RU2154230C1 - Gas distributing station - Google Patents

Abstract

FIELD: gas industry; reduction of gas pressure in gas distributing stations of main gas lines. SUBSTANCE: station includes technological unit with high-pressure and low- pressure gas lines, vortex tube with hot and cold gas flow branch pipes, condensate receiver, hot and cold gas flow pipe lines, pressure regulator, cooler and temperature and flow rate control unit fitted in vortex tube; it consists of diaphragm mechanism, rod and wedge-shaped damper; one end of rod is connected with wedge-shaped damper shutting-off the nozzle inlet of vortex tube and other end is connected with diaphragm of diaphragm mechanism whose above-diaphragm chamber is connected with hot gas flow pipe line through adjustable valve. Condensate receiver is connected to vortex tube hot flow branch pipe. EFFECT: extended capabilities of gas distributing station; reduced overall dimensions of station. 14 cl, 2 dwg

Description

 The invention relates to the gas industry and can be used to reduce gas pressure in gas distribution stations of gas pipelines.

 A device for regulating gas pressure at gas distribution stations of high throughput (copyright certificate N 646318, MKI G 05 D 16/00, priority 16.05.75). This device contains a heater and a control valve sequentially installed on the gas pipeline, a throttle made in the form of a vortex tube, the inlet of which is connected to the gas pipeline to the heater, a separator, the inlet of which is connected to the outlet of the heated year stream from the vortex pipe, and the outlet - to the outlet of the cooled gas stream from the vortex tube and the gas pipe after the control valve, as well as a heat exchanger mounted on the control valve, through which the separator outlet is connected to the outlet of the cooled stream from the vortex tube would.

The disadvantages of the known device include:
the presence of a gas heater, complicating the design of the device and requiring material and labor costs in the manufacture. In addition, the gas heater requires the consumption of fuel gas, which, when burned, is released into the atmosphere in the form of flue gases, polluting the environment;
the hot gas stream from the vortex tube, after the moisture and condensate is removed by the separator, enters the gas pipeline after the control valve, this leads to the incomplete use of the positive temperature of the heated gas stream necessary for the stable operation of the pressure regulator and, as a result, to a decrease in its functionality
The closest in technical essence is the Potok gas distribution station (preliminary patent of the Republic of Uzbekistan N 2061, MKI F 25 B 11/00, priority 16.03.93) (prototype) containing a high pressure gas pipeline, a vortex tube, a pressure regulator with a pulse tube, a heat exchanger, a choke and a low pressure gas pipeline, while the vortex tube is installed at the station inlet so that its outlet for heated gas is communicated through a separator and pressure regulator with a low pressure gas pipeline, and the outlet for the cooled gas is communicated through and a choke coil of a low-pressure pipeline at a point downstream of the gas supply point connected thereto impulse tube.

The disadvantages of the device selected as a prototype include:
the presence of a separate separator, complicating the design of the station;
the presence of a throttle on the cold gas flow line, which also complicates the design of the station;
the inability to control the size of the cross section of the nozzle inlet, which reduces the technical capabilities of the station in terms of changing the temperature and flow parameters of hot and cold gas flows.

 The aim of the invention is to expand the functionality of the gas distribution station and reduce its size.

 This goal is achieved by the fact that in a gas distribution station containing a process unit with high and low pressure gas pipelines, a vortex tube with nozzles for hot and cold gas flows, a condensate cathedral tank, pipelines for hot and cold gas flows, a pressure regulator, a refrigerator, a temperature control unit has been introduced and flow parameters installed in a vortex tube and consisting of a membrane mechanism, a rod and a wedge-shaped damper, with one end of the rod connected to the wedge-shaped damper ,, which overlaps the nozzle inlet of the vortex tube, and its other end is connected to the membrane, a membrane mechanism, the supmembrane cavity of which is through an adjustable valve, connected to the hot gas flow pipeline. And the condensate collection tank is connected through the shutoff member to the nozzle of the hot stream of the vortex tube.

 The use of the additionally introduced temperature and flow rate control unit in the vortex tube of the gas distribution station provides the ability to smoothly change the temperature and flow parameters of hot and cold gas flows emerging from the vortex tube into the plant’s process equipment in those proportions that are sufficient to prevent hydrate formation in the pressure regulator and ensuring stable operation of technological equipment.

 The connection of the condensate collection tank through the shut-off element directly to the nozzle of the hot stream of the vortex tube eliminates the need for a separate separator, reducing the dimensions of the station, saving material and labor costs.

 The applicant does not know the design of gas distribution stations with a temperature and flow control unit installed in the vortex tube and with the connection of a condensate collection tank through the shut-off element to the vortex tube hot flow nozzle, which would expand the station's functionality.

 In FIG. 1 shows a diagram of a gas distribution station; in FIG. 2 is a section AA in FIG. 1.

 Gas distribution station (Fig. 1) contains a process unit 1, gas pipelines of high 2 and lower 3 pressures, a vortex tube 4. The vortex tube 4 is equipped with nozzles of hot 5 and cold 6 gas flows. The hot gas flow pipe 5 is connected by an end part through the hot gas flow pipe 7 to the pressure regulator 8. The lower part of the hot gas flow pipe 5 is connected by a line 9 through the shut-off element 10 with a condensate collecting tank 11. A low pressure gas pipeline 3 is connected to the pressure regulator 8. The pipe the cold stream 6 is connected by a pipe 12 through a refrigerating chamber 13 to a low pressure gas pipeline 3. In the upper part of the vortex tube 4 there is a control unit for temperature and flow parameters 14. Over-membrane cavity the diaphragm mechanism 15 (Fig. 2) of the temperature and flow rate control unit 14 is connected by line 16 through the control valve 17 to the hot gas pipeline 7. The stem 18 (Fig. 2) of the temperature and flow rate control unit 14 is connected at one end to the membrane mechanism membrane 19 15, and its other end is provided with a wedge-shaped shutter 20 for blocking the nozzle inlet 21 of the vortex tube 4.

 Gas distribution station operates as follows. Gas flows through a high pressure gas pipeline 2 into a vortex tube 4 installed with the process unit 1, known as the Rank-Hills vortex tube. In the vortex tube 4, due to its design features, the gas is divided into two streams - hot and cold. The vortex tube 4 is also a separator of liquid particles and solids. The liquid particles separated in the vortex tube 4 and mechanical impurities in the form of condensate from the hot flow pipe 3 are discharged via line 9 through the shut-off element 10 to the condensate collecting tank 11. Then, the purified and dried gas through the hot flow pipe 7 enters the pressure regulator 8, where it is reduced to a predetermined pressure and then through the low pressure gas pipeline 3 to the consumer. The cold gas stream from the pipe 6 through the pipe 12 enters the refrigeration chamber 13, in which the cold is taken, and is sent to the gas 3 od low pressure for mixing with the gas entered after the pressure regulator 8.

 Changes in temperature and flow parameters in the nozzle of the hot 5 and cold 6 gas flows of the vortex tube 4 occur using the node temperature and flow parameters 14 as follows. Heated and purified gas from the hot flow pipeline 7 through line 16 through the control valve 17 enters the supramembrane cavity of the membrane mechanism 15 of the temperature and flow control unit 14. In this case, the control valve 17 is pre-set to a predetermined output pressure sufficient to act on the membrane 19 mechanism 15, and therefore, the necessary movement of the rod 18 with a wedge-shaped damper 20 for the corresponding change in the size of the cross-sectional area of the nozzle inlet 21 of the vortex second pipe 4. The vortex tube 4 is provided with a temperature regulating unit and supplies the parameters 14, provides job distribution station, as part of the change of temperature and gas supplies parameters required for operation of the proportions, the square cross-sectional dimensions of the nozzle adjustment input 21 is automatic.

 Thus, the use of a temperature and flow rate control unit installed in a vortex tube in a gas distribution station made it possible to smoothly change these parameters within the required limits, which ensure stable operation of technological equipment and expand the station's functionality. The use of a vortex tube as a separator of liquid particles and solids by connecting a condensate collection tank to it made it possible to reduce the dimensions of the station, saving material and labor costs.

Claims (2)

 1. A gas distribution station comprising a process unit with high and low pressure gas pipelines, a vortex tube with hot and cold gas flows, a condensate collection tank, hot and cold gas flows, a pressure regulator and a refrigerator, characterized in that it is equipped with a temperature control unit and flow parameters installed in the vortex tube and consisting of a membrane mechanism, a rod and a wedge-shaped damper, with one end of the rod connected to the wedge-shaped damper, overlapping ayuschey nozzle entering the vortex tube and the other end thereof is connected with the membrane of the membrane mechanism nadmembrannaya cavity through which the steering valve is connected to the conduit the hot gas stream.  2. The gas distribution station according to claim 1, characterized in that the condensate collection tank is connected via a shut-off element to the nozzle of the hot stream of the vortex tube.

Images