RU2167343C1 - Method of pumping out of gas from disconnected section of gas main - Google Patents

Abstract

FIELD: gas transfer equipment. SUBSTANCE: proposed method includes delivery of gas into nozzle of ejector and pumping out of gas by ejector from disconnected section of gas main. Gas is pumped out by gas transfer plant from section following disconnected section of gas main. Nozzle of ejector is connected to section preceding disconnected section. Outlet of ejector is connected to parallel line of gas main or to section of gas main following disconnected section, and then gas is delivered into ejector nozzle from section of gas main before disconnected section and gas is pumped from disconnected section of gas main into parallel line of gas main or into section of gas main following the disconnected section. Gas from section following the disconnected section of gas main is pumped out by gas transfer plant. EFFECT: enlarged possibility of pumping out of gas from disconnected section of gas main by means of ejector. 2 cl, 4 dwg

Description

 The invention relates to the field of gas pumping, in particular to gas pumping devices for repair and maintenance work on gas pipelines.

 A known method of pumping gas from a disconnected section of a gas pipeline, comprising supplying compressed gas from a supercharger to an ejector nozzle and pumping gas out of a disconnected section of a gas pipeline by this ejector (see, for example, patent RU 2108489 C1, class F 04 D 25/02, publ. 10.04 .98).

 However, this pumping method requires the use of bulky equipment, namely, the presence of a supercharger and a gas turbine drive with silencing and maintenance devices, as well as the need to coordinate the joint operation of the ejector - compressor and drive, which makes it difficult for the mobile pump to use this pumping method. In addition, gas cooling requires a significant amount of energy.

 The closest to the invention in technical essence and the achieved result is a method of pumping gas from a disconnected section of a gas pipeline, comprising supplying gas to an ejector nozzle and pumping gas from this disconnected section of a gas pipeline (see, for example, patent RU 2410582 C1, class F 04 F 5/54, publ. 10.27.99).

 This method of pumping from a disconnected section of a gas pipeline allows the use of gas pressure from an adjacent string of a main gas pipeline to pump gas from a disconnected section of a gas pipeline. However, this limits the scope of this pumping method.

 The problem to which the present invention is directed, is to expand the ability to pump gas from a disconnected section of the pipeline through an ejector.

 This problem is solved due to the fact that in the method of pumping gas from a disconnected section of a gas pipeline, including supplying gas to an ejector nozzle and pumping gas from a disconnected section of a gas pipeline by this ejector, from a section following a disconnected section of a gas pipeline, gas is pumped by a gas pumping unit to a section, the ejection nozzle is connected to the previously disconnected section, the ejector outlet is connected to a parallel gas pipeline thread or to the gas pipeline section following the disconnected section, and then gas is supplied to the nozzle zhektora portion of the pipeline before the disconnected portion, and gas is pumped from the disconnected part of the pipeline in parallel to the line of the pipeline or to the next portion of the disconnected portion of the pipeline, and gas is evacuated from the last gas compressor unit.

 In addition, gas pumping is possible with a two-stage ejector; in this case, gas from the first stage is supplied to the low-pressure cavity of the second stage of the ejector, and from the last gas is supplied to the parallel string of the gas pipeline or to the section of the gas pipeline that follows the disconnected section.

 The invention allows, as shown by studies, the use of compressed gas, which is located in the gas pipeline in front of the disconnected section of the gas pipeline for feeding into the nozzle of the ejector and, due to this, to ensure the operation of the ejector and pump gas from the disconnected section of the pipeline. In addition, it allows pumping out of the disconnected section of the gas pipeline when there are no two consecutive sections of the gas pipeline after the disconnected section of the gas pipeline, for example, when the disconnected section of the gas pipeline is near the gas pumping unit. Thus, it becomes possible to ensure the pumping of gas from the disconnected section of the pipeline without the use of additional energy sources, for example, mobile compressors, and to prevent almost completely the emission of gas from the disconnected section of the pipeline or the burning of gas from the disconnected section of the pipeline, for example, during repair work on the gas pipeline.

 As a result, the achievement of the objective of the invention is achieved — expanding the ability to pump gas from the disconnected section of the gas pipeline.

 In FIG. 1 shows a diagram of a device that implements the described method of pumping gas from a disconnected section of a gas pipeline, including at least two pipelines, in FIG. 2 is a diagram of a device that implements the described method of pumping gas from a disconnected section of a gas pipeline, including at least two pipelines using a two-stage ejector, FIG. 3 is a diagram of a device that implements the described method of pumping gas from a disconnected section of a gas pipeline, including one gas pipeline, in FIG. 4 is a diagram of a device that implements the described method of pumping gas from a disconnected section of a gas pipeline, including one line of a gas pipeline using a two-stage ejector.

 The main gas pipeline can consist of at least two threads 1, 2 of the gas pipeline or one thread 1 of the gas pipeline, and valves 3, 4, 5, 6 are installed on each line of the gas pipeline over a certain distance. Near each valve 3, 4, 5 , 6 a bypass assembly is made with at least two valves, respectively 7 and 8, 9 and 10, 11 and 12, 13 and 14. In the gap between the valves 7 and 8, 9 and 10, 11 and 12, 13 and 14 are installed respectively, bypass pipelines 15, 16, 17 and 18, and the bypass piping 15 installed on the bypass node in front of the disconnected gas section the piping is made with an ejector 19, and the bypass pipe 17 adjacent to it of the adjacent gas pipe 2 is made with a receiving flange connection 20. The nozzle 21 of the ejector 19 is connected through a valve 7 to a section of the gas pipeline in front of the valve 3 along the gas pumping path. The low-pressure chamber of the ejector 19 is connected through the valve 8 to the disconnected section of the gas pipeline between the valves 3 and 4, and the outlet of the ejector 19 through the flange connection 20 is connected to the bypass pipe 17 and through it to the parallel thread 2 of the gas pipeline, which in turn is connected to the gas pumping unit 22. In the case of using a two-stage ejector, nozzles 23, 24 of the first and second degrees of the ejector are connected through the valve 7 to the gas pipeline section in front of the valve 3, while in front of the nozzle 24 of the second stage of the ejector, tanovlen valve 25.

 In the event that the gas pipeline is single-threaded, a bypass pipe 16 is made with a receiving flange connection 20 (see Figs. 3, 4) and the outlet of the ejector 19 is connected through a flange connection 20 to the bypass pipe 16 and through it to the next section of the gas pipeline .

 The method of pumping gas from a disconnected section of the pipeline is implemented as follows.

During repair or maintenance work, valves 3, 4 are closed. Valves 7, 8, 9, 10, 11, 12, 13, 14 are also in the closed position. As a result of the gas line 3 being closed by the valve 3 of the gas pipeline, the pressure in the gas line 1 before the valve 3 rises to its compression value in the gas pumping unit (approximately 70-75 kg / cm ² ), and the pressure in the gas pipeline section after the valve 3, as well as after the valves 5 and 6 is 10-30 kg / cm ² less due to pressure losses during gas pumping through the gas pipeline, and as a result of the operation of gas pumping units 22, which continue to pump gas from the threads 1, 2 of the gas pipeline, after the valve 4 the pressure will be even lower. Valves 7.8 and 12 are opened (in the case of a single-line gas pipeline, valve 10 is opened instead of valve 12). As a result, gas is supplied to the ejector nozzle 21 from the gas pipeline section in front of the gate valve 3 and gas is ejected by the ejector 19 from the disconnected gas pipeline section between the valves 3 and 4. From the gas pipeline section behind the gas valve 4, which follows the disconnected gas pipeline section, gas is pumped out by the gas pumping unit 22. As a result of the operation of the ejector 19, gas from the disconnected section of the gas pipeline is pumped into a parallel thread 2 of the gas pipeline through the bypass pipe 17 and valve 12, and then this gas is supplied together with the gas of the thread 2 in the gas pumping unit 22 of this thread. If the gas pipeline is single-flow (see Fig. 3), then gas from the disconnected section of the gas pipeline is supplied by the ejector 19 to the next section of the gas pipeline following the disconnected section through the bypass pipe 16 and valve 10, after which this gas enters the gas pumping unit 22 of the pipe 1 of the gas pipeline.

 Gas can also be pumped out by a two-stage ejector (see Figs. 2 and 4), while gas from the first stage is fed into the low-pressure cavity of the second stage of the ejector, and from the last, which is the outlet of the ejector, gas is supplied to the parallel thread 2 of the gas pipeline or to the next beyond the disconnected section of the pipeline. In this case, compressed gas from the gas pipeline section in front of the gate valve 3 is simultaneously supplied to both nozzles 23 and 24 of the two-stage ejector, and by means of valve 25, the gas supply to the second stage nozzle 24 can be regulated or even the gas supply to this nozzle 24 can be completely shut off. In this case, the two-stage ejector will work in the same way as the single-stage ejector 19 described above. Using a two-stage ejector is advisable when it is necessary to intensify the pumping of gas from the disconnected section of the gas pipeline and get in the last pain e low pressure. As a result, the discharge of pumped gas into the environment is almost completely prevented, which preserves valuable raw materials and helps protect the environment.

 The present invention can be used on any gas pipelines where repair and maintenance work is required.

Claims (2)

 1. A method of pumping gas from a disconnected section of a gas pipeline, comprising supplying gas to an ejector nozzle and pumping gas from a disconnected section of a gas pipeline by this ejector, characterized in that gas is pumped out from a section following a disconnected section of a gas pipeline to a section prior to a disconnected section, the ejector nozzle is connected, the ejector exit is connected to a parallel gas pipeline thread or to the gas pipeline section following the disconnected section, and then gas is supplied to the ejector nozzle from the gas section wire disconnected portion and before the gas is pumped from the disconnected part of the pipeline in parallel to the line of the pipeline or to the next for the disconnected portion of the pipeline, and gas is evacuated from the last gas compressor unit.  2. The gas evacuation method according to claim 1, characterized in that the gas is evacuated by a two-stage ejector, while the gas from the first stage is supplied to the low-pressure cavity of the second stage of the ejector, and from the last gas is supplied to the adjacent gas pipeline or to the next section of the gas pipeline disconnected .

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