RU2101562C1 - Wind-electric storage plant - Google Patents

Abstract

FIELD: wind-power engineering. SUBSTANCE: plant has several wind-power units each incorporating windmill coupled kinematically with compressor, as well as set of pipings for compressed air supply from wind-power units of turbines kinematically coupled with electric generators; it is also provided with flywheels having blades and additional compressors kinematically coupled with flywheels through engageable clutches; set of pipings has nozzles for feeding compressed air to flywheel and turbine blades, as well as gate valves, speed and pressure sensors controlling compressed air supply to turbine and flywheel blades. EFFECT: improved design. 6 dwg

Description

 The invention relates to wind energy, in particular to power plants capable of converting wind energy into electrical energy from large areas.

Known wind power station containing towers, installed on them wind motors and kinematically connected with the latest power generators [1]
However, this wind power station has low efficiency and cannot work in the absence of wind.

Known wind energy storage plant containing several wind power plants, each of which includes a wind turbine and a kinematically connected compressor, as well as a piping system for supplying compressed air from wind power plants to turbines kinematically connected to electric generators [2]
However, this wind storage power plant has low efficiency and limited operational capabilities.

 The invention is aimed at increasing the efficiency of a wind storage power plant, expanding operational capabilities and improving the environmental situation, because in addition, it is a means of light protection, wind protection and protection against the penetration of cold northerly winds into other areas.

 To solve this problem, a wind storage power plant containing several wind power plants, each of which includes a wind turbine and a kinematically connected compressor, as well as a piping system for supplying compressed air from the wind power plants to turbines kinematically connected to electric generators, is equipped with flywheels with blades and additional compressors kinematically connected to the flywheels using the included clutch, while the sleep piping system wife nozzles for supplying compressed air to the turbine vanes and flywheel, as well as valves and pressure sensors and the rotational speed for controlling the supply of compressed air to the turbine blades and flywheels.

 Figure 1 shows a block-modular diagram of a wind storage power plant located in a large area; figure 2 is a separate module of the wind storage power plant; figure 3 is a schematic diagram of a wind storage power plant; figure 4 wind power installation; figure 5 flywheel with a compressor; in Fig.6 view along arrow A in Fig.5.

The wind storage power plant contains a system of modules 1 interconnected by main pipelines 2, wind power plants 3 and air pipelines 4. The connection of the modules 1 creates a block-modular scheme, which can take the form of a grid covering large territories. Block-modular design may take the form of a closed line, which is located on the shores of the seas and oceans. The density of modules 1 in the general block-modular scheme depends on the availability of consumers of electric energy and the location of settlements. Each module 1 has a symbol in the form of A ₁ , A ₂ , A _n (modules of the first row), B ₁ , B ₂ , B _n (modules of the second row), etc. This branched block-modular scheme allows you to maneuver the air flow in the absence of wind in one area (for example, module K ₁ ) and strong wind in the areas of modules A ₁ and B ₁ . At the same time, part of the compressed air produced by the wind power plant through the air pipelines 4 and main pipelines 2 (these pipelines form a system of pipelines for supplying compressed air from the wind power plants to the turbines) is sent to the K ₁ module. This module can work if there is no wind in its environment.

 Each module 1 consists of several wind power plants 3, which are located around the module and connected to it through a piping system. Inside each module 1, a turbine 5 is installed, kinematically connected with an electric generator 6, flywheels 7 with blades 8, which convert the energy of compressed air into the kinetic energy of rotating flywheels.

 The wind power installation 3 consists of blades 9, a weather vane 10, a bevel gear 11, a vertical shaft 12, a crank 13, a compressor 14 and a metal structure 15. The compressor 14 has two cylinders in which the reciprocating movement of the pistons is converted into compressed air energy. Compressor 14 is installed at the base of the wind power installation. Compressed air from the compressor 14 through the exhaust valves enters the air pipe 4. Passing the check valve, the compressed air raises the pressure in the piping system, while the valve opens, which allows compressed air to enter the main pipe 2. The valves are controlled and the movement of compressed air is controlled by pressure sensors. The non-return valve serves to prevent the flow of compressed air from the main pipeline 2 to the wind power installation 3.

 Compressed air enters the turbine 5 through nozzles 16, which are evenly mounted around the turbine. A jet of compressed air acts on the turbine blades and spins it to a certain speed. In this case, the generator 6 generates electrical energy. Part of the compressed air through the nozzle 16 enters the blades 8 of the flywheel 7 (first flywheel), which also spins up to the nominal speed. The flywheel speed sensor switches the compressed air supply to the next flywheel. The unwinding of several (there may be three or more, it depends on the power of the power plant) of the flywheels allows you to convert the energy of compressed air into kinetic and accumulate this energy. After untwisting all the flywheels 7 of module 1, reducing the air pressure and rotational speed of the turbine, clutches 17 are turned on, which transfer the accumulated kinetic energy to the additional compressors 18. The compressed air from the additional compressor 18 passes through the pipeline 19 to the turbines 5 of the generators 6. Additional compressors 18 have a device similar to compressors 14.

 Wind storage power plant operates as follows.

If there is wind in the area of one of the modules 1, wind power plants 3 come into operation, which convert wind energy into compressed air energy. This is done in the compressor 14. Next, the compressed air enters the air pipe 4, in which it passes the non-return valve, interacts with the pressure sensor and, at its signal, the valve opens and the compressed air passes into the main pipe 2. From several wind power plants 3, the compressed air through the system pipelines goes to module 1 (for example, A ₁₀ , figure 2). The number of wind power plants adjacent to one module depends on the power of the power plant and can range from ten to several tens and hundreds. The main stream of compressed air is initially directed to the turbine 5, where, passing through the nozzle 16, it acts on the blades of the turbine 5, spinning it to a certain speed. Together with the turbine 5, a generator 6 rotates, which generates electrical energy. The frequency of rotation of the turbine 5 is automatically maintained by means of control equipment, which increases or decreases the supply of compressed air to the turbine blades. This reduces the flow of compressed air directed to the turbine, which is already rotating at a certain frequency. The released stream of compressed air is directed to the nozzles 16 and acts on the blades 8, untwisting the flywheel 7, while this accumulates energy. Each module 1 can have from one to three flywheels. The number of flywheels 7 in one module 1 can be much larger, it depends on the power of the power plant. After untwisting the first flywheel to the rated frequency, a signal is received from the speed sensor and the supply of compressed air to the blades 8 is stopped. Compressed air enters the blades of the second, then the third flywheel and so on.

 Module 1 is fully loaded when turbine 5 is running with generator 6 and all flywheels 7 rotate. This is possible with strong winds. The free stream of compressed air through the piping system from the compressor 14 goes to other modules where there is no wind or the wind is small. There is a redistribution of wind energy and its transfer to other modules through the energy of compressed air.

 If a gusty wind blows in the area of module 1, then at the moment of lack of wind an additional compressor 18 comes into operation. The corresponding additional compressor 18 is switched on with the help of clutch 17. When the speed of the turbine 5 is reduced from the flywheel 7, the rotation is transmitted to the additional compressor 18, which compresses air and through a pipe 19 feeds it through the nozzle to the turbine blades. The kinematic energy of the flywheel 7 is converted into the energy of compressed air to maintain the normal operation of the generator 6. If necessary, the second, third flywheel, etc., comes into operation. This allows the production of electrical energy not to stop after air pressure in the main pipeline decreases.

 With a very strong wind, module 1 can work in the mode of generating electric energy (the turbine and generator are working) and compressed air (the flywheels 7 rotate and the additional compressor 18 works). This causes the injection of compressed air into the entire piping system and the transfer of wind energy to modules where there is no wind.

The combination of all modules on a vast territory, the creation of a block-modular scheme, the ability to accumulate wind energy increases the power of the power plant and makes its operation independent of the absence of wind. The wind storage power plant can operate in the following modes:
production of electric energy without the accumulation of wind energy;
production of electrical energy with the simultaneous accumulation of wind energy;
accumulation of wind energy without generating electric energy;
production of electrical energy and compressed air.

 The choice of operating mode depends on the strength of the wind, meteorological forecast, demand for electric energy and other factors. It is advisable to manage the operation of the entire power plant using a computer.

 The proposed wind storage power plant has a simple design, reliable in operation, has high efficiency and can operate in various modes and in the absence of wind.

Claims (1)

 A wind storage power plant containing several wind power plants, each of which includes a wind turbine and a compressor kinematically connected to it, as well as a piping system for supplying compressed air from wind power plants to turbines kinematically connected to electric generators, characterized in that it is equipped with flywheels with vanes and additional compressors kinematically connected to the flywheels using the included clutch, while the piping system sn Abzhena nozzles for supplying compressed air to the blades of the flywheels and turbines, as well as valves and sensors for pressure and speed to control the supply of compressed air to the blades of the turbines and flywheels.

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