SU1665096A1 - Method for operation of pneumatic lift - Google Patents

Abstract

The invention relates to pump engineering and can be used in the design of hydrotransport systems for general industrial purposes. The purpose of the invention is to reduce gas consumption. The liquid is expelled from the replacement chamber 3 without gas breakthrough into the gas lift column 5 by lowering the liquid level to a level above the entrance to the gas lift column 5 and supplying the gas lift column 5 from the upper part of chamber 3. The position of the upper part of chamber 3 relative to the dynamic liquid level in The well is determined by the actual and specified values for the pipe cross-section, the density of the fluid, and the pressure of the injected gas. In this case, the gas-lift column 5 below the gas entry point is blocked for the period of the liquid removal. 2 hp ff, 1 ill.

Description

The invention relates to a pump engineering, in particular, to a gas lift design, and can be used in the design of hydrotransport systems for general industrial purposes.

The purpose of the invention is to reduce gas consumption.

The drawing schematically shows a device for carrying out the proposed method.

In the casing 1 there is an air duct 2 with a replacement chamber 3, in the lower part having a lifting pipe 4, above which a gas-lift column 5 is located. The replacement chamber 3 is connected to the air duct 2 and the gas-lift column 5 with control valves 6-8, with a casing 1 a check valve 9, and the latter is connected to the outlet 10 of the gas-lift column 5 by a check valve 11. A channel 12 in which valve b is installed informs the upper part of chamber 3 with the gas-lift column 5.

The method is carried out as follows.

A well, having a layout of underground equipment and wiring, according to the diagram in the drawing, produces oil with a small gas factor. When gas is supplied through the duct 2 in the annular space between the duct 2 and the gas-lift column 5, a predetermined gas pressure is established. At this time, the liquid level in the annular space between the casing 1, the air duct 2 and the gas-lift column 5 is at the depth shown in the drawing, the valve 6 is closed. Then the valve 6 is opened, and the valve 7 is closed and the gas begins to force the liquid out of the replacement chamber 3 into the column 5 of pipes. In this case, the valve 9 is closed by the pressure increase in the replacement chamber 3, the valves 8 and 11 are open,

After displacing the liquid from chamber 3 and creating a predetermined gas pressure in it, valve 6 is closed and valve 7 is opened, and gas from chamber 3 is passed through channel 12 to the gas lift column 5, carrying the liquid through the gas lift column 5 to exit 10, with sufficient speed increasing the gas pressure under the liquid column. During removal of the plug from the well, the valve 11 is closed by the effect of pressure drop at the outlet 10 and in the casing 1, and the valve 8 is closed by a drive or it is closed by the pressure drop in the lifting pipe 4 and the gas lift column 5 the gas lift column 5 to the wellhead of the gas pressure in the replacement chamber 3, the channel 12 and the gas lift column 5 is reduced due to the expansion of the gas. After reducing the gas pressure to some

the value determined by the position of the replacement chamber 3 relative to the dynamic level, the valve 9 opens, and fluid from the reservoir and the annulus between

air duct 2 and casing 1, the process of gas expansion slows down and slows down its pressure while maintaining the necessary energy costs for lifting a plug of liquid through the gas lift column 5. The noted effect is explained by compensating the loss of energy of the expanding gas by the energy of the reservoir and the operation of the column fluids in the interstitial space between the duct

2 and casing 1.

After the liquid is removed from the well to exit 10 in the replacement chamber 3 and the gas-lift column 5, the gas pressure continues to decrease further and the level increases.

liquids in chamber 3. When the liquid level reaches the upper part of the replacement chamber 3, valve 7 is closed and valve 8 is opened. The liquid begins to flow into the gas lift column 5 to the level of the dynamic level.

During the period of filling of the replacement chamber 3 and the gas-lift column 5 with liquid, the liquid level in the annular space between the air duct and the casing 1 varies. These changes in the annular space level improve the reservoir operation, reducing the maximum depressions to it. The dynamic fluid level is taken as the average of its position during

well work. The gas that is separated from the reservoir fluid is concentrated mainly in the annular space and is discharged from it through the pipe to outlet 10. The method can be implemented in several constructive ways. device options.

Claims (3)

Invention Formula 0 1. The method of operation of a pneumatic liquid lifter by cyclically pushing it out of the replacement chamber through the riser and lifting along the gas lift column due to the supply of gas from the storage chamber, characterized in that, in order to reduce the gas flow, an upstream section of the riser, and the gas from the replacement chamber is supplied after the completion of the displacement cycle. 516650966 2. The method according to claim 1, characterized by 3. It is capable of claims 1 and 2, that is, that the gas-lift column in the lower part is the fact that the liquid is introduced into the upper overlap for the period of gas supply from the ca-part of the chamber, the replacement measures.