RU2577672C2 - Section of manifold gas pipeline - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: section of a gas pipeline (1) between linear cranes (2) and (3), from which it is necessary to pump gas for its subsequent repair, is the closest upstream a gas pumping unit (4). A gas ejector (9) is installed in the last bypass unit (5) upstream the gas pumping unit so that the outlet of the bypass unit (10) is fixed on the flange of a joint (8) in a relief pipe (6) at the outlet from the disconnected section, and a nozzle (11) via a stop valve (13) is connected to an injection gas pipeline directly downstream the gas pumping unit (4). Since gas pressure directly downstream the gas pumping unit (4) is higher than upstream the linear valves at the inlet to the gas pumping unit (4) and there is effect of gas pumping with the gas pumping unit (4) itself from the cavity downstream the linear valve, the gas pressure difference at the gas ejector (9) increases.

EFFECT: increased extent of gas pumping from a disconnected pipeline section.

1 dwg

Description

The invention relates to the field of gas pumping, in particular to gas pumping devices for pumping gas from a gas pipeline disconnected for repair.

A gas main is known with a section disconnected for pumping gas out of it, containing at least two linear valves, each of which is equipped with a bypass assembly. On the bypass node there is a gas ejector pumping gas from the disconnected section to the parallel string of the gas pipeline (see patent No. 2140582 C1, IPC ⁷ F04F 5/54, published ^on 10.27.1999).

A disadvantage of the known main gas pipeline is the insufficient efficiency of gas pumping in the section of the gas pipeline closest to the entrance to the gas pumping unit (GPU), because the gas pressure in front of the nozzle of the gas ejector, taken in front of the disconnected section of the gas pipeline, drops along the gas pipeline due to the presence of jumpers between the threads of the gas pipeline.

A well-known gas pipeline in which the construction of bypass nodes for pumping gas is performed, where the gas ejector is mounted and connected by a nozzle to the bypass node of the gas pipeline section in front of the disconnected section, and the low-pressure chamber to the disconnected section (see patent RU No. 2167342 C1, IPC ⁷ F04F 5 / 54, published May 20, 2001).

A disadvantage of the known main gas pipeline is also the limited depth of gas pumping from the disconnected section of the gas pipeline in connection with a drop in gas pressure at the inlet to the ejector nozzle in sections of the gas pipeline close to the receiving compressor station.

An object of the invention is to provide an increase in gas pressure in front of the nozzle of the gas ejector and thereby increase its efficiency in the section of the gas pipeline directly in front of the receiving compressor station.

The indicated technical problem for the section of the main gas pipeline located directly in front of the gas compressor unit with a bypass assembly equipped with a gas ejector is achieved by the fact that the gas ejector is installed on the bypass assembly at the outlet of the disconnected section of the gas pipeline, and the gas ejector nozzle is connected to the discharge gas pipeline directly behind the gas pumping unit.

The drawing shows a section of the main gas pipeline.

The section of gas pipeline 1 between linear valves 2 and 3, from which it is necessary to pump gas for subsequent repair, is the closest (last) in front of the gas pumping unit (GPU) 4.

In the last bypass unit 5 in front of the gas compressor unit 4, located behind the disconnected section 1, in the bypass pipe 6 equipped with a shut-off valve 7, a gas ejector 9 is installed through connector 8. By its output 10, the nozzle 11 of the gas ejector 9 is connected to the high-pressure line 12 of the gas compressor unit 4 through shut-off valve 13. The low-pressure cavity 14 of the gas ejector 9 is connected to the disconnected section 1 of the gas pipeline through the pipe 15, flange connector 16, the shut-off valve 17 and the bypass pipe 18.

The output 10 of the gas ejector 9 is also communicated through a shut-off valve 19 and a pipeline 20 with a bypass assembly 21 with a parallel thread 22 of the gas pipeline.

Work on pumping gas as follows.

When the linear valves 2 and 3 are closed, shut-off valves 17, 7 and 13 are opened. As a result of the gas supply to the nozzle 11 of the gas ejector 9, gas is pumped out from the gas pipeline section 1 through the low-pressure cavity 14 and the gas ejector 9 exits 10 into the section following the disconnected section immediately before the GPA 4.

Thus, due to an increase in pressure at the inlet to the nozzle 11 of the gas ejector 9 due to gas extraction directly behind the gas compressor unit 4 and a decrease in back pressure at the outlet 10 of the gas ejector 9 due to the effect of gas evacuation from the cavity after the linear valve 3 and due to gas evacuation by ourselves GPA 4 increases the compression ratio of the gas ejector 9 and thereby the depth of gas pumping from the disconnected section 1 of the pipeline.

To pump gas into a parallel thread 22 of the gas pipeline through the bypass node 21 close the shut-off valve 6 and open the shut-off valve 19.

Claims (1)

A section of the main gas pipeline located directly in front of the gas pumping unit with a bypass unit equipped with a gas ejector, characterized in that the gas ejector is installed on the bypass pipe of the bypass unit at the outlet of the disconnected section of the gas pipeline, and the nozzle of the gas ejector is connected to the pumping gas pipeline directly behind the gas pumping unit.