RU2779109C1 - Gas compressor unit of a compressor station with a sub-atmospheric utilization power plant - Google Patents

Abstract

FIELD: gas compressor units.

SUBSTANCE: gas compressor unit of the compressor station contains a compressor, a combustion chamber, a power gas turbine, a natural gas blower, a regenerative air heater and a subatmospheric utilization power plant; in front of the compressor of the drive gas turbine plant, an M-cycle apparatus is installed with “dry” and “wet” air channels separated by a metal wall covered on the side of the “wet” air channel with a hydrophilic surface wetted by water. When operating in summer mode, the “wet” outlet is connected by an air duct to the inlet of a regenerative air heater, the outlet of which is connected to the turbine inlet of a subatmospheric utilization power plant; its output through the heat exchange surface of the air cooler-condenser and the compressor is connected to the atmosphere; the inlet of the hydrophilic surface is connected to the inlet water pipeline with the pump, and its outlet is connected by the cooling water pipeline to the heat exchange surface of the air cooler-condenser. The sprinkler is installed at the air inlet to the regenerative air heater; the pipeline bypassing the hydrophilic surface of the M-cycle apparatus connects the inlet water pipeline with the cooling water pipeline, the pipeline for supplying condensate to the spray device connects the air cooler-condenser housing with the spray device; shut-off valves are additionally installed on the inlet water pipeline, on the pipeline bypassing the hydrophilic surface of the M-cycle apparatus and on the pipeline for supplying condensate to the spraying device.

EFFECT: gas compressor unit improvement.

1 cl, 1 dwg

Description

The invention relates to the field of gas transportation through main gas pipelines and can be used in the creation of highly economical utilization gas turbine power plants for power supply to the auxiliary needs of compressor stations and external consumers of electrical energy.

Known subatmospheric gas turbine plant operating on the reverse Brayton cycle with heat recovery of the gas turbine and the apparatus of the M-cycle. (A.A. Khalatov, S.D. Severin, P.I. Brodetsky, V.S. Maisotsenko “Subatmospheric reverse Brayton cycle with output heat regeneration according to the Maisotsenko cycle”. Reports of the National Academy of Sciences of Ukraine 2015. Ris 1). In this installation, the outlet of the gas turbine is connected through the M-cycle apparatus to the inlet of the compressor. The use of the M-cycle apparatus makes it possible to compress dry cold air in the compressor and expand air with increased enthalpy in the turbine. The hydrophilic surface covering the wall of the “wet” air channel of the M-cycle apparatus is moistened with water. When it evaporates, the humidity and enthalpy of the air increase due to the use of environmental energy. In the "dry" channel, condensation of the moisture contained in the air occurs.

The supply of dry cold air to the compressor significantly reduces the energy consumption for its compression. Due to the strong air humidification in the M-cycle apparatus, its enthalpy at an air temperature of 300-400°C is equivalent to the enthalpy of combustion products at a temperature of 1300-1400°C. The increase in enthalpy occurs due to the use of the energy of the environment - the psychrometric temperature difference. The use of psychrometric energy of atmospheric air and an increase in the degree of regeneration significantly increases the thermal efficiency of the cycle and reduces the cost of a gas turbine plant.

The disadvantage of the subatmospheric gas turbine plant is that it is not used to recover the heat of the exhaust gases of the drive gas turbine plant of the compressor station.

A combined utilization gas turbine power plant of a main gas pipeline compressor station is known (RF Patent No. 2744139, F02C 6/18, 12/29/2016), consisting of a gas turbine drive unit containing a compressor, a combustion chamber, a power gas turbine, a natural gas blower, a regenerative air heater installed in the exhaust gas duct of a power gas turbine and a subatmospheric utilization power plant containing an air turbine, an air cooler-condenser, a compressor, an electric generator. An M-cycle apparatus with "dry" and "wet" air channels, which are separated by a metal wall covered with an infiltration layer from the side of the "wet" channel, is installed in front of the compressor of the drive gas turbine plant. The air cooler-condenser is installed between the air turbine and the compressor. The inputs of the "dry" and "wet" channels of the M-cycle apparatus are connected to the atmosphere, the output of the "dry" channel is connected to the input of the compressor of the gas turbine drive unit; the outlet of the "wet" channel is connected by a humid air duct to the inlet of the regenerative air heater, its outlet is connected to the inlet of the turbine of the subatmospheric utilization power plant, the outlet of which is connected to the atmosphere through the heat exchange surface of the air cooler-condenser and the dry air compressor. The case of the air cooler-condenser is connected via condensate to the condensate discharge pipeline with the pump.

The positive qualities of the combined utilization gas turbine power plant, adopted as a prototype for the proposed invention, is that its operation in the summer period of the year provides an increase in thermal efficiency and power of the drive gas turbine plant by reducing the air temperature in front of its compressor, as well as thermal efficiency and capacity of a subatmospheric utilization power plant due to the use of environmental energy in the M-cycle apparatus and the psychrometric difference in temperatures of moist and dry atmospheric air.

The disadvantage of the prototype in the winter period of his work, at negative outdoor temperatures, is the impossibility of supplying water to the hydrophilic surface of the M-cycle apparatus.

The technical objective of the invention is to improve the design of the gas-pumping unit of the compressor station in order to increase efficiency and power during its operation both in summer and in winter periods of the year.

The task is achieved by the fact that the gas pumping unit of the compressor station contains a compressor, a combustion chamber, a power gas turbine, a natural gas blower, a regenerative air heater and a subatmospheric utilization power plant containing an air turbine, an air cooler-condenser, a compressor, an electric generator; an M-cycle apparatus with "dry" and "wet" air channels separated by a metal wall covered from the side of the "wet" air channel with a hydrophilic surface wetted by water is installed in front of the compressor of the drive gas turbine plant; the inputs of the "dry" and "wet" channels are connected to the atmosphere, the output of the "dry" channel is connected to the inlet of the compressor, when the unit is operating in summer mode, the outlet of the "wet" is connected by an air duct to the inlet of the regenerative air heater, the outlet of which is connected to the inlet of the turbine of the subatmospheric utilization power plant ; its output through the heat exchange surface of the air cooler-condenser and the compressor is connected to the atmosphere; the inlet of the hydrophilic surface is connected to the inlet water pipeline with the pump, and its outlet is connected by a cooling water pipeline to the heat exchange surface of the air cooler-condenser; the housing of the air cooler-condenser is connected via condensate to the condensate discharge pipeline with the pump, and it additionally uses a spray device, a pipeline bypassing the hydrophilic surface of the M-cycle apparatus, a pipeline for supplying condensate to the spray device; the spraying device is installed at the air inlet to the regenerative air heater; the pipeline bypassing the hydrophilic surface of the M-cycle unit connects the inlet water pipeline with the cooling water pipeline, the pipeline for supplying condensate to the spray device connects the air cooler-condenser housing with the spray device; shut-off valves are additionally installed on the inlet water pipeline, on the pipeline bypassing the hydrophilic surface of the M-cycle apparatus and on the pipeline for supplying condensate to the spraying device.

On FIG. Figure 1 shows a schematic thermal diagram of a gas-pumping unit of a compressor station with a subatmospheric utilization power plant. It contains a compressor 1, a combustion chamber 2, a power gas turbine 3, a natural gas blower 4, an M-cycle apparatus 5 with "dry" and "wet" air channels, an inlet water pipeline 6 with a pump, an air duct 7, a pipeline bypassing the hydrophilic surface of the apparatus M-cycle 8, sprinkler device 9, regenerative air heater 10, electric generator 11, air turbine 12, compressor 13 of subatmospheric power plant, air cooler-condenser 14 with heat exchange surface, condensate pipeline 15 with pump, cooling water pipeline 16, pipeline 17 for supplying condensate to sprinkler device.

The inlet of the compressor 1 is connected to the atmosphere through the "dry" air channel of the M-cycle apparatus. The inlet of the "wet" air channel of this apparatus 5 is connected to the atmosphere, the inlet of its hydrophilic surface is connected to the inlet water pipeline 6. The outlet of the "wet" air channel is connected by an air duct 7 through the heating surface of the regenerative air heater 10 to the inlet of the air turbine 12, the rotor of which is connected by a common shaft with an electric generator 11 and with a compressor 13 of a subatmospheric power plant. The outlet of the air turbine 12 is connected through the heat exchange surface of the air cooler-condenser 14 with the inlet of the compressor of the subatmospheric power plant 13, the outlet of which is connected to the atmosphere. The case of the air cooler-condenser 14 is connected by a pipeline 15 of the condensate to the pump and pipeline 17 with the nozzles of the spray device 9. The outlet of the hydrophilic surface of the M-cycle apparatus is connected by a cooling water pipeline 16 to the heat exchange surface of the air cooler-condenser 14.

During the summer period, the gas pumping unit of the compressor station with a subatmospheric utilization power plant operates as follows. Atmospheric air is supplied to the inputs of the "dry" and "wet" air channels of the M-cycle apparatus 5. Water is supplied to the input of the hydrophilic surface of the "wet" channel through the inlet water pipeline 6. Due to its evaporation from the hydrophilic surface, the metal wall of the M-cycle apparatus and atmospheric air in the “dry” channel are cooled. The cooled air is supplied to the inlet of the compressor 1, compressed and fed into the combustion chamber 2, where the fuel is burned. The combustion products are expanded in the power gas turbine 3, which drives the natural gas blower 4, and through the regenerative air heater 10 they are discharged into the atmosphere. In the “wet” channel of the M-cycle apparatus 5, atmospheric air is cooled and humidified, moist air from this channel is supplied through the air duct 7 to the regenerative air heater 10, where it is heated by the heat of the exhaust gases of the drive gas turbine 3. Due to the supply of cold moist air to the regenerative air heater 10 it intensifies heat exchange with a decrease in the temperature of gases discharged into the atmosphere. Humid air, heated in a regenerative air heater to 380-420°C, is expanded in an air turbine 12 of a subatmospheric power plant, the useful work of which is used to drive a compressor 13 and generate electricity in an electric generator 11. Expanded in an air turbine 12, moist air is cooled in an air cooler-condenser 14, where by supplying cooling water (not evaporated water) from the hydrophilic surface of the M-cycle apparatus to its heat exchange surface through pipeline 16, the steam contained in the humid air is condensed. From the housing of the air cooler-condenser 14, the condensate is discharged into the atmosphere through a condensate pipeline with a pump 15. Dry air from the air cooler-condenser 14 is fed into the compressor of the subatmospheric power plant 13, compressed and discharged into the atmosphere.

In winter, at negative air temperatures, as well as in summer, atmospheric air is supplied to the inlets of the air channels of the M-cycle apparatus 5. The shut-off valve on the inlet water pipeline 6 is closed and the water supply to the hydrophilic surface of this apparatus is stopped. The shut-off valve is opened on the pipeline bypassing the hydrophilic surface of the M-cycle apparatus 8. Through the pipeline 6 and the cooling water pipeline 16, cooling water is supplied to the heat exchange surface of the air cooler-condenser 14, which is used to cool the moist air in the air cooler-condenser 14 and condense the steam contained in it . As in summer mode, the useful work of the air turbine is used to drive the compressor of the subatmospheric power plant 13 and generate electricity in the electric generator 11. Humid air expanded in the air turbine 12 is cooled in the air cooler-condenser 14, but cold air is supplied to its heat exchange surface. water from the inlet pipeline 6 through the pipeline bypassing the hydrophilic surface of the M-cycle apparatus and the cooling water pipeline 16. The steam condensate formed in the air cooler-condenser 14 is fed through the condensate supply pipeline 17 to the nozzles of the spraying device 9 and the air supplied through the air duct 7 is humidified into the regenerative air heater 10. Dry air from the air cooler-condenser 14 is supplied to the compressor of the subatmospheric power plant 13, compressed and discharged into the atmosphere.

Thus, the proposed gas-pumping unit, when operating in summer mode, allows:

- increase thermal efficiency and power by reducing the energy consumption for compression in the dry cold air compressor and reducing the temperature of the exhaust gases leaving the regenerative air heater;

- significantly increase the air enthalpy in front of the turbine of the subatmospheric utilization power plant, increase its thermal efficiency and electric power by humidifying the air in the "wet" air channel of the M-cycle apparatus, cooling the air and condensing the steam in the air cooler-condenser through the use of cold water flowing down from the hydrophilic surface of the “wet” channel of the M-cycle apparatus.

When operating in winter mode, the proposed gas compressor unit allows you to:

- to provide an increase in the efficiency and electric power of a subatmospheric utilization power plant with air cooling and steam condensation by supplying cold water to the heat exchange surface of the air cooler-condenser;

- provide air humidification in front of the regenerative air heater by spraying condensate in the spray device.

Claims (1)

Gas compressor unit of the compressor station, containing a compressor, a combustion chamber, a power gas turbine, a natural gas blower, a regenerative air heater, with a subatmospheric utilization power plant containing an air turbine, an air cooler-condenser, a compressor, an electric generator; an M-cycle apparatus with "dry" and "wet" air channels separated by a metal wall covered from the side of the "wet" air channel with a hydrophilic surface wetted by water is installed in front of the compressor of the drive gas turbine plant; the inputs of the "dry" and "wet" channels are connected to the atmosphere, the output of the "dry" channel is connected to the inlet of the compressor, when the unit is operating in summer mode, the outlet of the "wet" is connected by an air duct to the inlet of the regenerative air heater, the outlet of which is connected to the inlet of the turbine of the subatmospheric utilization power plant ; its output through the heat exchange surface of the air cooler-condenser and the compressor is connected to the atmosphere; the inlet of the hydrophilic surface is connected to the inlet water pipeline with the pump, and its outlet is connected by a cooling water pipeline to the heat exchange surface of the air cooler-condenser; the case of the air cooler-condenser is connected via condensate to the condensate discharge pipeline with a pump, characterized in that it additionally uses a spray device, a pipeline bypassing the hydrophilic surface of the M-cycle apparatus, a pipeline for supplying condensate to the spray device; the spraying device is installed at the air inlet to the regenerative air heater; the pipeline bypassing the hydrophilic surface of the M-cycle unit connects the inlet water pipeline with the cooling water pipeline, the pipeline for supplying condensate to the spray device connects the air cooler-condenser housing with the spray device; shut-off valves are additionally installed on the inlet water pipeline, on the pipeline bypassing the hydrophilic surface of the M-cycle apparatus and on the pipeline for supplying condensate to the spraying device.

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