transmitted to the generator in the fourth block 23 of the hydro generator 19. The horizontal displacement of the hydro generator 19 through the cable 25, the enveloping pulley 13 in the block 11 and the pulley 5 in the block 4, is transmitted to the load 2. The load 2, rising from the water , due to the increase in its weight, smoothly stops the hydrogenerator 19 and then, lowering, returns it to its original position. The rise from the water and the lowering of the load 2 into the water occurs with a free flow of water between the support 1 and the load 2. In the lower part of the support cavity, the channel for the flow of water narrows and the load 2 stops smoothly. The alternating movement of the cable 25 through the pulley 5 and the gearbox is transmitted to the generator 7 in the block 4. The operation of the pumps in the block 23 and in the cargo cavity 2 can be controlled remotely using control signals. Based on these signals, using a controlled pump 24, the amount of water in the float chambers 22 is regulated, which makes it possible to deepen the hydrogenerator 19 depending on the height of the waves, as well as lower it to the bottom before a storm and raise it after a storm. When lowering, the hydrogenerator 19 rests on the bottom through the stand 27. In addition, with the help of an individual controlled pump, it is possible to adjust the weight of the load 2 in the support 1 by filling the cavity of the load with water or draining it, which makes it possible to maintain the optimal running of the hydrogenerator 19 at different wave heights. The controlled pump can pump water or compressed air. Air injection is carried out at the time when the hydrogenerator 19 under the action of the load 2 in the support 1 is returned to its original position. At this time, the wave leaves and the hydrogenerator 19 floats to the surface of the water. As a result, the energy of a tailwind, water flow and the energy of horizontal wave movement are used to generate electrical energy.

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

Linear speeds of rope pulleys and cable drums must be the same to avoid tensile forces on the cable. The length of the cable wound on the drum 6 must exceed the maximum displacement of the hydrogenerator 19.

Hydrogenerator 19 assumes a stable position relative to the water level when float chambers are placed at the ends of the hydrogenerator.

The working part of the blade is lighter than water, and the second half of the blade relative to its axis is heavier than water, so the blade at the top of the turbine is installed against the movement of wind and water flows, and the blade at the bottom of the turbine is pressed against it, reducing the resistance of water to the rotation of the turbine.

When waves act on the hydrogenerator 19, its movement must begin with increased acceleration in order to keep up with the wave, and the end of the movement must begin with increased braking. 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 the load 2 in the support 1 partially filled with water was used. The load begins to float when water flows freely into the lower part of the pipe. Before the completion of the lift, the load leaves the water and stops the hydro generator 19 with increased force, and then pulls it to its original position with increased acceleration. Before stopping, the flow of water between the pipe and the load is slowed down, and the load stops smoothly.

The controlled pump 24 of the block 23 can simultaneously or selectively fill the float chambers 22 with air or water, and the water is ejected through the check valve parallel to the axis of the hydrogenerator and from the hydrogenerator. It is possible that the wind blowing from the sea to the shore changes direction and begins to blow from the shore to the sea. In this case, the hydro generator may collide with the support. In this case, one of the float chambers is continuously filled with water. Under the action of the reactive force of the water jet, the hydrogenerator, held by the cable, rotates around the support and, synchronously with its rotation, the platform 4 is rotated using a controlled electric motor.

The cable is laid below the waves in order to avoid its kinks from the waves. During a storm, the float chambers are completely filled with water, and the hydroelectric generator sinks to the bottom, resting on a stand 27. When operating a wave installation on a river, equipment is used that is associated with the rotation of the turbine.

Claims (1)

A wave installation containing a support fixed on the sea bottom, on top of which a platform is installed, a generator and a gearbox connected to it, placed on the platform on one shaft, two turbines, characterized in that the installation includes the first, second, third and fourth blocks, the support contains a cavity , in which a load hanging on a rope with a cavity for water and an individual controlled pump is placed with the possibility of movement, the platform is made rotatable and includes the first block containing the input pulley of the gearbox and the cable drum with the current collector, fixed on one shaft, and the gearbox with the generator, as well as the second block with electrical equipment, from the output of which a cable is led through the current collector to the consumer of electricity, the third block is installed on a turntable at sea level and contains a pulley for the cable and a drum for the cable placed under it, a hydrogenerator, two turbines of which are fixed on one shaft, two float chambers mounted through bearings at the ends of the shaft, the fourth block is mounted on the shaft between the turbines through bearings and contains a gearbox, a generator and a controlled pump connected to the inlets of the float chambers, while a cable and a cable are attached to the hydro generator, which is carried under the pulley of the third block, above the pulley of the first block and the second end is attached to the load in the support, the cable is led under the drum of the third block, wound on the drum of the first block and through the current collector is brought into the second block.

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