RU2543710C1 - Gas pumping compressor station (versions) - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: gas pumping compressor station contains a gas pumping unit with the process compressor, which is driven by a gas-turbine unit comprising an axial compressor. Upstream the process compressor a gas cooler is installed. Upstream the axial compressor of the gas-turbine unit a heat exchange unit is installed, the inlet and outlet branch pipes of the cold heat-carrier cavity of which are connected to the outlet branch pipe of the cavity of the refrigerating agent of gas cooler and inlet branch pipe of the compressor of heat utilising refrigerating machine, which comprises the gas cooler.

EFFECT: decrease of power consumption at gas compression in the process compressor and air compression in the axial compressor of the gas-turbine unit, improvement of overall performance of compressor station.

5 cl, 3 dwg

Description

The invention relates to the field of gas pumping by compressor stations and can be used in the workshops of compressor stations when transporting gas through gas pipelines.

Known compressor station for pumping gas, containing a gas pumping unit with a process compressor, the drive of which is a gas turbine unit, gas air cooling apparatus located behind the discharge pipe of the process compressor [Alimov SV, Malanichev VA, Migacheva L.A. Increasing the throughput capacity of gas pipelines // Business Glory of Russia, vol. VI 2008 - I 2009. - P.90-91.].

A disadvantage of the known technical solution is the significant energy consumption for gas compression associated with a high level of gas temperature at the inlet to the process compressor, although gas cooling in air coolers after its compression allows to increase the throughput of the gas pipeline.

Known technical solution aimed at reducing energy costs for air compression in the axial compressor of a gas turbine installation. Improving the efficiency of a gas turbine installation is achieved by cooling the atmospheric air entering the axial compressor using absorption refrigeration units using the heat of the exhaust gases of a gas turbine installation [Kuzmina TG, Teslya ES On increasing the power and efficiency of a gas turbine engine in the warm season due to cooling of cyclic air // Gas Turbine Technologies. - 2008, No. 1. - S.16-18.].

The disadvantage of this technical solution is that absorption refrigeration units have significant weight and dimensions. In addition, a cooling tower must be provided in the circuit of the absorption refrigeration unit, for the operation of which it is necessary to ensure the circulation of water.

These drawbacks are partially eliminated in a compressor station containing a gas pumping unit with a process compressor, the drive of which is a gas turbine unit including an axial compressor, an air purifying device containing at least cyclone elements with atmospheric air entry zones and a dust collector is installed on its inlet duct , clean air exhaust manifold, gas cooler installed at the inlet of the process compressor and made as a part of heat use guide refrigerating machine comprising a compressor, an inlet is connected to the outlet fitting of the cavity refrigerant gas cooler [RF patent №2418 991, IPC F04D 27/00, publ. 05/20/2011.]. Thanks to the cooling of the gas to compression in the process compressor, the energy consumption for gas compression is significantly reduced, the efficiency of the compressor station is increased.

This technical solution is the closest to the proposed set of features and is taken as a prototype.

However, the cold generated in a heat-using refrigeration machine is not used efficiently.

The objective of the invention is to increase the efficiency of the compressor station by reducing the energy consumption for compressing the atmospheric air entering the axial compressor of the gas turbine unit by cooling it with cold generated in a heat-using refrigerating machine.

To achieve this technical result, the compressor station according to its first embodiment, comprising a gas pumping unit with a process compressor, the drive of which is a gas turbine unit including an axial compressor, an air-purifying device comprising at least a clean air exhaust manifold is installed in its inlet duct, gas cooler installed at the inlet of the process compressor and made as part of a heat-utilizing refrigeration machine, including The compressor, the inlet pipe of which is connected to the outlet pipe of the gas cooler refrigerant cavity, according to the invention is equipped with a heat exchanger located between the air-cleaning device and the inlet tract of the gas turbine compressor unit, the inlet and outlet pipes of the coolant cavity of which are connected respectively to the outlet pipe of the gas cooler refrigerant cavity and the inlet pipe of the compressor of the heat-consuming refrigeration machine, and the inlet and outlet th hot coolant cavity heat exchanger tubes are connected respectively to the collector outlet of clean air and air purifying device input path of an axial compressor of a gas turbine installation.

To achieve a technical result in a compressor station for pumping gas according to its second embodiment, comprising a gas pumping unit with a process compressor, the drive of which is a gas turbine unit including an axial compressor, an air purifying device comprising at least cyclone elements is installed in its inlet duct with air inlet areas, dust collector, clean air exhaust manifold, gas cooler installed at the inlet of the process compressor and made in the form of a part of a heat-utilizing refrigerating machine including a compressor, the inlet of which is connected to the outlet of the cavity of the gas cooler refrigerant, according to the invention, the air-cleaning device is arranged with a chamber located between the atmospheric air inlet areas and the dust collector, limited by the walls, bottom and a lid, with inlet and outlet nozzles placed on the walls at opposite ends in the lower and upper parts of the chamber and connected to correspondingly to the outlet pipe of the gas cooler refrigerant agent cavity and to the compressor inlet pipe of the heat-utilizing refrigeration machine, nests with seating surfaces in which cyclone elements are installed are made on the bottom and cover of the chamber, the chamber is sealed from the environment by sealing elements located between the seating surfaces of the nests and the outer surfaces of the cyclone elements.

New is that the landing surfaces of the nests on the bottom and cover are made coaxially.

In addition, the inlet and outlet nozzles of the chamber are separated from each other by a partition with cylindrical bushings covering the outer surfaces of the cyclone elements with annular gaps. Also new is the fact that cyclone elements are made of a material with high thermal conductivity.

Thanks to the introduction of new features, a constant circulation of the refrigerant exiting the gas cooler is ensured through the cavity of the cold heat carrier of the heat exchanger (chamber of the air-purifying device), which allows to reduce the temperature of the air entering through the air-purifying device and the cavity of the hot heat-carrier of the heat exchanger (cyclone elements of the air-purifying device) into axial compressor, reduce the energy costs of compressing air in an axial gas turbine compressor installation, increase the efficiency of the compressor station for pumping gas.

The invention is illustrated by drawings, presented in figures 1, 2, 3.

Figure 1 shows a functional diagram of a compressor station according to the first embodiment.

Figure 2 shows the functional diagram of the compressor station according to the second embodiment.

Figure 3 shows a diagram of an air cleaning device.

The compressor station according to the first embodiment contains (Fig. 1) an inlet manifold of a gas main 1 connected in series, a gas purification unit 2, an inlet stop valve 3, a gas cooler 4, a process compressor 5 mechanically connected to its drive 6, which uses a gas turbine installation , outlet stop valves 7, outlet manifold 8 of the main gas pipeline. The main elements of a gas turbine installation are an axial compressor 9, mechanically connected to a high pressure turbine 10, a power turbine 11, mechanically connected to a process compressor 5, a combustion chamber 12. The gas turbine installation inlet duct connected to the inlet of the axial compressor 9 contains an air receiver 13, an air purifier device 14, heat exchanger 15 and connecting pipes. The output path of the gas turbine installation, associated with the output of the power turbine 11, contains a heat recovery unit 16, made in the form of a boiler. The gas cooler 4 and the heat recovery unit 16 are also elements of a heat-utilizing turbo-refrigerating machine 17, which further comprises a turbine 18 mechanically connected to the turbocharger 19, a condenser 20, a flow regulator 21, a pump 22, a throttle-regulator 23.

The compressor station according to the second embodiment (FIG. 2) is similar to the first embodiment. The only difference is that the heat exchanger is combined with an air-cleaning device 14. The air-cleaning device includes (Fig. 3) cyclone elements 24 with zones of atmospheric air inlet 25, a clean air exhaust manifold 26, a dust collector 27, a chamber 28 with an inlet 29 and output 30 nozzles located on the walls 31, 32 in the lower and upper parts of the chamber and separated from each other by a partition 33 with cylindrical bushings 34, covering the outer surfaces of the cyclone elements 24 with annular gaps. On the lid 35 and the bottom 36 of the chamber, nests 37, 38 are made with coaxial seating surfaces into which the cyclone elements 24 are mounted. Between the outer surfaces of the cyclone elements and the seating surfaces of the nests, sealing elements 39 are provided to seal the chamber 28 with respect to the environment. At the places where the cyclone elements enter the dust collector 27 and the clean air exhaust manifold 26, landing surfaces 40, 41 are also arranged. To increase the efficiency of air cooling, the cyclone elements can be made of a material with high thermal conductivity.

The compressor station according to the first embodiment (figure 1) operates as follows.

Gas from the inlet manifold of the main gas pipeline 1 enters the purification unit 2, where it is cleaned of condensate and mechanical impurities, then passes through the inlet stop valves 3 and is cooled in the gas cooler 4 to a predetermined temperature. Cooled gas enters the process compressor 5, where it is compressed to a predetermined pressure, passes through the outlet shutoff valve 7, and enters the outlet manifold 8 of the main gas pipeline for further transportation.

The technological compressor 5 is driven from a gas turbine unit 6. Air from the atmosphere through an air receiver 13, an air purifier 14, a heat exchanger 15 enters an axial compressor 9, which compresses it to the required pressure and supplies it to the combustion chamber 12. In the combustion chamber 12, air is supplied heat due to combustion of fuel gas and the temperature of the combustion products increases sharply. Further, the combustion products expand in the high pressure turbine 10, the power turbine 11, giving off mechanical energy. The turbine 10 gives its energy to the axial compressor 9, and the power turbine 11 to the process compressor 5, bringing its rotor into rotation. Expanded products of combustion - exhaust gases with a sufficiently high temperature pass through a heat recovery unit 16 installed in the outlet tract of a gas turbine installation and give off heat to the refrigerant of a heat-utilizing turbo-refrigerating machine.

Turbo-refrigerating machine used to generate cold, which is used to cool the gas in the gas cooler 4 and air cooling in the heat exchanger 15, operates as follows. The refrigerant under pressure boils in the heat recovery unit 16. The refrigerant vapor leaving the heat recovery unit 16 overheats to a temperature depending on the temperature level of the exhaust gas, i.e. heat utilized. Vapors of the refrigerant from the heat recovery unit 16 enter the turbine 18, where, expanding, they perform work and then pass to the condenser 20. Vapors of the refrigerant from the gas cooler 4, which is also the evaporator of the turbo-refrigerating machine, pass through the heat exchanger 15 and are sucked in by the turbocharger 19 and after compression, it also enters the condenser 20. The turbocharger 19 receives the mechanical energy necessary for compressing the refrigerant vapor from the turbine 18. The liquid refrigerant after exiting the condensate Ator 20 in the flow controller 21 is branched into two streams: the first is sent through a throttle controller 23 to supply gas cooler (evaporator) 4 and heat exchanger 15 and fed via the second pump 22 to heat exchanger 16.

The compressor station according to the second embodiment (FIG. 2) operates similarly to the first embodiment. The difference is that the refrigerant after the gas cooler 4 (FIG. 2) through the inlet pipe 29 (FIG. 3) enters the chamber 28 of the air-cleaning device, passes through the annular gaps between the cylindrical bushings 34 of the partition 33 and the outer surfaces of the cyclone elements 24 and through the outlet pipe 30 is fed into the suction pipe of the compressor 19 (figure 2) of a heat-utilizing refrigeration machine. Air from the atmosphere through the inlet zones 25 enters the cyclone elements 24, is cooled by a refrigerant washing the outer surfaces of the cyclone elements in the area of the cylindrical bushings 34, is cleaned of mechanical impurities, condensate and through the clean air exhaust manifold 26 enters the inlet tract of the axial compressor of the gas turbine unit .

Thus, the use of the cold generated during the heat recovery of the exhaust gases of a gas turbine unit using a heat-using chiller to cool the pumped gas and air before they are compressed in the process compressor and axial compressor of the gas turbine unit, respectively, will reduce the energy costs for their compression, increase the efficiency of the compressor station as a whole.

Claims (5)

1. Compressor station for pumping gas, containing a gas pumping unit with a process compressor, the drive of which is a gas turbine unit including an axial compressor, an air purifying device comprising at least a clean air exhaust manifold, a gas cooler installed at the inlet of the process compressor and made in the form of a part of a heat-consuming refrigeration machine, including a compressor, the inlet of which is connected to the outlet pipe of the gas cooler refrigerant cavity, characterized in that it is provided with a heat exchanger located between the air-cleaning device and the inlet duct of the gas turbine axial compressor, the inlet and outlet pipes of the coolant cavity of which are connected respectively to the outlet pipe of the gas cooler refrigerant cavity and the compressor inlet heat-using refrigeration machine, and the inlet and outlet pipes of the cavity of the hot coolant are warm exchanger are respectively connected to the collector of the clean air outlet air purifying apparatus and an input path of an axial compressor of a gas turbine installation. 2. A compressor station for pumping gas, comprising a gas pumping unit with a process compressor, the drive of which is a gas turbine unit including an axial compressor, an air purifying device comprising at least cyclone elements with zones of atmospheric air inlet, a dust collector, is installed on its inlet duct , a clean air exhaust manifold, a gas cooler installed at the inlet of the process compressor and made as part of a heat-utilizing refrigeration machine a compressor, the inlet of which is connected to the outlet of the cavity of the refrigerant agent of the gas cooler, characterized in that the air-cleaning device is made with a chamber located between the atmospheric air inlet areas and the dust collector, limited by the walls, bottom and cover, with an inlet and outlet pipes located on the walls at opposite ends in the lower and upper parts of the chamber and connected respectively to the outlet pipe of the cavity of the refrigerant gas cooler and to the inlet pipe of the compressor of the heat-consuming refrigeration machine, while on the bottom and cover of the chamber there are nests with seating surfaces in which the cyclone elements are installed, the chamber is sealed from the environment by sealing elements located between the landing surfaces of the nests and the outer surfaces of the cyclone elements. 3. The compressor station according to claim 2, characterized in that the landing surfaces of the nests on the bottom and cover are made coaxial. 4. The compressor station according to claim 2, characterized in that the inlet and outlet nozzles of the chamber are separated from each other by a partition with cylindrical bushings covering the outer surfaces of the cyclone elements with annular gaps. 5. The compressor station according to claim 2, characterized in that the cyclone elements are made of a material with high thermal conductivity.

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