RU2601912C1 - Device for gas evacuation from a disconnected section of multiline main gas pipeline - Google Patents

Abstract

FIELD: gas industry.

SUBSTANCE: device is intended for gas evacuation from a disconnected section of multiline main gas pipeline. Device comprises a two-stage ejector made in the bypass unit of the main gas line or connected to this bypass unit by means of flanges on the pipeline of discharging gas from a disconnected section and pipeline of gas injection into a section, which follows a pumping section, each stage of the two-stage ejector is equipped with a stop cock on active gas supply, and the section between a stop cock of active gas supply into the first stage of the ejector and its nozzle communicated with the gas supply pipeline through an additional stop cock from a disconnected section to a low-pressure chamber of the first stage of the ejector, output of which through the nozzle of passive gas and mixing chamber of the first stage is an input into circular active gas nozzle of the second stage of the ejector, output of second stage of the ejector is connected to the flange pipeline of discharging gas into the section, which follows a pumping section.

EFFECT: technical result is increased efficiency of the ejector.

1 cl, 1 dwg

Description

The invention relates to the field of gas pumping, in particular to gas pumping devices for pumping gas from a disconnected section of a gas pipeline in order to carry out repairs or preventive maintenance.

There is a known method of pumping gas from a disconnected section of a gas pipeline, with which gas is pumped out from a section following a disconnected section using an ejector, and then, using a second ejector, gas is pumped from a disconnected section to the section following the disconnected section (see patent RU No. 2140582, F04F 5 / 54, published on October 27, 1999).

The disadvantage of this method is the need to use two ejector devices on the bypass nodes of adjacent linear valves.

The closest in technical essence is the analogue described in patent RU No. 2167343, F04F 5/54, publ. 05/20/2001, taken as a prototype, in which gas is pumped out by a two-stage ejector, where gas from the first stage is supplied to the low-pressure cavity of the second stage of the ejector, and from the second stage, gas is supplied to the next section of the gas pipeline.

The disadvantage of this method of pumping gas is that it does not implement additional features to improve efficiency, i.e. pumping depth, as at the initial stage of pumping, when the pressure in the pumped-out section is high and it would be possible to increase the ejector productivity to reduce the pumping time, its first stage limits the flow rate from the pumped-out section due to the active component of the total flow through the first stage.

The task to which the invention is directed is to increase the efficiency (depth) of pumping gas from a disconnected section of the pipeline.

The problem is achieved in that in the known device containing a two-stage ejector made as part of the bypass node of the main gas pipeline or connected to this bypass node by means of flanges on the gas exhaust pipe from the disconnected section and the gas injection pipeline into the section following the pumped section, according to the proposed technical solution, in a two-stage ejector, each stage is equipped with a shut-off valve on the supply of active gas, and the section between the shut-off valve for supply of active gas into the first stage of the ejector and its nozzle through an additional shut-off valve is connected with the pipeline for supplying gas from the disconnected section to the low-pressure chamber of the first stage of the ejector, the exit of which through the nozzle of the passive gas and the mixing chamber of the first stage serves as an entrance to the annular nozzle of the active gas of the second stage of the ejector moreover, the outlet from the second stage of the ejector is connected to a flange on the gas injection pipeline into the section following the pumped-out section.

The technical result is to increase the performance of the ejector at the initial stage of pumping, since the second degree of the ejector receives gas from the pumped area through both nozzles (active and passive) of the first stage of the ejector.

The figure shows a device in which a two-stage ejector 1 includes an active gas nozzle 2 of the first stage, a low-pressure chamber 3 of the first stage of the ejector with a passive gas nozzle 4, and a displacement chamber 5 of the first stage, the output 6 of which serves as an entrance to the annular active gas nozzle 7 second stage. This nozzle is connected to the bias chamber — diffuser 8 of the second stage.

The two-stage ejector 1 can be part of the bypass unit 9 of the linear valve 10 of the gas pipeline 11, or connected to it for the period of shutdown of the pumped section 12 of the gas pipeline 11 between the linear valves 13 and 10. To connect the ejector 1 to the bypass node 9, use the flange 14 on the tee 15 on the section between the bypass valves 16 and 17 and the flange 18 on the tee 19 on the section between the bypass valves 17 and 20. To select the active gas to the ejector 1, the flange 21 is used between the bypass valves 22 and 23 of the bypass assembly 24 of the second (other) gas pipeline 25. on the bottom On the active gas, shut-off valves 26 and 27 are installed respectively at the entrance to the nozzle 2 of the first stage of the ejector and at the entrance to the annular nozzle 7 of the active gas of the second stage.

The pipeline 28 for supplying gas from the disconnected section to the low-pressure chamber 3 of the first stage of the ejector has a tap 29 to the shut-off valve 30 at the entrance to the cavity 31 between the shut-off valve 26 for supplying active gas to the first stage of the ejector and its nozzle 2. Exit 32 from the second stage of the ejector through the shut-off The valve 33 and the gas injection pipe 34 to the portion 35 behind the linear valve 10 are connected through the flange 18 of the tee 19 of the bypass assembly 9. The pipe 36 is used to take active gas from the bypass assembly 24 (flange 21) to the nozzles 2 and 7 of the ejector 1 through shut-off valves 26 and 27 with responsibly. Bypass unit 9 is equipped with a candle valve 37.

The device operates as follows. To prepare for pumping gas from the disconnected section 12, the pipe 28 is connected to the flange 14 on the tee 15 of the bypass unit 9, and the pipe 34 is connected to the flange 18 on the tee 19 of the same bypass unit 9. Next, the pipe 36 is connected to the flange 21 of the active gas from bypass node 24 of the second gas pipeline 25. The device is ready for pumping gas from section 12.

To turn on the device, the linear valves 13 and 10 are closed, the bypass valves 16, 17 and 20 are opened, thereby connecting the section 12 between the linear valves 13 and 10 with the section 35 behind the linear valve 10. Gas flows from the section 12 to the section 35 for account of the work of gas pumping units (GPU) at the receiving station of the main gas pipeline. At the time of pressure equalization in sections 12 and 35, the ejector 1 is turned on, for which the bypass valve 17 is closed, the shut-off valves 30 and 33 are opened, and then the bypass valve 22 and the shut-off valve 27 at the entrance to the annular nozzle 7 of the second stage of the ejector. As a result, the second stage of the ejector is included in the operation. Moreover, its productivity is increased due to the additional supply of passive gas to the mixing chamber 5 through the nozzle 2. When reaching the maximum degree of pressure increase at the second stage of the ejector, close the valve 30 and open the valve 26 for supplying active gas to the nozzle 2 of the first stage of the ejector, which, including the operation provides a higher degree of increase in pressure in the ejector 1.

By the time the pressure in the pumped-out section 12 stops decreasing, the pumping process is stopped, for which the ejector 1 is turned off by closing the bypass valves 20 and 22, as well as the bypass valve 16 and the shut-off valves 26 and 30. For bleeding from the device and pipelines 29, 36 and 34 of gas residues through the open shut-off valve 33 open the candle valve 37. After bleeding the gas, the candle valve 37 is closed, and the device for pumping gas is disconnected from the bypass nodes 9 and 24 through the flanges 14, 19 and 21.

Claims (1)

A device for pumping gas from a disconnected section of a multi-line main gas pipeline, comprising a two-stage ejector made as part of a bypass assembly of a main gas pipeline or connected to this bypass assembly by means of flanges on a gas discharge pipe from a disconnected section and a gas injection pipe to a section following the pumped section, different the fact that in a two-stage ejector, each stage is equipped with a shut-off valve on the supply of active gas, and the section between the shut-off valve the supply of active gas to the first stage of the ejector and its nozzle through an additional shut-off valve are in communication with the pipeline for supplying gas from the disconnected section to the low-pressure chamber of the first stage of the ejector, the exit of which through the nozzle of the passive gas and the mixing chamber of the first stage serves as an entrance to the ring nozzle of the active gas of the second stage an ejector, the exit from the second stage of the ejector being connected to a flange on the gas injection pipeline to the section following the pumped section.

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