SU1683819A1 - Device for injecting dispersed corrosion inhibitor into pipelines - Google Patents

Abstract

The invention relates to the protection of metals against corrosion and can be used in gas pipelines and in the gas, oil and chemical industries, where corrosion inhibitors are used to protect the internal cavities of pipes transporting gas. The goal is to increase the efficiency of the device by preventing intensive precipitation of droplets. injecting an inhibitor; and ensuring the re-crushing of large droplets. For this, the device for injecting the dispersed inhibitor into the gas pipeline is equipped with at least one additional nozzle placed symmetrically with respect to the axis of the gas pipeline. The main and additional nozzles are fitted with nozzle holes to meet the flow direction. The inclination of the nozzles to the axis of the gas pipeline ensures the movement of torches along the line connecting the nozzles, which predetermines the shortest path and, consequently, the maximum velocity of the collision of large drops from the opposite nozzles. 1 il. sl C

Description

The invention relates to the protection of metals against corrosion and can be used in gas pipelines, as well as in the gas, oil, and chemical industries, where corrosion inhibitors are used to protect the internal cavities of gas transporting pipes.

The purpose of the invention is to increase the efficiency of the device by preventing the intensive deposition of droplets of the injected inhibitor and ensuring the re-crushing of large droplets.

The drawing shows the device, the overall appearance.

The device for introducing the dispersed corrosion inhibitor into the gas pipeline 1 comprises a system 2 supplying the inhibitor from

tank 3 and the nozzle 4 connected to it, located in the near-wall region of the pipeline 1 obliquely to its axis.

In addition, the device is equipped with at least one additional nozzle 5 placed symmetrically with the main nozzle 4 with respect to the axis of the gas pipeline 1, while the main and additional nozzles 4 and 5 are installed with nozzle holes 6 and 7 in opposition to the flow.

The angle a of each nozzle 4 and 5 to the axis of the pipeline 1 is determined from the ratio

Vn.

and arccos

V

00 CO 00

"Ha

where Vn is the flow rate in the pipeline 1;

UV — average velocity of the sputtering gas when injected into a stationary medium;

Vpea is the resulting speed.

The number of additional nozzles 5 can be set, based on the length of the pipeline 1 and the required flow rate of the inhibitor, and they should be arranged in pairs diametrically symmetric about the axis of the pipeline 1.

The inhibitor supply system 2 comprises a source 8 of compressed gas, a pressure reducing device 9 and pipelines 10 and 11 for gas and an inhibitor.

The device works as follows.

To supply the inhibitor from tank 3 to nozzles 4 and 5, a reducing device 9 is opened, gas from source 8 is fed to tank 3, from where an inhibitor is fed to pipe nozzles 4 and 5, and 10-atomizing gas is fed through pipe 11. At the meeting of the sawing gas and the inhibitor in the nozzles 4 and 6, the latter is split into droplets, which move together with the spreading gas with a high crust. When meeting in the center of the gas wires 1 two gas-liquid flows formed by the nozzles 4 and 5, there is a sharp braking of their gas phases. At the same time, the brake and the small drops quickly brake, and the largest drops by inertia fly farther and fall into the gas flow moving towards them opposite the nozzle, where they are repeated crushing and braking. The small drops of the inhibitor, located in the central part of the pipeline 1, are carried away by the main gas flow and are gradually deposited on the surface of the pipeline 1, protecting it from corrosion. Intensive deposition of droplets on the wall of the pipeline 1

it does not occur near the nozzle 4 and 5. The inclination of the nozzles 4 and 5 to the axis of the pipeline 1 ensures the movement of torches along the line connecting the nozzles 4 and 5, which

determines the shortest path and, consequently, the maximum speed of the collision of large drops from the opposite nozzles 4 and 5.

The arrangement of nozzles 4 and 5 perpendicular to the axis or inclined in the direction of gas movement removes the point of impact of the flares from the nozzle holes 6 and 7, which reduces their speed and the possibility of crushing the droplets.

Optimality of the claimed ratio of the angle of installation of the nozzles 4 and 5 aVn

 arccos tu- determined theoretical uh

from the condition of the smallest resultant path of advancement of the inhibitor particles in the stream before meeting the torch from the opposite nozzle 4 or 5.

Claims (1)

Invention Formula A device for injecting a dispersed corrosion inhibitor into a gas pipeline containing an inhibitor supply system from a reservoir and a nozzle connected to it, located in the near-wall region of the gas pipeline inclined to its axis, characterized in that, in order to increase the efficiency of the device operation by preventing intensive precipitation droplets of the injected inhibitor and ensuring the re-crushing of large droplets; it is equipped with at least one additional nozzle placed symmetrically with the main axis the gas pipeline, while the main and additional nozzles are installed by nozzle openings against the flow. F Yu