RU2529615C1 - Method of energy accumulation - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: in this method of energy accumulation, in which compressed air and gaseous fuel are supplied into a power plant from a gas storage, and products of gaseous fuel combustion are used in periods of increased load of a power grid for a gas turbine drive of a motor-generator, which in the periods of power grid off-peak load is used for compression of air and its injection into the gas storage, at least some air bled from the gas storage is used for steam and air conversion of natural gas in an adiabatic reactor of conversion, products of which are supplied in the periods of higher load of the power grid for combustion in the flow of compressed air with production of combustion products supplied for expansion into the gas turbine drive of the motor-generator, and then for cooling in the water steam generator, from which the generated water steam is sent for mixing with compressed air before steam and air conversion of natural gas. In the periods of power grid off-peak load prior to supply of compressed air into the gas storage it is cooled by heating of heating water.

EFFECT: invention makes it possible to increased reliability of energy accumulation.

8 cl, 1 dwg

Description

The invention relates mainly to autonomous systems and energy supply systems using both different types of fuel and renewable energy sources, such as wind or solar energy, and is intended to provide heating heat, hot water, cold and electricity to various objects having an uneven energy load.

Power plants, wind turbines with electric generators or tidal power plants are known that convert primary energy into electrical energy, which is stored in electric accumulators and then, if necessary, is supplied to various consumers of electricity. Various power plants are also used that convert thermal (solar or geothermal) energy into electrical energy. Nuclear power sources have significant potential, which are advantageous to use under constant load, while in the power system there are day peaks and night power dips. As can be seen from the above enumeration of the operating characteristics of various energy generating systems, there is a significant difference in the time schedules of energy production and consumption. Thus, the problem arises of creating energy-saving installations and systems that can provide consumers with various types of energy, secondary energy carriers and desalinated water in the uneven mode required by the consumption conditions, regardless of the schedule of primary energy consumption.

The energy potential of nuclear and renewable energy sources exceeds the energy demand by more than two orders of magnitude. Using this potential will solve the geopolitical problems associated with the uneven distribution of natural deposits of fossil fuels, as well as lead to a noticeable restoration of the natural ecological potential and improve the environment.

Alignment of the load schedule of energy sources through the use of traditional energy storage devices or heat accumulators increases the cost of energy production and complicates the work schedule.

A cycle of air-accumulating gas turbine units (VAGTU) is proposed [see in the book: Air-accumulating gas turbine power plants (VAGTE). G.G. Olkhovsky, V.A. Ghazaryan, A.Ya. Stolyarevsky. Because: Institute for Computer Research, 2011, p.113], which is a variation of the standard cycle of energy production by a gas turbine. In a standard power generation cycle of a gas turbine power plant, a gas turbine is physically connected to an air compressor. Thus, during the operation of a gas turbine, approximately two-thirds of the energy of the turbine is used to compress air. When using the VAGTU installation, the compression cycle proceeds separately from the combustion and production cycles. Energy generated during off-peak periods or excess electricity is used to pre-compress the air that is stored in the underground cavity, usually in the salt cavity. When the VAGTU installation converts energy, compressed air from the underground cavity is taken out and heated by the regenerator, then mixed with fuel (natural gas) and expanded in the turbine to generate energy. Since the turbine’s power is no longer required to drive an air compressor, a turbine of the same size can generate three times more energy using less fuel for each generated MW. The accumulated compressed air takes the place of gas, which would otherwise have to be burned in the process of energy production and used to compress the air with a gas turbine compressor.

The concept of VAGTU has established itself in existing installations for the storage of energy of compressed air. The plants have a compression unit connected to the generation unit by a common motor generator and a number of clutches. VAGTU often has a regenerator (air-to-air heat exchanger) for utilizing the exhaust heat of a gas turbine to preheat the air coming from the underground storage. Such design changes increase heat output.

When the cost of peak electricity in the wholesale market is 7-10 times higher than nightly, the total revenue from the operation of drives, taking into account payment for system services, ensures the investment attractiveness of long-term financial investments in their construction.

In particular, a method of operating a wind farm with hydrogen energy storage is proposed, which consists in decomposing water into oxygen and hydrogen, characterized in that in order to increase efficiency they create a closed cycle where water is pumped into a desuperheater and an electrolyzer from which hydrogen and oxygen how the components of the decomposition of water are collected in separate storage tanks, burned in the combustion chamber, and the combustion products in the form of superheated water vapor are sent to a desuperheater, where water is injected and oh they add superheated water vapor, the energy of which is converted into electric and thermal energy by means of a steam turbine, generator, condenser and electric boiler, and the condensate is drained into a condensate tank (RF application for invention No. 99102865, publication date 2000.12.20). The disadvantage of this solution is the high cost and low efficiency of energy storage, which is associated with high costs for the creation and operation of electrolyzers (up to 3000 US dollars / kW) and hydrogen and oxygen storage systems, as well as the relatively low efficiency of the steam turbine cycle.

A more economical solution is proposed in the EU patent for invention No. 2378100 (publication date 10/19/2011), in which the VAGTU-based power generation system includes a first compressor, a second compressor, a combustion chamber configured to receive compressed air from a second compressor to produce a stream exhaust gas, first turbine and power turbine. The first turbine, configured to receive an exhaust gas stream, generates energy by expanding the exhaust gas stream and also serves as a drive for a second compressor that compresses the gas stream from the underground compressed air storage. The system includes a connecting device configured to connect and separate the first compressor from the second turbine connected by a gas exhaust to a power turbine supplying an electric generator configured to output electrical power, an analogue. The disadvantages of this solution are the relatively low efficiency of electricity production and the need for a large volume of gas storage.

The technical solution to eliminate this drawback was the proposal of VAGTU according to the RF patent for invention No. 2273742 - a prototype in which the energy storage unit containing an electric current generator, compressor, gas turbine and a compressed air reservoir connected to the latter, is made in the form of an elastic hermetic shell and installed in the hydraulic medium at a depth determined by the ratio of a number of parameters, including: the total cross-sectional area of the turbine inlet and the total cross-sectional area section of the outlet openings of the tank. During hours of reduced load on the power system, air from the atmosphere is pumped by the compressor through the air ducts into the tank. From the beginning of the air supply, the pressure inside the tank is set equal to hydrostatic in accordance with its immersion depth. In this case, the air is compressed and its volume decreases as many times as the hydrostatic pressure of water at a given depth exceeds atmospheric air pressure. When the load peaks in the power system, compressed air from the tanks enters through the air ducts into a gas turbine with an electric generator to generate electricity. In this proposal, the disadvantage is the low efficiency and the need to create air batteries of high cost due to high pressure, elastic shell and large volume.

The objective of the invention is the creation of a method of energy storage, in which due to the utilization of thermal energy of the combustion products in the steam generator and the use of compressed air stored in the gas storage due to the failed electricity, a hydrogen-containing gas mixture with a high hydrogen content is obtained, the combustion of which increases the power of the gas turbine in peak mode and reduces emissions of harmful substances, creates conditions for reducing energy costs and harmful emissions into the atmosphere, increase the reliability of energy storage plant, simplify its design, increase reliability and improve operating conditions.

The problem is solved in that in the method of energy storage, in which compressed air is supplied to the power plant from the gas storage, as well as gaseous fuel, the combustion products of which are used during periods of increasing power supply load for a gas turbine drive of the motor generator, which is used for periods of failure of the power supply to compressing the air and forcing it into the compressed air storage, at least a portion of the compressed air taken from the compressed air storage is used to conduct steam air-gas conversion of natural gas in an adiabatic conversion reactor, the products of which are supplied during periods of increased load of the electric grid for burning in a stream of compressed air to produce combustion products supplied for expansion into the gas turbine drive of the motor generator, and then for cooling in a water steam generator, from which the produced water steam is mixed with compressed air before the steam-air conversion of natural gas.

Besides:

- during periods of failure of the power supply network before supplying compressed gas to the gas storage, it is cooled by heating the heating water;

- steam-air conversion of natural gas is carried out using a catalyst;

- gaseous fuel is selected from the range containing natural gas, hydrocarbons, dimethyl ether, methanol, ethyl alcohol or mixtures thereof;

- feed water to the steam generator is supplied from a reservoir replenished with condensate released from the combustion products;

- before being fed into the combustion chamber, the conversion products are cooled by heating the inlet vapor-air stream entering the conversion reaction and stored in storage tanks;

- the temperature regime of conversion is supported by changing the flow rate and composition of the inlet vapor-air stream;

- the supply of compressed air taken from the gas storage is distributed between the combustion chamber and the conversion reactor by using a locking and / or control element.

The essence of the present invention is as follows.

The highest thermodynamic efficiency of utilization of waste heat of a gas turbine can be achieved by using this heat to produce chemical products, during the combustion of which a high-temperature working fluid is generated, which is triggered in a gas-turbine cycle. Among these products is hydrogen, which not only does not form harmful products during combustion, but also provides an increase in turbine efficiency and allows working on an extremely poor mixture with a very large coefficient of excess air (up to λ = 9.8 in the case of a hydrogen-air mixture). Due to the presence of a large amount of air in the combustion chamber that is not involved in the combustion of the fuel, a significant reduction in the temperature of the exhaust gases and an incredibly low level of NO _x emissions of less than 5 mg / nm ³ or 2 ppm are achieved, which is practically approaching the detection limit. Moreover, an increase in the mass flow rate of the working fluid leads to an increase in the turbine power. The use of conversion products, which are hydrogen-containing mixtures with a high hydrogen content (up to 30-40%), as fuel gas in gas turbine plants, including VAGTU type, will not only significantly improve operational characteristics and reduce fuel gas consumption, but and significantly reduce emissions. The production of hydrogen-containing gas conversion products according to the invention is carried out by a catalytic process of steam-air conversion of natural gas (methane), which uses compressed air stored in a compressed air storage tank during periods of power failure, and water vapor obtained in a steam generator in which waste heat of products is utilized combustion of hydrogen-containing gas. Heat is removed from the combustion products discharged from the gas turbine to produce water vapor, some of which is used in the methane conversion reaction, and the remaining stream can be directed along with the stream of conversion products to the combustion chamber, or to a power turbine. Thus, it is possible to use the energy of the combustion products discharged from the gas turbine with the highest possible efficiency.

An example implementation of the invention is the method of energy storage, described below.

The figure shows a diagram of the implementation of the method, where 1 is natural gas, 2 is a mixing chamber, 3 is a steam-air stream, 4 is a partial oxidation reactor, 5 is a conversion product, 6 is a combustion chamber, 7 is a compressed air oxidizer, 8 is a combustion product , 9 - gas turbine, 10 - motor generator, 11 - electricity, 12 - flue gases, 13 - steam generator, 14 - feed water, 15 - reservoir of feed water, 16 - steam, 17 - receiver, 18 - compressed air - reagent, 19 - distribution unit, 20 - compressed air, 21 - compressed air storage, 22 - air supply pipes, 23 - compressor air Sora, 24 - cogeneration heat exchanger, 25 - compressor, 26 - air from the atmosphere.

The method is as follows.

During periods of increasing load on the mains, natural gas 1 is fed into the mixing chamber 2, into which high-pressure steam-air stream 3 is also sent. Due to the oxidation of natural gas, the temperature of the mixture rises to 1100-1200 ° С at a pressure above 2.0 MPa and a heated reaction mixture is formed, which enters the partial oxidation catalytic reactor 4, in which the mixture is converted into conversion products 5 sent at a temperature of about 700 ° the combustion chamber 6, which also directs compressed air 7. To correct the composition of the gases, an additional flow of natural gas 1 can be supplied to the combustion chamber 6. The combustion products 8 formed in the combustion chamber 6 with a temperature of 1100-1400 ° C the input of the gas turbine 9, wherein the combustion products are expanded and 8 are converted into low-pressure flue gases with a temperature of 450 ° C, which is sent to the steam generator 13 and then to the atmosphere. In front of the combustion chamber 6, conversion products 5 can accumulate in storage tanks (not shown in the figure). In the steam generator 13 from the feed water 14 taken from the reservoir 15, high-pressure water vapor 16 is produced, which is mixed with compressed air 18 in the receiver 17. It is advisable from the flue gases 12 cooled in the steam generator 13 to be sent to the atmosphere in a contact condenser (on the drawing is not shown) to withdraw water by condensing low-pressure water vapor contained in the products of combustion 12, then discharged into the atmosphere 11. Condensation is carried out with chilled water. Part of the condensate after the pump (not shown) is sent to the feed water tank 15.

During periods of load failure, the compressor 25 compresses the air 26 taken from the environment, feeds it into the gas storage of compressed air 21, pre-cooling it in a heating heat exchanger 24, in which the heat carrier - heating water supplied to the heating and hot water supply network is heated.

In addition to the motor generator 10 (during periods of increasing load of the power supply network), the air compressor 25 can act as a mechanical load of the turbine 9 (during periods of failure of the load of the power supply network).

The reaction in the catalytic reactor 4 is carried out without supplying thermal energy to a catalyst containing metals of the series nickel, iron, platinum, palladium, iridium or their compounds, to increase the efficiency of which, before mixing natural gas 1 with steam-air stream 3, natural gas is purified from sulfur compounds .

The pressure of high pressure water vapor 16 is selected in the range of approximately from 2.0 to 9.0 MPa, bringing it as close as possible to the pressure at the inlet of the gas turbine 9. The proposed method of energy storage in comparison with the prototype has the following advantages:

- increases the power of the gas turbine 9 and the total generated peak energy, since the required energy consumption, supplied in peak mode from an external energy source, is only 20-30% of the energy supplied to the working fluid from an external source in the prototype technical solution;

- increases the reliability of the installation and reduces the cost of energy production due to a sharp (40-50%) reduction in the supply of natural gas to the installation supplied from the outside, which also eliminates the dependence on the transportation of the working fluid to the installation site;

- provides full environmental safety of the proposed method of energy storage, since the emission of harmful compounds into the environment is sharply reduced;

- using heating batteries in the proposed method of energy storage, any required amount of energy is stored enough to provide heating loads and hot water supply even during periods of interruption in the supply of thermal energy from an external source;

- it is possible to use this installation to generate peak electricity and supply various objects with thermal energy and cold in the mode of a decompressed schedule of their consumption;

- technically simple and reliable, it is possible to accumulate failed night energy supplied at a reduced rate;

- the possibility of efficient utilization of waste heat of various heat engines is provided, and the possibility of using renewable natural energy sources with significant resource potential and at the same time high unevenness of their energy supply, as well as an additional increase in installation efficiency in cold climates, is expanding;

- increases the reliability and reduces the cost of the proposed method of energy storage due to moderate in temperature and pressure parameters of the working fluid.

So, for example, at a flow rate of 100 thousand m ^{3 of} air / h and a supply of natural gas 1 with a flow rate of 20 t / h (about 35 thousand m ³ / h) to reactor 4 with a feed of 5 a combustion chamber 6 in a gas turbine 9, when the working fluid expands to a pressure of 0.1 MPa, 200 MW of electric energy is generated. The high back pressure in the gas turbine 9 dramatically reduces the size and cost of the turbine. To deliver peak power within 8 hours / day, the capacity of the underground cavity of the compressed air gas storage 21 will be about 0.4 million m ³ , which has been mastered in domestic practice with experience in creating underground gas storage with a pressure of 10-12 MPa and a capacity of about 1 billion cubic meters. m of active gas.

An additional positive feature of this energy storage unit is the ability to use existing materials, technical solutions and equipment necessary for its creation.

Thus, this method will allow, by utilizing the thermal energy of the combustion products in the steam generator and using compressed air stored in the gas storage due to the failed electricity, to obtain a hydrogen-containing vapor-gas mixture with a high hydrogen content, the combustion of which increases the power of the gas turbine in peak mode and reduces harmful emissions substances, create conditions to reduce energy costs and harmful emissions into the atmosphere, increase the reliability of the energy storage unit, simplify its design functions, improving reliability and improving operating conditions.

Claims (8)

1. A method of energy storage, in which compressed air is supplied to a power plant, as well as gaseous fuel, the products of combustion of which are used during periods of increased load on the power grid for a gas turbine drive of the motor generator, which during periods of failure of the load on the power grid is used to compress air and pump it in a gas storage of compressed air, characterized in that at least a portion of the compressed air taken from the compressed air storage is used for carrying out in a catalytic reaction partial oxidation of steam-air conversion of natural gas, the products of which are supplied during periods of increased load of the electric network for burning in a stream of compressed air to produce combustion products supplied for expansion into a gas turbine, and then for cooling in a water steam generator, from which the generated steam is mixed with compressed air before the steam-air conversion of natural gas. 2. The method according to claim 1, characterized in that during periods of failure of the power supply network before it is supplied with compressed air to the gas storage, it is cooled by heating the heating water. 3. The method according to claim 1 or 2, characterized in that the steam-air conversion of natural gas is carried out using a catalyst. 4. The method according to claim 1 or 2, characterized in that the gaseous fuel is selected from the range containing natural gas, hydrocarbons, dimethyl ether, methanol, ethyl alcohol or mixtures thereof. 5. The method according to claim 1 or 2, characterized in that the feed water to the steam generator is supplied from the feed water tank, replenished with condensate released from the combustion products. 6. The method according to claim 1 or 2, characterized in that before being fed into the combustion chamber, the conversion products are cooled by heating the inlet steam stream entering the conversion reaction and stored in storage tanks. 7. The method according to claim 1 or 2, characterized in that the temperature regime of conversion is supported by changing the flow rate and composition of the input steam-air stream. 8. The method according to claim 1 or 2, characterized in that the supply of compressed air taken from the compressed air storage is distributed between the combustion chamber and the conversion reactor by using a locking and / or control element.

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