RU2650238C1 - Gas distribution station power plant or the gas control unit operation method - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: invention is intended for power generation at power plants of gas distribution stations and at gas-control units. High-pressure natural gas is expanded in a turboexpander and reduces its pressure to the level required by a particular consumer, maintaining its temperature at least 278 K. Heat of combustion products expanded in a gas turbine is used to generate superheated high-pressure steam. In the gas turbine, the resulting gas-vapor mixture is expanded, its heat is used to generate superheated high-pressure steam and for heating the high-pressure natural gas in front of the turboexpander. Useful work of the turboexpander is used to compress air in the compressor, the useful work of the gas turbine is used to generate electricity in an electric generator. Cooling water is injected into the gas-vapor mixture partially cooled during the production of high-pressure superheated steam and by heating the high-pressure natural gas. Reduce the temperature of the gas-vapor mixture to 65–70 °C. Condensation of the steam contained in the gas-vapor mixture separates the condensate and cooling water from the combustion products; a smaller part of the mixture of condensate and cooling water is softened and used as feed water to produce superheated steam. Most of this mixture is divided into two streams. First stream of the mixture is cooled by atmospheric air in a cooling tower to 25–30 °C, and the second mixture stream is cooled to 15–20 °C with natural gas, expanded in a turboexpander, then the first and second cooled streams of the mixture are injected into the cooled gas-vapor mixture.

EFFECT: invention is aimed at increasing the power and thermal efficiency of the power plant of a gas distribution station or gas control unit.

1 cl, 1 dwg

Description

The invention relates to the field of gas transport through gas pipelines and can be used to generate electricity at gas distribution stations (gas distribution stations) and gas control points (hydraulic fracturing).

A regenerative gas turbine expander unit for the auxiliary needs of main gas pipelines is known, comprising a turboexpander with an adjustable nozzle apparatus and a gas turbine unit. High pressure natural gas expanded in a turboexpander provides fuel gas supply to the combustion chambers of the gas turbine expander and to the combustion chambers of the gas pumping units of the compressor station (RF Patent No. 2570296). But this installation cannot be used to generate electricity at gas distribution stations and hydraulic fracturing.

The closest in technical essence to the present invention is a method of operating a power plant with a turboexpander, which consists in directing high-pressure natural gas to the consumer through a turboexpander with an adjustable nozzle apparatus, in which the pressure of natural gas is reduced to the level required by a particular consumer, and this pressure is kept constant gas and its temperature at a level of not less than 278 K, while the exhaust gases of a gas turbine engine produce preliminary heating at a high pressure gas directed into the turbo expander (Patent RU №2096640). This method is adopted as a prototype of the invention.

The disadvantage of the prototype method is the lack of thermal efficiency and electrical power of a power plant installed on hydraulic fracturing or gas distribution system.

An object of the invention is to increase the power and thermal efficiency of the power plant gas distribution station or gas control point.

The problem is solved due to the fact that in the proposed method of operation of a power plant of a gas distribution station or gas control station containing a turboexpander, a gas turbine plant with a compressor, a combustion chamber and a gas turbine, an electric generator, high-pressure natural gas are expanded and reduced in a turboexpander pressure to the level required by a specific consumer, maintaining a constant pressure of this gas using an adjustable nozzle device an expander and a gas temperature of at least 278 K, while the high-pressure gas is heated with heat from the combustion products expanded in the gas turbine before being fed to the turboexpander, the heat of the combustion products expanded in the gas turbine is also used to generate superheated steam in the recovery boiler high pressure, 5-7% of which (relative to the air flow in the compressor) is supplied to the compressed air in the compressor, and 9-12% is mixed with the combustion products in the output part of the combustion chamber, then the resulting gas-vapor mixture expand in a gas turbine and sent to a waste heat boiler, where cooling water is injected into a gas-steam mixture partially cooled during generation of superheated high-pressure steam and when heating high-pressure natural gas, lowering the temperature of the gas-steam mixture to 65-70 ° C, and then condense the steam contained in the gas-vapor mixture, and the condensate and cooling water are separated (separated) from the combustion products, while a smaller part of the mixture of condensate and cooling water is softened and used as feed water for webs of superheated steam, and most of this mixture is divided into two streams, the first of which is cooled by atmospheric air, in a cooling tower, to 25-30 ° С, and the second is cooled to 15-20 ° С by natural gas expanded in a turboexpander, then combined the first and second flows of the mixture are used as cooling water in the recovery boiler, while the useful work of the turboexpander is used to compress the air in the compressor, the useful work of the gas turbine is used to generate electricity in the generator.

Comparison of the proposed method of operation of the power plant gas distribution station or gas control point with the prototype and other technical solutions allowed to conclude that the proposed method meets the criterion of "novelty." Given the signs that distinguish the claimed method from the prototype, we can conclude that the proposed method of operation of the power plant gas distribution station or gas control points meets the criterion of "significant differences".

In FIG. 1 shows the thermal diagram of a power plant GRS or hydraulic fracturing. It contains: a gas main 1, a turboexpander 2 with an adjustable nozzle apparatus, a compressor 3, a combustion chamber 4, a gas turbine 5, an electric generator 6, an injection pipeline for superheated steam 7, an injection pipeline for superheated steam in the fuel combustion products 8, a steam pipeline for superheated high pressure steam 9 , recovery boiler 10, superheater 11, evaporator 12, economizer 13, high-pressure gas heater 14, feed pump 15, cooler 16, injection device 17, softener 18, separation device 19, failure tank 20, pipe 21, cooling tower 22, pipe 23, condensate-cooling water mixture pipe 24, high pressure gas pipe 25, reduced pressure gas pipe 26, reduction unit 27.

The operation of a power plant GRS or hydraulic fracturing, the thermal diagram of which is presented in FIG. 1 is carried out as follows.

In the normal mode of operation of the gas distribution system or hydraulic fracturing, high-pressure natural gas from the main gas pipeline 1 is supplied through the high-pressure gas pipeline 25 to the high-pressure gas heater 14, where the gas is heated and then sent to the inlet of the turboexpander 2 equipped with an adjustable nozzle apparatus. In a turboexpander 2, high-pressure natural gas is expanded to lower its pressure and temperature. When changing the pressure of natural gas in the main gas pipeline 1 using an adjustable nozzle apparatus of a turboexpander 2 in the low pressure gas pipeline 26, a constant pressure of the gas supplied to the consumer is maintained. The superheated steam generated in the recovery boiler 10 is supplied via the superheated steam pipe 9 and the superheated steam injection pipe 7 into the air compressed by the compressor 3. Steam is supplied to the outlet of the combustion chamber 4 of the gas turbine unit through the superheated steam injection pipe 8 into the fuel combustion products . In the combustion chamber 4, fuel is burned. The resulting gas-vapor mixture is expanded in the gas turbine 5, using the useful work of the gas turbine to generate electricity in the electric generator 6. The heat of the expanded gas-vapor mixture is used in the superheater 11, the evaporator 12 and the economizer 13 to generate superheated high pressure steam, as well as for heating natural gas in the heater high-pressure gas 14. In the gas-vapor mixture exiting the heater 14, cooling water is injected through the injection device 17, reducing the temperature of the mixture to 65-70 ° C, after which condensate the steam contained in it. In the separation device 19, the mixture of steam condensate and cooling water is separated from the combustion products, which are then discharged into the atmosphere, and the separated mixture of condensate and cooling water is fed into the collection tank 20, after which it is divided into two streams: a smaller part of the mixture is softened in the softener 18 and used as feed water to generate superheated steam in the recovery boiler 10, and most of it is fed into the pipeline of a mixture of condensate and cooling water 24 and divided into two streams. The first mixture stream is cooled by atmospheric air, in cooling tower 22, to a temperature of 25-30 ° C, and the second mixture stream is sent through line 23 to cooler 16, where it is cooled to 15-20 ° C with natural gas expanded in turbine expander 2. Then the first mixture stream cooled in the cooling tower 22 is directed into the pipe 21 and mixed with the second mixture stream cooled in the cooler 16. The combined first and second mixture flows are supplied as cooling water to the injection device 17.

The useful work of the turboexpander 2 is used to drive the compressor 3 of the gas turbine installation. The useful work of a gas turbine 5 is used to generate electricity in an electric generator 6.

In the event of an accident or repair of a power plant of a gas distribution system or hydraulic fracturing, high-pressure natural gas from main gas pipeline 1 is reduced in a reduction unit 27 and then it is supplied to consumers.

Using the useful work of a turboexpander to drive a compressor and compressing atmospheric air in it, and the useful work of a gas turbine to generate electricity allows you to increase the efficiency of a gas turbine expander power plant to 65-75% and its electric power.

Injection into compressed air of 5-7% of superheated high-pressure steam (relative to the air flow in the compressor), as well as injection of 9-12% of superheated high-pressure steam into the outlet of the combustion chamber allows reducing the concentration of toxic gases in the combustion products by 40-60% and 1.5-1.6 times increase the electric power of a gas turbine.

The connection of a high-speed turboexpander to a compressor by a common shaft allows reducing the number of stages in the compressor, increasing the efficiency and reducing its cost.

The electric generator drive from the gas turbine shaft at 3000 rpm allows you to refuse to use a reduction gear and increase the reliability of the power plant.

Claims (1)

The method of operation of a power plant in a gas distribution station or gas control station containing a turboexpander, a gas turbine plant with a compressor, a combustion chamber and a gas turbine, and an electric generator, according to which high-pressure natural gas is expanded in a turboexpander with an adjustable nozzle apparatus and its pressure is reduced to the level required by a particular consumer while maintaining a constant pressure of this gas using an adjustable nozzle apparatus of a turboexpander and a gas temperature at less than 278 K, while the high-pressure gas is heated with heat of the combustion products expanded in the gas turbine before being fed to the turboexpander, characterized in that the heat of the combustion products expanded in the gas turbine is also used to generate superheated high pressure steam in the recovery boiler, 5-7% of which (relative to the air flow in the compressor) is supplied to the compressed air in the compressor, and 9-12% is mixed with the combustion products in the outlet part of the combustion chamber, then the resulting gas-vapor mixture is expanded in a gas turbine and sent to a waste heat boiler, where cooling water is injected into a gas-steam mixture partially cooled during generation of superheated high-pressure steam and heating of high-pressure natural gas, lowering the temperature of the gas-steam mixture to 65-70 ° C, after which the steam contained in gas-vapor mixture, and the condensate and cooling water are separated (separated) from the combustion products, while a smaller part of the mixture of condensate and cooling water is softened and used as feed water to produce superheated steam, and the pain The majority of this mixture is divided into two streams, the first of which is cooled by atmospheric air, in a cooling tower, to 25-30 ° С, and the second is cooled to 15-20 ° С by natural gas expanded in a turboexpander, after which the first and second flows are combined the mixtures are used as cooling water in a recovery boiler, while the useful work of a turboexpander is used to compress air in a compressor, the useful work of a gas turbine is used to generate electricity in an electric generator.

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