RU2004108957A - GAS PIPELINE COMPRESSOR STATION - Google Patents

Claims (11)

1. A gas pipeline booster station, characterized in that it is installed in an underground gas storage facility or in a gas field or directly at these facilities and includes systems for purifying process gas from mechanical impurities and drying from moisture carried out with the gas, as well as gas pumping units connected at the inlet of the process piping piping with a system for preparing at least a process gas and at the outlet with a process gas cooling installation and through a shut-off arm a tour supplying and discharging pipelines with a main gas pipeline, and the process gas cooling unit is equipped with at least one gas air cooling apparatus predominantly consisting of at least two heat exchange sections, each heat exchange section of which is made with a multi-row bundle of finned one-way pipes that form within of each row in the projection onto a conventional plane normal to the flow vector of the external heat-transfer medium supplied to the pipes — the cooling air flow, and passing through the central longitudinal axis of the pipes of each row, sections of full aerodynamic opacity, corresponding to projections onto the indicated plane of the pipes without taking into account finning, sections of full aerodynamic transparency, corresponding to projections onto the indicated plane of the gaps between the edges of the edges of adjacent pipes facing each other, and sections of incomplete aerodynamic transparency, each limited on one side of a conditional straight line running along the tops of the ribs, and on the other hand, by the contour of the pipe body along the ribs, and the specific ratio per unit area of the mentioned conditional plane of the total projection areas of these sections with different aerodynamic transparency in each row is respectively (0.85-1.15) :( 1.82-2.17) :( 1.80 -2.19). 2. The booster compressor station according to claim 1, characterized in that it is made with a parallel collector piping of gas pumping units, comprising a connection unit, including security, bypass, inlet taps, and a cleaning unit is placed behind the inlet tap, which is connected to the inlet through a corresponding pipeline centrifugal full-pressure superchargers of gas-pumping units, which are connected through the outlet valve and pipelines to the gas air cooling apparatus, which is also through the outlet and ocher The taps and pipelines are connected to the main gas pipeline, while the bypass valve is made with a diameter smaller than the diameter of the inlet valve, and the nominal diameters of the pipelines are successively decreasing from the connection unit to the inlet of the centrifugal superchargers, and after centrifugal superchargers, at least after their output taps, increasing to the diameter of the pipeline through which the gas enters the gas air-cooling apparatus and after exiting it into the main gas pipeline, the piping being equipped with plex gas-dynamic protection made in the form of a system of check valves and candle taps, and check valves are installed on the outlet pipelines of each gas pumping unit and additionally on the output loop of the compressor station's process gas pipeline, and the plug taps are installed in an amount exceeding at least one number check valves and are placed along the gas flow, the first in the installation area of the inlet valve with the possibility of candle operation for any combination of inlet and / or of the inlet cranes, and the remaining candle valves are connected to the piping technological pipelines mainly in front of the check valves along the gas flow, and the piping is equipped with two jumpers with cranes, one of which is external and connected to the inlet pipe to the inlet valve and to the outlet pipe after the outlet valve and is intended for the transit passage of gas through the main gas pipeline when the compressor station is turned off, and the second internal jumper, technologically parallel I am the first one, connected at the inlet and at the outlet, respectively, after the inlet tap and in front of the outlet tap, designed to equalize the pressures in the plant's process pipelines and to ensure the station operates in the “station ring” mode, while the cross-sectional area of the pipeline of the second jumper is assumed to be smaller than the throughput area the cross-section of the pipeline of the external jumper is 2.5-7.0 times, and the flow area of the tap installed on the internal jumper is 0.075-0.25 of the cross-sectional area the gadfly of this jumper. 3. The booster compressor station according to claim 1, characterized in that at least part of the gas pumping units are driven by a centrifugal supercharger from a gas turbine, the gas pumping unit is made in the form of a stationary installation, mainly of the type GT-6-750 or GTK-16 produced by the Ural Motor Plant, or GT-700-5, or GT-700-6, or GTK-10, or GTK-10-2, or GTK-10-4 produced by the Nevsky Plant, the gas pumping unit is made with a gas turbine drive of a centrifugal supercharger, containing gas aviation turbines reconstructed for use in gas pumping units, for example, GPA-Ts-6.3 or GPA-Ts-6.3A, or GPA-Ts-6.3A, mainly with an engine of the brand D-336, or GPA-Ts-6.3B mainly with an engine of the brand D-336 or NK-14ST, or GP-Ts-16, or GP-Ts-16L mainly with an engine of the brand AL-31ST or GPA-Ts-16A mainly with an engine of the brand NK-38ST or GPA-Ts- 25, mainly with an engine of the NK-36ST brand, the gas pumping unit is made with a gas turbine drive of a centrifugal supercharger in the form of a ship gas turbine installation, for example, according to the GPA-2 type , 5 mainly with an engine of the GTG-2.5 or GPU-6 brand, mainly with an engine of the DT-71 or GPU-10A brand, mainly with an engine of the DN-70 or GPA-Ts-16S brand, mainly with an engine of the DG-90 or GPU-brand 25 mainly with an engine like DN-80. 4. The booster compressor station according to claim 1, characterized in that at least part of the gas pumping units are made mainly electric drive type STM-4000, or STD, or STD-12.5, or type A3-4500-1500 or SGD- 12.5. 5. The booster compressor station according to claim 1, characterized in that at least part of the gas pumping units are equipped with gas compressor units with piston units, mainly of the type 10GK, or 10GKM, or 10GKN, or 10GKNA. 6. The booster compressor station according to claim 1, characterized in that at least one gas pumping unit is made with a full-pressure centrifugal gas blower with a compression ratio of from 1.45 to 1.51, preferably of type N-196-1.45, or 650-21-1, or 820-21-1, either of type Cooper-Bessemer type superchargers of brands 280-30, or 2BB-30, or Nuovo-Pignoni type superchargers of types PCL-802/24, or PCL-1001-40. 7. The booster compressor station according to claim 1, characterized in that at least a portion of the gas pumping units is provided with a recuperator installed predominantly directly behind the gas turbine unit in the exhaust hot gas exit zone for utilizing the heat of the exhaust gas with heating of the air supplied to the turbine, the recuperator is made in the form of a regenerative air heater, mainly in the form of a monoblock with a cylinder-conical body, at least within most of its length, or the recuperator is made in the form of a regenerative air heater of a block type, preferably sectional-block and is in communication with the outlet of the gas turbine unit and with the atmosphere through a gas duct with a diffuser at the hot gas supply to the heat exchange zone of the regenerative air heater and a confuser at the outlet from it. 8. The booster compressor station according to claim 1, characterized in that the preparation system for the process, as well as starting, and / or fuel, and / or pulsed gas contains at least one cyclone type dust collector, or at least one a cyclone type dust collector and at least one filter separator installed sequentially along the gas after the cyclone dust collector or cyclone dust collector system, the filter separator comprising at least two process sections having replaceable filters, a filter section, rednaznachennoy coagulation liquid and mechanical retention of the particles and separation section, designed to complete the cleaning gas from moisture, and has a condensate, heating system, advantageously electric, at least the lower part of the filter separator and equipped with control and measuring equipment. 9. The booster compressor station according to claim 1, characterized in that each heat-exchange section of the gas air-cooling apparatus is made of a horizontal type or the heat-exchange sections of the gas-air cooling apparatus are installed with the formation of slopes. 10. The booster compressor station according to claim 1, characterized in that the multi-row bundle of finned tubes of each heat exchange section of the gas air-cooling apparatus is communicated through gas inlet and outlet chambers and gas supply and exhaust manifolds with the plant technological pipelines, wherein the multi-row tube bundle of the heat exchange section contains from two to fourteen rows, and each heat-exchange section of the gas air-cooling apparatus includes a vessel for external cooling medium with longitudinal side walls transverse to the end walls formed by the inlet and outlet chambers of the in-pipe medium and the bottom formed by the fan diffuser bodies, which are installed under the heat-exchange sections, and from one to six fans are installed under each section, and each fan is placed in an aerodynamic protective casing containing a diffuser and a smooth collector entrance, while the collector of the smooth entrance is made in a longitudinal section of variable curvature with a configuration, at least from the side of the inner surface, for example, along niskata, and mainly round in plan, with the entrance mouth of the casing in the zone of transition of the collector to the diffuser made with a diameter of 0.6-0.95 of the width of the heat exchange section, and the diffuser of the casing of each fan is made in its upper part in the area adjacent to the frame elements heat-exchange section with the configuration of the outlet edge contour, which provides the possibility of attaching to the corresponding elements of the contour of the frame of the section, and the fans are made mainly of two - or three-blade and with adjustable change the angle of rotation of the blades, with the fan wheel driven mainly straight from the low-speed gearless motor, its power is preferably 2,5-12,0 kW and the nominal rotational speed is preferably 290-620 min ^-1. 11. The booster compressor station according to claim 1, characterized in that it is equipped with a system of gas air-cooling apparatuses forming a structural complex integrated into at least one field of gas air-cooling apparatuses - “ABO field”, and is made with supporting structures, combined into a common spatial unit within the "ABO field", including with the possibility of partial support of the supporting structure of each subsequent gas air cooling apparatus to the supporting structure of the previous one.