RU2708430C1 - Operating method for water-flooded gas or gas condensate well - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to oil and gas industry, namely to operation of water-flooded gas or gas condensate wells, and can be used at oil and gas condensate deposits at development of gas and gas condensate deposits at the final stage. According to the method, the well is supplied with the main tubing string and the central tubing string concentrically placed in it with formation of annular space between them, inside the central part of the central tubing string, every 200–250 m from the shoe, dispersers are installed in the form of a ring with a cone-shaped surface, at that height of the disperser ring makes 5–7 mm, width – 10–14 mm, and angle between the ring inner surface of the ring and inner pipe surface is 130–140°, end of central tubing string is placed below end of main tubing string, and gas is extracted simultaneously along central tubing string and annular space. At that, gas-liquid mixture is extracted along the central production string, gas is extracted from it with flow rate equal to one and a half times higher than flow rate required for fluid discharge from the column, and gas flow rate is set in annular space so that it does not exceed the working flow rate. Gas-liquid mixture of the central tubing string is separated on the surface to produce gas and liquid, the liquid is recycled after extraction of valuable components, and condensate is preliminarily extracted from the liquid of gas condensate wells.

EFFECT: effective removal of liquid from well bottomhole by its lifting to day surface and operation of water-flooded gas or gas condensate wells at the final stage of development.

1 cl, 2 dwg, 2 tbl

Description

The invention relates to the oil and gas industry, in particular to the exploitation of flooded gas or gas condensate wells and can be used in oil and gas fields in the development of gas and gas condensate deposits at the final stage.

It is known that during gas withdrawal by more than 80-85%, a significant decrease in reservoir pressure occurs, which gives an impetus to the active manifestation of the water pressure regime, a decrease in production wells, and the rise of a gas-water contact. All this leads to a significant watering of production wells with the formation of liquid plugs in the wellbore.

As reservoir water accumulates in the gas stream and gas is saturated with water, the gas stream extracted from the well becomes heavier, which leads to an increase in the static pressure in the well. At the same time, the gas flow rate decreases, the liquid phase begins to fall out of the system and accumulating at the bottom leads to self-capping of the well. The main way to counteract the loss of liquid from a gas-liquid stream is to maintain the required flow rate above critical values.

In order to eliminate this phenomenon, in addition to maintaining the flow rate, various methods and devices are also used to change the structure of the gas-liquid flow. It is known that the movement of multi-phase multicomponent systems in pipes is inherently much more complicated than the movement of single-phase media. The main difficulty lies in the fact that in the gas-liquid flow there is a relative movement of the phases, due to the difference in their densities and viscosities, as well as surface tension at the phase boundary.

A known method of crushing and mixing gas in a liquid and a device for its implementation, comprising a housing with a set of diaphragms and a nozzle for supplying a gas phase (see Muravyev IM and other Investigation of the movement of multicomponent mixtures in wells. -M .: Nedra, 1972 . - 138 p.).

The disadvantage of this method is poor-quality mixing of the mixture and the presence of large bubbles of free gas in the tubing, which adversely affects their joint movement.

There is a method of changing the structure of a gas-liquid flow using the "Dispersant" device, designed for crushing and mixing gas in a liquid in oil and gas collection systems (see A.S. No. 970039, publ. 30.10.1982)

The disadvantage of this device is the need to work in a horizontal position, as well as separate input of liquid and gas.

A known method of dispersing a liquid into a gas-liquid stream using the device "Dispersant for removal of water accumulations from gas wells" (see RF patent No. 66413, publ. 10.09.2007).

The disadvantages of the method are the possibility of its application only after a sharp decrease in the flow rate of the well, the installation of the device in a liquid below its level and its high gas-dynamic resistance.

Closest to the proposed invention is a method of operating a gas well (see RF patent No. 2513942, publ. 04/20/2014), in which the gas well is provided with a main lift column and a central lift column concentrically placed in it with the formation of an annular space between them. The end face of the central elevator column is placed 1-3 m below the end of the main elevator column, and gas is sampled simultaneously along the central elevator column and the annular space. At the same time, gas is taken from the central elevator column with a flow rate that is one and a half times higher than the flow rate required for liquid removal from the column, and the gas flow rate in the annular space is set such that it does not exceed the value of the working (total) flow rate of the well.

The method provides optimization of the operating mode of gas wells, allowing to operate them without stopping to remove fluid.

The disadvantage of this method is the small amount of liquid raised to the day surface due to its release from the gas-liquid stream and draining along the inner wall of the elevator column, which is associated with the film-dispersion (core) structure of the gas-liquid stream forming, and the impossibility of operating watered and watered wells.

The objective of the invention is to provide a method of operating an irrigated gas or gas condensate well, which provides effective removal of fluid from the bottom of the well by raising it to the surface while maintaining the gas flow rate.

The problem is solved in that in the method of operating an irrigated gas or gas condensate well, the well is supplied with the main lift column and the central lift column concentrically placed in it with the formation of an annular space between them, the end face of the central lift column is located below the end of the main lift column, and gas is taken at the same time along the central lift column and the annular space, while the gas-liquid mixture passes through the central lift column They are discharged through dispersers installed inside the end part of the central elevator column every 200-250 m from the shoe to disperse liquid from the inner surface of the column into a gas-liquid stream, and gas is taken from it with a flow rate that is one and a half times higher than the flow rate required to remove the liquid from it, and the gas flow rate in the annular space is set such a value that it does not exceed the value of the working flow rate. A device in the form of a ring with a conical surface is used as a dispersant, while the height of the dispersant cone is 5-7 mm, the width is 10-14 mm, and the angle between the conical inner surface of the ring and the inner surface of the pipe is 130-140 °. The gas-liquid mixture from the central lift column is separated on the surface to produce gas and liquid, the liquid is disposed of after the extraction of valuable components, and condensate is preliminarily extracted from the gas-condensate well liquid.

The claimed invention is illustrated by the following graphic material. In FIG. 1 schematically shows a section through a gas well equipped with a concentric elevator column with despergators installed in the central elevator column.

The well consists of a production casing 1, a main lift column 2, a central lift column 3 concentrically placed in it with the formation of an annular annular space 4. Dispersants 5 are placed in the central lift column. The lower end of the central lift column 3 is located below the end of the main lift column 2. Well equipped with fountain fittings 6.

In FIG. 2 shows a fragment of a central elevator column with a dispersant, on which:

7 - end pipe elevator columns;

5 - dispersing ring;

a is the width of the dispersing ring;

h is the height of the cone of the dispersant ring;

D is the outer diameter of the dispersing ring;

d is the inner diameter of the dispersing ring.

The principle of operation of the dispersant ring to ensure the return of liquid from the inner surface of the pipe into the total flow of the gas-liquid mixture is based on the use of the phenomenon of hydrodynamic instability of Rayleigh-Taylor (Taylor Gl The instability of liquid surfaces when accelerated in a direction perpendicular to their planes. I. Proc. Roy. Soc., V. A201, p. 192, 1950) and associated turbulent mixing. The Rayleigh-Taylor instability develops at the interface between two media of different densities, moving with acceleration directed from a lighter medium to a heavier one. Gas is lighter than a condensed medium (liquid) and therefore the boundary between the gas and the liquid layer will be unstable if the acceleration is directed from gas to liquid.

When a liquid ring, moving due to interaction with the gas flow along the pipe wall, gets on the conical surface of the dispersant, the angular momentum of the liquid particles is redirected at an angle of 45 ° to the angular momentum of the gas particles. Upon reaching the top of the cone, the fluid flow is broken up by the gas flow ultimately into stable drops, which again reorient their angular momentum, now up in the direction of gas flow. As a result, almost the entire volume of liquid is dispersed in the gas, and in the future, the rise of the liquid is no longer due to friction of the layers of gas and liquid, but due to the resistance force of the medium when particles fall in it according to Newton's law. The latter in terms of lifting fluid is much more effective.

It is known that the boundaries of the existence of film-dispersed and emulsion flow structures depend little on the diameter of the pipes and are mainly determined by the degree of turbulence of the flow and the properties of the coexisting phases. The proposed method contributes to the transition of the film-dispersed structure of the gas-water stream into the emulsion structure of the drip-fog type, because in this case, the liquid is already dispersed in the gas, which leads to an increase in the liquid in the gas-liquid flow.

With an increase in the installation interval of the dispersant of more than 250 m, the amount of liquid in the gas-liquid flow decreases due to its loss from the system. Reducing the installation interval of the dispersant below 200 m leads to an increase in gas-dynamic resistance and a decrease in gas flow rate.

A decrease in the height of the dispersant ring less than 5 mm leads to a decrease in the efficiency of dispersing the liquid into the gas-liquid flow, and with an increase in the height of the ring more than 7 mm the gas-dynamic resistance increases and, accordingly, the gas flow rate decreases.

The width of the dispersant 10-14 mm provides the optimum angle between the conical inner surface of the ring and the inner surface of the pipe and reliable connection with the pipe of the elevator column. When these parameters are changed above or below the limit values, the dispersion of the liquid into the gas-liquid flow decreases and the amount of liquid removed from the well decreases.

With an increase in the angle between the conical part of the dispersant and the inner surface of the pipe more than 140 °, the efficiency of dispersing the liquid into the gas-liquid flow decreases, and when it decreases below 130 °, the gas-dynamic resistance increases, which leads to a decrease in the gas flow rate.

The advantages of the proposed method of operating an irrigated gas or gas condensate well are: providing effective removal of fluid from the bottom of the well by raising it to the surface by using the energy of its own gas flow from the production well while maintaining the gas flow rate and the associated recovery of valuable components from the produced industrial water.

Thus, the hallmark of the proposed method is the transformation of the film-dispersion structure of the gas-liquid stream into an emulsion due to the periodic dispersion of the liquid from the inner surface of the elevator column into the gas-liquid stream using dispersant rings.

The invention is illustrated by a specific embodiment of the inventive method and the accompanying drawings (see Fig. 1 and Fig. 2).

Example

To calculate the main indicators, it is first necessary to determine the gas velocity and flow rate, which ensure the removal of fluid from the bottom of the well by a moving gas stream, according to Turner's formulas [Arbuzov V.N. Operation of oil and gas wells. - Tomsk, Publishing house of the Tomsk Polytechnic University, 2012. - 272 p.].

Taking into account the data on the difference between the minimum and maximum pressures of the depression funnel using the example of the Urengoy area, as well as data not exceeding the depression of 30% of the reservoir, 16.6 atm is used for the calculation of the bottomhole pressure P _s .

The gas flow rate will be:

Gas flow rate for fluid removal:

Possible volumes of liquid extracted in the gas-liquid stream can be estimated by the method of A.P. Krylov [Muravyov V.M. Operation of oil and gas wells. - M., "Nedra", 1973. - 384 p.]

Liquid flow rates and gas flow rate are determined by the following formulas:

where Q _max and Q _{opt the} maximum and optimal flow rate of the liquid, t / day .;

R _max and R _opt - maximum and optimal gas flow, m ³ / t;

d is the inner diameter of the tubing string, mm;

ρ is the density of the liquid, kg / m ³ ;

p ₁ and p ₂ - pressure at the shoe and at the mouth, respectively, Pa;

L is the length of the tubing string, m

The following values are accepted for calculations: L - 1135 m; d - 62 mm; ρ - 1100 kg / m ³ ; p ₁ -1660000 Pa and p ₂ - 850,000 Pa.

The estimated flow rates of the liquid and gas flow are shown in table 1.

The implementation of the proposed method is considered on the example of its implementation for flooded wells of the Urengoy gas condensate field, where the main gas-bearing deposit is located in the Cenomanian deposits (1030-1277 m). The initial production rate of the experimental well is 130 thousand m ³ / day. Formation water contains industrial concentrations of iodine.

The main lift string (2) with a diameter of 168 mm is lowered into the production casing (1) with a diameter of 219 mm of a water-cut gas well. In addition, the central lift column (3) with a diameter of 73 mm is lowered with disperser rings (4) installed inside the end of the pipe (7) every 200-250 m from the shoe and the lower end of the central lift column is placed 2 m below the end of the main lift column . The height of the cone of the dispersing ring (h) is 5-7 mm, the width (a) is 10-14 mm, and the angle between the conical inner surface of the ring and the inner surface of the pipe is 130-140 °. The main and central elevator columns form an annular space (4).

The well is equipped with fountain fittings (6), including the wellhead piping, the first wellhead piping is connected to the annular annular space (MCP), the second - to the pipe space of the central lift column (CLC).

The output of the second wellhead piping from the central heating plant is connected to a separator to separate the liquid.

After connection, the well is mastered and put into operation. Gas sampling is carried out simultaneously along the central lift column and the annular space with gas supply to the gas collection manifold. The removal of fluid from the well takes place along the central lift column by controlling the gas flow rate. For this, gas flow is continuously monitored throughout the well and from annular annular space. At the same time, the gas-liquid mixture velocity in the CLK is maintained above 7 m / s. The gas is taken from the CLK with a flow rate that exceeds one and a half times the minimum flow rate required for the removal of fluid from the bottom of the well (50 thousand m ³ / day). The gas flow rate according to the MCP is set so that it does not exceed the value of the working flow rate (130 thousand m ³ / day). The gas-liquid mixture from CLK is subjected to separation to obtain gas and liquid. The produced fluid is sent for disposal after the recovery of valuable components. If there is gas condensate in the liquid, it is preliminarily separated before the recovery of valuable components.

The results of the studies, taking into account the calculated parameters are shown in table 2.

Thus, the proposed method provides for the production of fluid through the Central lift column in the amount of 15.1-15.8 m ³ / day while maintaining the flow rate of gas. The gas production by the CLK is approximately one third of the total gas production of the well. At the same time, “self-jamming” is prevented and a normal mode of operation of a gas or gas condensate well is ensured.

The implementation of the method for gas condensate wells will allow to obtain gas condensate together with produced water. After condensate is separated, produced industrial water is processed before disposal to produce valuable chemical and rare-metal products, which ensures diversification of well products and additional income.

Claims (1)

A method of operating a flooded gas or gas condensate well, comprising supplying the well with a main elevator column and a central elevator column concentrically placed therein to form an annular space between them, the end of the central elevator column is located below the end of the main elevator column, and gas is taken simultaneously from the central elevator column and annular space, while a gas-liquid mixture is extracted from the central elevator column, gas is taken from it with a flow rate of one and a half times the flow rate required for the removal of fluid from the column, and the gas flow rate in the annular space is set such that it does not exceed the value of the working flow rate, characterized in that the gas-liquid mixture in the central elevator column is passed through dispersers in the form of a ring with a conical surface, the height of the dispersant ring is 5-7 mm, the width is 10-14 mm, and the angle between the conical inner surface of the ring and the inner surface of the pipe is 130-140 °, installed inside the end part the central elevator column every 200-250 m from the shoe, the gas-liquid mixture of the central elevator column is separated on the surface to produce gas and liquid, the liquid is disposed of after the extraction of valuable components, and condensate is preliminarily extracted from the gas-condensate well liquid.

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