RU2576951C2 - Gas evacuation method for disconnected section of gas pipeline - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method includes delivery of gas to nozzle of gas ejector and gas evacuation by this gas ejector from disconnected section of pipeline to parallel line or section next to the disconnected one, at that to the from disconnected section of pipeline fluid-gas ejector is coupled additionally and its nozzle is communicated with fluid pump, while output of fluid-gas ejector through separator is communicated to parallel line of gas pipeline or section of gas pipeline next to the disconnected section. Input to fluid pump is communicated with a vessel with fluid placed under separator, thereafter as evacuation intensity decreases gas ejector is switched off and gas evacuation from the disconnected section is made by fluid-gas ejector switching on delivery of fluid to its nozzle.

EFFECT: ensuring complete gas evacuation from the disconnected section.

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 repair and maintenance work.

A known method of pumping gas from a disconnected section of a gas pipeline, comprising supplying compressed gas from a compressor to an ejector nozzle and pumping gas out of a disconnected section of a gas pipeline by this ejector (see patent RU No. 2108489 C1, IPC ⁶ F04D 25/02, published on 04/10/1998, )

However, this method of pumping gas requires the use of bulky equipment, namely: a compressor with a gas turbine drive with sound attenuation and gas cooling devices behind the compressor, so the implementation of this method of pumping gas is complex and expensive.

A known method of pumping gas from a repaired section of a gas pipeline, including, together with supplying a gas to a nozzle of a gas ejector and pumping gas from a repaired section by this gas ejector, also a booster device, and then a compressor for pumping gas into a discharge pipe of a gas pipeline (see patent RU No. 2386862 C1, IPC F04D 25/02, F17D 1/02, F04F 5/54, F04B 41/00, published on 04/20/2010).

However, this method of pumping gas also requires the use of bulky equipment: an additional booster device with a drive, a compressor, a device for regulating the reduction in the flow area, etc.

Closest to the invention in technical essence and the achieved result is a method of pumping gas from a disconnected section of the gas pipeline (see patent RU No. 2167343 C1, IPC ⁷ F04F 5/54, published on 05/20/2001).

This method of pumping gas, including the supply of gas to the nozzle of the gas ejector and the pumping of gas by the gas ejector from the disconnected section of the gas pipeline by connecting the nozzle of the gas ejector to the section preceding the disconnected section, and the outlet of the gas ejector is connected to a parallel line of the gas pipeline or to the next one after the disconnected section of the gas pipeline and then feed gas into the nozzle of the gas ejector and pump gas from the disconnected section of the pipeline to the parallel string of the gas pipeline or to the next disconnected m section of the gas pipeline. The method also includes pumping gas with a two-stage gas ejector to increase the depth of pumping, i.e. increase the efficiency of the pumping method.

A disadvantage of the known method of pumping gas is that with its increased efficiency, while remaining quite simple and universal, it does not allow to achieve complete pumping of gas from the disconnected section of the gas pipeline.

An object of the invention is to ensure complete pumping of gas from a disconnected section of the pipeline up to atmospheric pressure and below.

The specified technical problem in a method of pumping gas from a disconnected section of a gas pipeline, including supplying gas to a nozzle of a gas ejector and pumping gas from a disconnected section of a gas pipeline to a parallel string or to a section following a disconnected section, is achieved by additionally connecting a disconnected section of the gas pipeline a liquid-gas ejector is connected, the nozzle of which is in communication with the hydraulic pump, and the outlet from the liquid-gas ejector through a separator is communicated with a parallel thread of the gas pipeline or the portion of the pipeline following the disconnected section, while the inlet to the hydraulic pump is communicated with a liquid container located under the separator, after which, as the pumping intensity decreases, the gas ejector is turned off and gas is pumped out of the disconnected section of the pipeline by the liquid-gas ejector, turning on the liquid his nozzle.

Thus, the efficiency of the liquid-gas ejector due to the possibility of increasing its compression ratio allows increasing the depth of gas pumping in the disconnected section of the gas pipeline up to atmospheric and below atmospheric up to complete pumping and thus preparing the disconnected section for repair work.

The drawing shows a diagram of a system for pumping gas from a disconnected section of the pipeline, explaining the method of pumping gas.

On the line 1 of the gas pipeline between the linear valves 2 and 3, there is a section 4. The gas ejector 6 is located in the bypass unit 5 in front of the disconnected section 4. The low-pressure cavity 7 communicates with the disconnected section 4 through the shut-off valve 8 and the nozzle 9 of the gas ejector 6 through the shut-off valve 10 is connected to the section 11 preceding the disconnected section 4. The output 12 of the gas ejector 6 through the shut-off valve 13 and the bypass unit 14 is connected to the second thread 15 of the gas pipeline.

The disconnected section 4 of the gas pipeline is additionally communicated through shut-off valves 8 and 16 with a low-pressure cavity 17 of the liquid-gas ejector 18. The nozzle 19 of the liquid-gas ejector 18 is in communication with the hydraulic pump 20 fed through the valve 21 from the tank 22 with liquid. The output 23 of the liquid-gas ejector 18 through the separator 24, the shut-off valve 25 and the bypass unit 14 is in communication with the second thread 15 of the gas pipeline.

It is possible to pump gas from the disconnected section 4 to the section of the gas pipeline following the disconnected section through the shut-off valve 26, the pipeline 27 and the bypass unit 28.

Gas evacuation is as follows.

The linear valves 2 and 3 are closed. When the shut-off valves 16 and 25 are closed, the shut-off valves 8, 13 and 10 are opened, thereby turning the gas ejector 6 into operation and pumping gas from the disconnected section through the bypass unit 14 into the second string 15 of the gas pipeline.

As the compression ratio of the ejector 6 decreases, the intensity of gas pumping from the disconnected section 4 decreases to the level of pumping depth set for it. At this point, the gas ejector 6 is turned off by closing the shut-off valve 13. Next, the liquid-gas ejector 18 is turned on, opening the valve 21, and the hydraulic pump 20 supplies liquid under pressure to its nozzle 19. As a result, liquid-gas ejector 18 is formed at the outlet 23 of the liquid-gas ejector 18. the gas mixture under high pressure, which, falling on the separator 24, is divided into gas, which is sent through the open shut-off valve 25 through the bypass unit 14 to the second string 15 of the gas pipeline, and to the liquid, which drains into the tank 22 under the separator 24.

Along with the injection of pumped gas to the second string 15 of the gas pipeline, it is possible to pump gas into the section behind the disconnected section 4 through the shut-off valve 26, the pipeline 27 and the bypass unit 28.

Claims (1)

A method of pumping gas from a disconnected section of a gas pipeline, including supplying gas to a nozzle of a gas ejector and pumping gas from a disconnected section of a gas pipeline to a parallel string or to a section following a disconnected section, characterized in that a liquid-gas additionally is connected to the disconnected section of the pipeline an ejector whose nozzle is in communication with the hydraulic pump, and the outlet of the liquid-gas ejector through the separator is communicated with a parallel line of the gas pipeline or with a section of the gas pipeline, as follows behind the disconnected section, while the entrance to the hydraulic pump is communicated with a liquid container located under the separator, after which, as the pumping intensity decreases, the gas ejector is turned off and gas is pumped out of the disconnected section of the pipeline by the liquid-gas ejector, turning on the liquid supply to its nozzle.