RU133252U1 - GAS DISTRIBUTION STATION - Google Patents

Abstract

1. A gas distribution station containing high and low pressure highways of natural gas interconnected by means of a reducing device and through a bypass gas pipeline in which a gas turbine installation and a heat recovery turbine expander are installed, each of which has an electric generator connected to an electricity consumer, characterized in that it is equipped with an energy recovery turbine expander with an electric generator connected to an electric power consumer and which is capable of generating low-temperature natural gas and condensate in the form of a liquefied fraction of heavy hydrocarbons, the gas turbine unit is made in the form of a gas turbine unit with a reverse gas generator with the possibility of cooling it with low-temperature natural gas, and the heat-utilizing turbine expander unit is configured to utilize the low-potential heat of natural gas, heated exhaust gas reversed gas generator, while energy recovery turbo-child The nuclear installation contains a high-pressure natural gas heat exchanger-cooler, the first inlet of which is connected to the high-pressure line of natural gas, and the first outlet is to the inlet of the expander, the outlet of which is connected to the separator-separator of the liquid phase of the low-temperature natural gas, the first outlet of which is connected to the gas turbine installation and the second exit with a separator-separator of the liquid phase of the heavy hydrocarbon fractions connected to the second inlet of the high pressure natural gas heat exchanger-cooler

Description

The utility model relates to the gas industry, namely, to gas distribution stations using the turbo-expander technology to lower the pressure of natural gas, and can be used for the combined generation of electricity, industrial refrigeration and condensate in the form of a liquefied fraction of heavy hydrocarbons by using the energy of the differential pressure of natural gas to the inlet and outlet of the gas distribution station.

The closest technical solution to this utility model is a gas distribution station containing high and low pressure highways of natural gas interconnected by a reducing device and through a bypass gas pipeline, in which a gas turbine installation and a heat recovery turbine expander are installed, which has an electric generator connected to electricity consumer (Patent RU No. 2009389, IPC F17D 1/04, 03/15/1994).

The main disadvantage of the known gas distribution station is the low efficiency (up to 45%) associated with the peculiarities of the thermodynamic cycle of a gas turbine installation with heat recovery.

Natural gas in a heat exchanger-heat exchanger is washed by a high-temperature flow of combustion products (350 ... 500 ° C) of a gas turbine engine, which leads to the pyrolysis of natural gas and impairs its physical and thermodynamic properties.

The throttling of a gas turbine engine by controlling the temperature in the combustion chamber (at low power modes) leads to an increase in specific fuel consumption and an increase in emissions of pollutants from combustion products.

In addition, the disadvantage of the known gas distribution station is limited functionality, since it does not allow the generation of condensate in the form of a liquefied fraction of heavy hydrocarbons.

The objective of the utility model is to increase the coefficient of performance (COP) due to the use of low-temperature natural gas for cooling the exhaust gas of a gas turbine installation, eliminating the pyrolysis of natural gas, reducing harmful emissions into the environment by reducing the specific fuel consumption in a gas turbine installation, as well as expanding the functionality due to the production of condensate in the form of a liquefied fraction of heavy hydrocarbons.

The technical result is achieved by the fact that a gas distribution station containing high and low pressure highways of natural gas interconnected by a reducing device and through a bypass gas pipeline in which a gas turbine installation and a heat recovery turbine expander are installed, each of which has an electric generator connected to a consumer electricity, according to a utility model, is equipped with an energy recovery turbine expander with an electric generator connected to a consumer of electricity that is capable of generating low-temperature natural gas and condensate in the form of a liquefied fraction of heavy hydrocarbons, the gas turbine unit is made in the form of a gas turbine unit with an inverted gas generator with the possibility of cooling it with low-temperature natural gas, and the heat recovery turbine expander is configured to utilize a low-potential heat of natural gas heated by exhaust gas of a reverse gas generator and, at the same time, the energy recovery turbo-expander installation contains a high-pressure natural gas heat exchanger-cooler, the first inlet of which is connected to the high-pressure line of natural gas, and the first outlet - to the inlet of the turbine-expander, the outlet of which is connected to the separator-separator of the liquid phase of low-temperature natural gas, the first outlet which is connected to a gas turbine installation, and the second output to a separator-separator of the liquid phase of heavy hydrocarbon fractions connected to the second input of the heat exchanger cooler high pressure natural gas, a second output connected to the receiver liquefied fraction of heavy hydrocarbons.

In this case, the bypass gas pipeline has a first bypass pipeline connecting the first input and the first output of the high pressure natural gas heat exchanger-cooler, the separator-separator of the liquid phase of the heavy hydrocarbon fractions is connected to the receiver of the liquefied fraction of heavy hydrocarbons using the second bypass pipeline and is configured to discharge solid impurities .

Thus, the main technical result is an increase in the efficiency due to the presence of an energy recovery turbine expander unit producing low-temperature natural gas, the implementation of a gas turbine unit in the form of a gas turbine unit with a reversed gas generator, cooled by a low-temperature natural gas, and the implementation of a heat-utilizing turbine expander unit with the possibility of utilizing low heat heated exhaust gas gas generator.

In addition, the technical result is the exclusion of pyrolysis of natural gas, as well as the reduction of harmful emissions into the environment through the use of a reversed gas generator, the expansion of functionality due to the presence of an energy recovery turbine expander, configured to produce condensate in the form of a liquefied fraction of heavy hydrocarbons.

The essence of the utility model is illustrated by drawings, in which Fig. 1 shows an enlarged block diagram of the proposed gas distribution station, and Fig. 2 shows the proposed gas distribution station with a schematic diagram of an energy recovery turbine expander.

In the drawing, the numbers indicate:

1 - high-pressure highway of natural gas,

2 - highway low pressure natural gas,

3 - reducing device

4 - bypass gas pipeline,

5 - gas turbine unit with a reversed gas generator,

6 - electric generator of a gas turbine installation,

7 - heat recovery turbine expander,

8 - electric generator heat recovery installation,

9 - energy recovery turbine expander,

10 - electric generator energy recovery installation,

11 - heat exchanger-cooler natural gas high pressure,

12 - turboexpander energy recovery installation,

13 - separator-separator of the liquid phase of the low-temperature natural gas,

14 - separator-separator of the liquid phase of the heavy hydrocarbon fractions,

15 - receiver liquefied fractions of heavy hydrocarbons,

16 - the first bypass pipe

17 - the second bypass pipe.

The gas distribution station (Fig. 1) contains high-pressure and high-pressure lines of natural gas 2 connected to each other by means of a reducing device 3 and through a bypass gas pipeline 4.

In the bypass gas line 4, a gas turbine unit 5 having an electric generator 6 and a heat recovery turbine expander 7 having an electric generator 8 are sequentially installed. The electric generators 6 and 8 are connected to a power consumer, for example, to a compressor station.

The difference of the proposed gas distribution station is that it is equipped with an energy recovery turbine expander 9 with an electric generator 10 connected to a consumer of electricity (figure 2).

The energy recovery turbine expander 9 is configured to produce low-temperature natural gas and condensate in the form of a liquefied fraction of heavy hydrocarbons.

Gas turbine unit 5 is made in the form of a gas turbine unit with a reversed gas generator, which is cooled by low-temperature natural gas.

The heat recovery turbine expander 7 is configured to utilize the low potential heat of natural gas heated by the exhaust gases of the reverse gas generator of the gas turbine 5.

The energy recovery turbine expander unit (Fig. 2) comprises a high pressure natural gas heat exchanger-cooler 11, a turboexpander 12 with an electric generator 10, a low-temperature natural gas liquid phase separator-separator 13, a heavy hydrocarbon fraction liquid phase separator-separator 14 and a heavy hydrocarbon liquid fraction receiver 15 .

The first input of the heat exchanger-cooler 11 of the high pressure natural gas is connected to the high-pressure line 1 of the natural gas, and the first output of the heat exchanger-cooler 11 is connected to the inlet of the turbine expander 12.

The output of the turboexpander 12 is connected to a separator-separator 13 of the liquid phase of the low-temperature natural gas.

The first output of the separator-separator 13 of the liquid phase of the low-temperature natural gas is connected to a gas turbine unit 5 with a reversed gas generator.

The second output of the separator-separator 13 is connected to the separator-separator 14 of the liquid phase of the heavy hydrocarbon fractions.

The separator-separator 14 of the liquid phase of the heavy hydrocarbon fractions is connected to the second inlet of the heat exchanger-cooler 11 of high-pressure natural gas.

The second output of the heat exchanger-cooler 11 is connected to the receiver 15 of the liquefied fraction of heavy hydrocarbons.

The bypass gas line 4 has a first bypass line 16 connecting the first inlet and the first outlet of the high pressure natural gas heat exchanger-cooler 11.

The separator-separator 14 of the liquid phase of the heavy hydrocarbon fractions is connected to the receiver 15 of the liquefied fraction of heavy hydrocarbons using the second bypass pipe 17 and is configured to discharge solid impurities.

The proposed gas distribution station operates as follows.

Natural gas is taken from the high-pressure line 1 in front of the reducing device 3 and sent through the bypass gas line 4 to the energy recovery turbine expander 9 to produce low-temperature natural gas and condensate in the form of a liquefied fraction of heavy hydrocarbons during expansion in the turbine expander 12 of unit 9.

At positive ambient temperatures, the natural gas taken from the high-pressure line 1 is cooled in a heat exchanger-cooler 11 of high-pressure natural gas using the generated condensate in the form of a liquefied fraction of heavy hydrocarbons. At negative ambient temperatures, the natural gas taken from the high-pressure line 1 is sent directly to the turboexpander 12 of unit 9 through the first bypass line 16.

The overpressure of natural gas in the turboexpander 12 of unit 9 is accompanied by a sharp decrease in gas temperature, which causes precipitation of solid hydrates of water, carbon dioxide CO ₂ and condensate in the form of a liquefied fraction of heavy hydrocarbons. The power of the turboexpander 12 is transmitted to an electric generator 10 connected to one shaft. The low-temperature natural gas at the outlet of the turboexpander 12 of the installation 9 is sent to the separator-separator 13 of the liquid phase of the low-temperature natural gas.

The separated condensate in the form of a liquefied fraction of heavy hydrocarbons with an admixture of solid particles of CO ₂ and water hydrates is sent to a separator-separator 14 of the liquid phase of the heavy hydrocarbon fractions to extract solid impurities and remove them through the existing removal of solid impurities.

The purified condensate in the form of a liquefied fraction of heavy hydrocarbons can be used to cool high-pressure natural gas in a heat exchanger-cooler 11 at positive ambient temperatures, and at negative ambient temperatures it can be directly supplied to the receiver 15 through the second bypass pipe 17.

The produced condensate in the form of a liquefied fraction of heavy hydrocarbons can be used as motor fuel, for example, for vehicles, burning in boiler units and combustion chambers of power plants.

The separated low-temperature natural gas is sent to a heat exchanger-cooler of an air compressor of a gas turbine unit 5 with a reversed gas generator, the units and assemblies of which are not conventionally shown in the drawing.

The heat exchanger-cooler of the air compressor is used at positive ambient temperatures to dry the outside air, at which moisture condensation occurs with further drainage of the released moisture.

At negative ambient temperatures, the separated low-temperature natural gas is sent directly to the heat exchanger-cooler of the inverted gas generator of the gas turbine unit 5 through the bypass pipeline.

The inverted gas generator of the gas turbine unit 5 is cooled by low-temperature natural gas produced in an energy recovery turbine expander 9. In the process of heat exchange of low-temperature natural gas with exhaust gases from the inverted gas generator, the exhaust gases of the inverted gas generator are drained with further drainage of the released moisture.

The low-temperature natural gas heated by the heat obtained from the exhaust gas from the inverted gas generator of the gas turbine unit 5 is sent to a heat recovery turbine expander 7 to utilize the low potential heat of high pressure natural gas when it is expanded in a heat recovery turbine expander 7, which is exited through a bypass gas line 4 line 2 of low pressure natural gas. The power of the heat-utilizing turboexpander unit 7 is transmitted to an electric generator 8 connected to one shaft.

The operation of the gas turbine unit 5 with the inverted gas generator, the units and assemblies of which are not shown in the drawing, is carried out according to the scheme:

suction of external air into the flow part of the air compressor,

cooling and drying in an air compressor heat exchanger-cooler,

compressing it in a multi-stage air compressor,

supply of heat in the combustion chamber,

expansion in the compressor turbine and power turbine,

overexpansion in the turbine of the inverted gas generator,

cooling and drying in a heat exchanger-cooler,

compression in the booster compressor.

The power of the power turbine of a gas turbine unit 5 is transmitted to an electric generator 6 connected to one shaft.

Example 1 specific implementation.

The proposed gas distribution station having a gas turbine unit 5 based on a gas turbine engine (GTE) of the NK-16ST type with an estimated effective efficiency η _e = 0.277.

A gas turbine engine of the NK-16ST type, using a reversed gas generator installed in an existing gas duct behind a gas turbine engine, has the following thermodynamic cycle parameters:

the temperature of the dried air at the inlet to the compressor 273.15 K,

cyclic air flow rate 78.87 kg / s,

the degree of pressure increase in the compressor π _to = 9.5744,

the temperature in the combustion chamber T _ks = 1100 K,

fuel gas consumption in the combustion chamber 0.8824 kg / s,

the temperature of the combustion products in front of the power turbine T _g = 826.34 K,

the temperature of the combustion products behind the over-expansion turbine of the reversed gas generator at the inlet to the heat exchanger-cooler T _g = 522.3 K,

the pressure of the combustion products behind the over-expansion turbine of the reversed gas generator at the inlet to the heat exchanger-cooler R _g = 0,0361 MPa,

the temperature of the combustion products at the entrance to the booster compressor behind the heat exchanger-cooler reversed gas generator T _g = 273.15 K,

the pressure of the combustion products at the inlet to the booster compressor behind the heat exchanger-cooler of the inverted gas generator R _g = 0,0346 MPa,

effective efficiency η _e = 0.353,

the temperature of the combustion products at the exhaust behind the booster compressor of the inverted gas generator is 383.13 K.

The use of the indicated gas turbine engine with a reversed gas generator makes it possible to obtain effective power on the shaft of a power turbine for driving an electric generator 6, equal to 16 MW.

In order to reduce the pressure of the transported natural gas at an initial pressure of 5.5 MPa and a flow rate of 100 kg / s, the following are used:

energy recovery turbine expander 9, including the following elements:

heat exchanger-cooler 11 natural gas high pressure with parameters:

natural gas at the inlet T _pg = 288.15 K, P _pg = 5.5 MPa,

natural gas at the outlet T _pg = 285.15 K, P _pg = 5.4 MPa,

purified condensate at the inlet T _ok = 255.75 K, P _ok = 3.1 MPa,

purified condensate at the outlet T _ok = 275.91 K, P _ok = 3 MPa,

the consumption of purified condensate G _o = 9.9 kg / s;

a turboexpander 12 of an energy recovery installation having an estimated isentropic efficiency = 0.87 with the parameters:

natural gas at the inlet T _pg = 285.15 K, P _pg = 5.4 MPa,

low-temperature natural gas at the outlet T _pg = 254.54 K, P _pg = 3.3 MPa,

the power for driving the electric generator 10 is equal to 4.782 MW;

separator-separator 13 of the liquid phase of low-temperature natural gas with the parameters:

low-temperature natural gas at the inlet T _pg = 254.54 K, P _pg = 3.3 MPa,

separated low-temperature natural gas at the outlet T _pg = 255.15 K, P _pg = 3.2 MPa,

the flow rate of the separated low-temperature natural gas at the outlet G _pr = 89.1 kg / s,

condensate flow rate at the outlet G _k = 10.9 kg / s;

separator-separator 14 of the liquid phase of the heavy hydrocarbon fractions with the parameters:

condensate at the inlet T _pg = 255.15 K, P _pg = 3.2 MPa,

purified condensate at the outlet T _ok = 255.75 K, P _ok = 3.1 MPa,

the consumption of purified condensate G _ok = 9.9 kg / s,

the consumption of impurities of solid particles at the output G _ptc = 1 kg / s;

receiver 15 of a liquefied fraction of heavy hydrocarbons for storing purified condensate with parameters:

purified condensate at the inlet T _ok = 275.91 K, P _ok = 3 MPa,

the consumption of purified condensate G _ok = 9.9 kg / s;

heat-utilizing turboexpander unit 7 having a calculated isoentropic efficiency = 0.87 with the parameters:

at the input T _pg = 337.13 K, P _pg = 3 MPa,

at the output T _pg = 281.07 K, P _pg = 1.25 MPa,

the power for driving the electric generator 8 is 10.175 MW.

In general, with a natural gas flow rate of 100 kg / s and an initial pressure of 5.5 MPa, the total electric power of the proposed gas distribution station spent on driving electric generators 6, 8 and 10 is 30.649 MW, and the effective efficiency of the proposed gas distribution station is a distribution system natural gas is 0.676.

The use of more economical gas turbine engines, as well as an increase in the initial pressure of the transported natural gas, will lead to an even greater increase in the effective efficiency of the proposed gas distribution station.

Example 2 specific implementation.

The proposed gas distribution station having a gas turbine unit 5 based on a gas turbine engine of the GTA-6RM type with an estimated effective efficiency η _e = 0.258.

A gas turbine engine of the GTA-6RM type, using a reversed gas generator installed in an existing gas duct behind a gas turbine engine, has the following thermodynamic cycle parameters:

the temperature of the dried air at the inlet to the compressor 273.15 K,

cycle air consumption 40 kg / s,

the degree of pressure increase in the compressor π _to = 8.523,

the temperature in combustion chamber T _kc = 1050 K,

fuel gas consumption in the combustion chamber 0.4918 kg / s,

the temperature of the combustion products in front of the power turbine T _g = 770,27 K,

the temperature of the combustion products behind the over-expansion turbine of the reversed gas generator at the inlet to the heat exchanger-cooler T _g = 507.75 K,

the pressure of the combustion products behind the over-expansion turbine of the reversed gas generator at the inlet to the heat exchanger-cooler R _g = 0.0364 MPa,

the temperature of the combustion products at the entrance to the booster compressor behind the heat exchanger-cooler reversed gas generator T _g = 273.15 K,

the pressure of the combustion products at the entrance to the booster compressor behind the heat exchanger-cooler of the inverted gas generator R _g = 0,0349 MPa,

effective efficiency η _e = 0,316,

the temperature of the combustion products at the exhaust behind the booster compressor of the inverted gas generator is 383.13 K.

The use of the indicated gas turbine engine with a reversed gas generator makes it possible to obtain effective power on the shaft of a power turbine for driving an electric generator 6, equal to 6.86 MW.

In order to reduce the pressure of the transported natural gas at an initial pressure of 5.5 MPa and a flow rate of 50 kg / s, the following are used:

energy recovery turbine expander 9, including the following elements:

heat exchanger-cooler 11 natural gas high pressure with parameters:

natural gas at the inlet T _pg = 288.15 K, P _pg = 5.5 MPa,

natural gas at the outlet T _pg = 285.15 K, P _pg = 5.4 MPa,

purified condensate at the inlet T _ok = 255.75 K, P _ok = 3.1 MPa,

purified condensate at the outlet T _ok = 275.91 K, P _ok = 3 MPa,

the flow rate of the purified condensate G _ok = 4.95 kg / s;

a turboexpander 12 of an energy recovery installation having an estimated isentropic efficiency = 0.87 with the parameters:

natural gas at the inlet T _pg = 285.15 K, P _pg = 5.4 MPa,

low-temperature natural gas at the outlet T _pg = 254.54 K, P _pg = 3.3 MPa,

the power for driving the electric generator 10 is 2.3912 MW;

separator-separator 13 of the liquid phase of low-temperature natural gas with the parameters:

low-temperature natural gas at the inlet T _pg = 254.54 K, P _pg = 3.3 MPa,

separated low-temperature natural gas at the outlet T _pg = 255.15 K, P _pg = 3.2 MPa,

the flow rate of the separated low-temperature natural gas at the outlet G _pg = 44.55 kg / s,

condensate flow rate at the outlet G _k = 5.45 kg / s;

separator-separator 14 of the liquid phase of the heavy hydrocarbon fractions with the parameters:

condensate at the inlet T _pg = 255.15 K, P _pg = 3.2 MPa,

purified condensate at the outlet T _ok = 255.75 K, P _ok = 3.1 MPa,

the consumption of purified condensate G _ok = 4.95 kg / s,

the consumption of impurities of solid particles at the output of G _ppt = 0.5 kg / s;

receiver 15 of a liquefied fraction of heavy hydrocarbons for storing purified condensate with parameters:

purified condensate at the inlet T _ok = 275.91 K, Ρ _ok = 3 MPa,

the flow rate of the purified condensate G _ok = 4.95 kg / s;

heat-utilizing turboexpander unit 7 having a calculated isoentropic efficiency = 0.87 with the parameters:

at the input T _pg = 339.59 K, P _pg = 3 MPa,

at the output T _pg = 283.29 K, P _pg = 1.25 MPa,

the power for driving the electric generator 8 is equal to 5.1308 MW.

In general, with a natural gas flow rate of 50 kg / s and an initial pressure of 5.5 MPa, the total electrical power of the proposed gas distribution station spent on driving electric generators 6, 8 and 10 is 14.2368 MW, and the effective efficiency of the proposed gas distribution station natural gas distribution system is 0.65.

The use of more economical gas turbine engines, as well as an increase in the initial pressure of the transported natural gas, will lead to an even greater increase in the effective efficiency of the proposed gas distribution station.

Thus, in comparison with the prototype, while maintaining the reliability of operation, the possibility of varying the modes of a gas turbine unit 5 with an inverted gas generator, as well as the use of low-temperature natural gas produced in an energy recovery turbine expander 9, increases the efficiency (up to 76%) of the proposed gas distribution stations and reduction of emissions (up to 60%) of nitrogen oxides in the process of condensation of moisture vapor contained in the exhaust gases of a gas turbine 5 with inverted gas generator, eliminating the pyrolysis of natural gas, expanding the functionality by obtaining condensate in the form of a liquefied fraction of heavy hydrocarbons.

The proposed gas distribution station makes it possible to increase the efficiency of electric energy removal from one kilogram of natural gas, to widely vary the power of electric generators depending on consumer requests, to ensure guaranteed values of pressure and temperature of the gas transported in gas distribution systems, and also to utilize: the heat of the combustion products of a gas turbine engine, physical exergy of natural gas transported through trunk pipelines under high im pressure.

Claims (3)

1. A gas distribution station containing high and low pressure highways of natural gas interconnected by means of a reducing device and through a bypass gas pipeline in which a gas turbine installation and a heat recovery turbine expander are installed, each of which has an electric generator connected to an electricity consumer, characterized in that it is equipped with an energy recovery turbine expander with an electric generator connected to an electric power consumer and which is capable of generating low-temperature natural gas and condensate in the form of a liquefied fraction of heavy hydrocarbons, the gas turbine unit is made in the form of a gas turbine unit with a reverse gas generator with the possibility of cooling it with low-temperature natural gas, and the heat-utilizing turbine expander unit is configured to utilize the low-potential heat of natural gas, heated exhaust gas reversed gas generator, while energy recovery turbo-child The nuclear installation contains a high-pressure natural gas heat exchanger-cooler, the first inlet of which is connected to the high-pressure line of natural gas, and the first outlet is to the inlet of the expander, the outlet of which is connected to the separator-separator of the liquid phase of the low-temperature natural gas, the first outlet of which is connected to the gas turbine installation and the second exit with a separator-separator of the liquid phase of the heavy hydrocarbon fractions connected to the second inlet of the high pressure natural gas heat exchanger-cooler a second output of which is connected to a receiver of a liquefied fraction of heavy hydrocarbons. 2. The gas distribution station according to claim 1, characterized in that the bypass gas pipeline has a first bypass pipeline connecting the first inlet and first outlet of the high pressure natural gas heat exchanger-cooler, and the separator-separator of the liquid phase of the heavy hydrocarbon fractions is connected to the receiver of the liquefied fraction of heavy hydrocarbons using the second bypass line. 3. The gas distribution station according to claim 1 or 2, characterized in that the separator-separator of the liquid phase of the heavy hydrocarbon fractions is configured to discharge solid impurities.

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