RU2810660C1 - Device for pulsed fluid injection and reservoir development - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention can be used when pumping liquid into a formation and subsequent development of the formation. A device for pulsed injection of liquid and development of a formation includes a housing, a pipe with a central channel, windows and a nut located concentrically in the housing, and a spring. The nut is installed on the outer surface of the pipe in its upper part, and the spring is installed between the nut and the housing, in which an internal cylindrical recess is made. The hollow cylindrical valve below the inner cylindrical part of the housing is equipped with radial windows; below the radial windows the cylindrical valve is equipped with a replaceable sleeve. A blind rod is installed in the replaceable sleeve, which is capable of limited reciprocating axial movements together with the housing relative to the replaceable sleeve with a hollow cylindrical valve. During operation of the device, when the upper part of the blind rod is located opposite the replaceable sleeve, the internal hole of the replaceable sleeve is hermetically sealed and there is no flow of liquid from top to bottom. And when the lower part of the blind rod is located opposite the replaceable bushing, the liquid is passed from top to bottom through the outer cylindrical recess of the blind rod. On top, the housing is equipped with a tube with perforated holes, while inside the tube, opposite the perforated holes, there is a hollow bushing that hermetically covers the perforated holes of the tube and is fixed with a shear screw relative to the tube. The hollow sleeve is equipped with an outer annular groove at the bottom, and at the top with a seat for a ball dropped from the wellhead into the device. The tube at the bottom is equipped with an internal annular protrusion, and above the inner annular protrusion there is an internal cylindrical groove in which a split spring ring is placed, which can be fixed in the outer annular groove of the hollow sleeve.

EFFECT: improved reliability of the device and eliminated pollution of the environment and the area around the wells.

1 cl, 3 dwg

Description

The proposal relates to the oil and gas industry and can be used when injecting liquid (water, acid, solvent) into a reservoir and subsequent development of the reservoir.

A device for pulsed injection of liquid into a formation is known (patent RU No. 2553687, MPK E21B 43/25, published June 20, 2015), including a housing, a pipe with a central channel located concentrically in the housing, a technological restriction located in the central channel of the pipe, made in in the form of a replaceable sleeve. The housing is mounted on a branch pipe on ball bearings, while the branch pipe is equipped with upper and lower rows of radial holes, between which a check valve is placed inside the branch pipe, passing from bottom to top, while the upper and lower rows of radial holes communicate with each other through a bypass channel made between the housing and branch pipe, and in the bypass channel on the inner surface of the housing, blades are tangentially placed, allowing the housing to rotate relative to the branch pipe, partially blocking and changing the flow area of the lower row of radial holes of the branch pipe with a ring equipped with a number of through holes, while the ring is installed outside the branch pipe opposite the lower row of radial holes of the branch pipe and is rigidly fixed to the body, and a replaceable sleeve is installed in the central channel at the lower end of the pipe.

The disadvantages of this device are:

- firstly, there is no possibility of regulating the flow rate of pulsed injection of liquid into the formation;

- secondly, its limited scope of application in terms of liquid consumption. This is due to the fact that pulsed injection of liquid occurs through periodically opening radial holes in the lower row of the pipe, and the diameters of the radial holes of the device are 4-5 mm located in the same row, and also due to the limited diameter of the pipe to 50-60 mm, therefore pulse injection of liquid occurs at low flow rates, usually up to 2 l/s with a low-performance pumping unit,

- thirdly, the device is impossible to operate in inclined and horizontal wells. This is due to the fact that during the operation of the device, the housing rotates relative to the nozzle; therefore, in inclined and horizontal wells, the device body will interact with the internal walls of the well, which will slow down the rotation of the housing relative to the nozzle or even stop the rotation of the housing relative to the nozzle,

- fourthly, the device does not allow the extraction of reaction products by swabbing along a pipe string without lifting the device to the surface, for example, after pulsed injection of acid into the formation,

- fifthly, when the column rises upward, the liquid located in the tubing string will flow out to the wellhead, causing pollution of the surrounding area.

The closest in technical essence and achieved result is a device for pulsed injection of liquid into a formation (patent RU No. 2543241, MPK E21B 43/18, published on February 27, 2015), including a housing, a pipe concentrically located in the housing with a central channel, windows and a nut , a spring, wherein the nut is installed on the outer surface of the nozzle in its upper part, and the spring is installed between the nut and the housing, in which the internal cylindrical recess is made, in the lower part of the internal cylindrical recess of the housing, radial channels are made, and from below to the nozzle inserted into the housing , a hollow cylindrical valve is rigidly attached, equipped with an annular protrusion on top with the possibility of limited sealed movement down relative to the internal cylindrical recess of the body, and the cavity of the internal cylindrical recess of the body above the annular protrusion of the cylindrical valve is connected by windows with the central channel, and the cavity of the internal cylindrical recess under the protrusion is connected by radial channels with space outside the body, a replaceable sleeve and a check valve that passes from bottom to top, that the hollow cylindrical valve below the internal cylindrical opening of the body is equipped with radial windows, below the radial windows the cylindrical valve is equipped with a replaceable sleeve with through windows on top, and a blind rod equipped with on top with a radial through hole into which a pin is installed, inserted into the radial windows of the hollow cylindrical valve and rigidly fixed in the body, while the blind rod has the possibility of limited reciprocating axial movements together with the body relative to the replaceable sleeve with a hollow cylindrical valve with the possibility of cyclic opening and closing the through holes of the replaceable sleeve during the process of pumping liquid into the device.

The disadvantages of this device are:

- firstly, there is no possibility of regulating the flow rate of pulsed injection of liquid into the formation;

- secondly, the low reliability of the structure, due to the fact that during the operation of the device, well fluid containing dirt, sludge, asphaltene-paraffin deposits (APD), etc. flow through the through windows of the replaceable sleeve, while gradual clogging and clogging of the through windows with sludge, dirt, and paraffin occurs, which gradually leads to a decrease in the productivity of the device, reducing the stroke length L and pulse injection. As a result, this leads to the failure of the device to pulse liquid injection into the formation;

- thirdly, limited functionality, since the device does not allow the extraction of reaction products by swabbing along a pipe string without lifting the device to the surface, for example, after pulsed injection of acid into the formation;

- fourthly, pollution of the environment and the area around the well, since when the device is removed (lifting the tubing string up), the liquid in the tubing string will pour out at the wellhead; the residues of an acidic composition, for example, a hydrochloric acid solution after pulse injection, are especially harmful acids into the reservoir.

The technical results of the invention are the development of a device design that makes it possible to increase the reliability of the device by eliminating its contamination during operation of the device with the ability to regulate fluid flow during pulsed injection into the formation, as well as with the possibility of swabbing fluid from the formation after pulsed injection and to eliminate environmental pollution and the area around the well.

The technical result is achieved by a device for pulsed injection of liquid and development of the formation, including a housing, a pipe with a central channel, windows and a nut located concentrically in the body, a spring, wherein the nut is installed on the outer surface of the pipe in its upper part, and the spring is installed between the nut and the body, in which an internal cylindrical recess is made, in the lower part of the internal cylindrical recess of the body, radial channels are made, while at the bottom a hollow cylindrical valve is rigidly connected to the nozzle inserted into the body, equipped with an annular protrusion on top with the possibility of limited sealed movement down relative to the internal cylindrical recess of the body, wherein the cavity of the internal cylindrical recess of the body above the annular protrusion of the cylindrical valve is connected by windows with the central channel, and the cavity of the internal cylindrical recess under the protrusion is connected by radial channels with the space outside the body, while the hollow cylindrical valve below the internal cylindrical recess of the body is equipped with radial windows, below the radial windows is a cylindrical valve the valve is equipped with a replaceable sleeve, and a blind rod is installed in the replaceable sleeve, equipped with a radial through hole on top, into which a pin is installed, inserted into the radial windows of the hollow cylindrical valve and rigidly fixed in the body, while the rod has the possibility of limited reciprocating axial movements together with body relative to a replaceable sleeve with a hollow cylindrical valve.

What is new is that in the upper part of the pipe in the central channel there is a replaceable ring rigidly installed, and in the lower part of the blind rod an external cylindrical recess is made, and at the lower end of the rod is equipped with a limiting protrusion, while during operation of the device when the upper part of the blind rod is located opposite replaceable bushing, the internal hole of the replaceable bushing is hermetically sealed and there is no flow of liquid from top to bottom, and when the lower part of the blind rod is located opposite the replaceable bushing, the liquid flows from top to bottom through the outer cylindrical sample of the blind rod, and on top of the body is equipped with a tube with perforated holes, while inside the tube Opposite the perforated holes, a hollow sleeve is installed, hermetically blocking the perforated holes of the tube, and fixed with a shear screw relative to the tube, and the hollow sleeve is equipped with an outer annular groove at the bottom, and at the top with a landing seat for a ball dropped from the wellhead into the device, while the tube at the bottom is equipped with an internal annular protrusion , and above the inner annular protrusion there is an internal cylindrical groove in which a split spring ring is placed, which can be fixed in the outer annular groove of the hollow sleeve.

In fig. Figure 1 shows a longitudinal section of a device for pulsed injection of liquid and development of the formation in the process of pulsed injection of liquid.

In fig. 2 shows a cross-section A-A of the device.

In fig. Figure 3 shows a longitudinal section of a device for pulsed injection of liquid and development of the formation during development of the formation.

The device for pulsed injection of liquid and development of the formation consists of a housing 1 (see Fig. 1, 2, 3), a pipe 2 concentrically placed in it (Fig. 1, 3) with a central channel 3 equipped with windows 4, a nut 5 and a spring 6. Nut 5 is installed on the outer surface of pipe 2 in its upper part.

The spring 6 is installed between the nut 5 and the housing 1 and rests against the upper end 7 of the housing 1. An internal cylindrical recess 8 is made in the housing 1, and radial channels 9 are made in the lower part of the internal cylindrical recess 8 of the housing 1.

From below, a hollow cylindrical valve 10 (see Figs. 1 and 2, 3), equipped with an annular protrusion 11 (see Figs. 1, 3) on top, made with the possibility of limited sealed downward movement, is rigidly connected to the pipe 2 inserted into the housing 1. relative to the internal cylindrical sample 8 of the housing 1 for a length L relative to the internal cylindrical sample 8 of the housing 1.

The cavity 12 of the internal cylindrical sample 9 of the housing 1 above the annular protrusion 11 is connected by windows 4 with the central channel 3.

The cavity 13 of the internal cylindrical sample 8 under the annular protrusion 11 by radial channels 9 communicates with the space (not shown) of the well behind the device, which eliminates the “pistoning” of the liquid during operation.

The hollow cylindrical valve 10 below the internal cylindrical sample 8 of the housing 1 is equipped with radial windows 14, and below it is equipped with a replaceable sleeve 15 (Fig. 1, 2, 3).

A blind rod 16 is installed in the replaceable sleeve 15, rigidly fixed on top to the body 1 by means of a pin 17 (Fig. 1, 3) inserted into the radial windows 14 of the hollow cylindrical valve 10 and rigidly fixed in the body 1.

In the upper part of the pipe 2 in the central channel 3, a replaceable ring 18 is rigidly installed.

The rod 16 has the possibility of limited reciprocating axial movements together with the body 1 relative to the replaceable sleeve 15 with a hollow cylindrical valve 10.

In the lower part of the blind rod 16 there is an external cylindrical recess 19, and at the lower end of the rod 16 is equipped with a limiting protrusion 20, which limits the upward movement of the blind rod 16 and prevents the blind rod 16 from coming out above the replaceable sleeve 15.

During operation of the device, when the upper part of the blind rod 16 is located opposite the replaceable sleeve 15, the internal hole of the replaceable sleeve 15 is hermetically sealed, so there is no flow of liquid from top to bottom. When the lower part of the blind rod 16 is located opposite the replaceable sleeve 15, the liquid is passed from top to bottom through the outer cylindrical sample 19 of the blind rod 16. Thus, a cyclic (pulse) injection of liquid into the formation occurs.

On top, housing 1 is equipped with a tube 21 with perforated holes 22 with diameters of 5-8 mm. For example, in the tube 21 there are 60 perforated holes with a diameter of 6 mm. Inside the tube 21, opposite the perforated holes 22, there is a hollow sleeve 23 that hermetically covers the perforated holes 22 of the tube 21, and is fixed with a shear screw 24 relative to the tube 21.

The hollow sleeve 23 is equipped at the bottom with an outer annular groove 25, and at the top with a seat 26 for a ball 27 dropped from the wellhead into the device (Fig. 3).

The tube 21 at the bottom is equipped with an internal annular protrusion 28 (Fig. 1, 3), and above the inner annular protrusion 28 there is an internal cylindrical groove 29, which houses a split spring ring 30, which can be fixed in the outer annular groove 25 of a hollow sleeve 23

After pulsed injection of a liquid, for example an acid composition, to increase oil recovery from the bottom-hole zone of a productive formation, in order to swab the formation, the ball 27 is dropped from the wellhead (not shown in Fig. 1, 2 and 3) into the device, then after landing the ball 27 (see Fig. 1 and 2) onto the seat 26 of the hollow bushing 23 using a pump unit, for example a TsA-320 pump unit. (not shown in Fig. 1-3) create excess pressure in the device above the hollow sleeve 23 (see Fig. 1) with the destruction of the shear screw 24 and the downward displacement of the hollow sleeve 23 relative to the tube 21 with the opening of the perforated holes 22 of the tube 21.

Unauthorized fluid flows during operation of the device are prevented by sealing rings.

The device for pulsed injection of liquid and development of the reservoir operates as follows.

Before lowering the device into the well (not shown), depending on the injectivity of the formation, the device is adjusted, that is, the optimal mode (oscillation frequency, amplitude) and fluid flow rate during pulse injection are selected.

To operate the device in the mode of pulsed injection of liquid, depending on the cross-sectional area S of the replaceable ring 18 formed by diameter D (see Fig. 1), the throughput of the outer cylindrical sample 19 of the blind rod 16 is selected.

To create the necessary controlled fluid flow, which is carried out using a replaceable ring 18, the following condition must be met:

where S is the cross-sectional area formed by the diameter D of the replacement ring 18;

∆S = S ₁ – S ₂ - the difference in cross-sectional areas in the upper part of the blind rod 16 and the lower part (along the outer cylindrical sample 19) of the blind rod 16;

S ₁ - cross-sectional area at the top of the blind rod 16

S ₂ – cross-sectional area in the lower part (along the outer

cylindrical sample 19) of a blind rod 16.

Next, the stiffness of the spring 6 is adjusted so that, at a certain fluid flow rate and pressure, the required oscillation frequency and pulse amplitude are created, selected during bench tests.

You can increase the amplitude of oscillations of the pulse effect on the formation and, accordingly, the pressure drop by increasing the stiffness of the spring by screwing nut 6 into pipe 2, and, conversely, you can reduce the amplitude of oscillations of the pulse effect on the formation and, accordingly, the pressure drop by reducing the stiffness of the spring by unscrewing nut 5 on pipe 2.

Thus, depending on the diameter of the replaceable ring 18 and the fulfillment of condition (1) in comparison with the prototype, adjustment of the flow rate of the device for pulsed injection of liquid into the formation is achieved. This allows you to create the necessary fluid flow during pulsed injection into the formation.

After adjustment, the device for pulsed injection of liquid and development of the formation is connected to a tubing string with a packer (not shown) of any known design (for example, a continuous packer with a mechanical axial installation PRO-YaMO (25 MPa) produced by the research and production company "Packer" » Oktyabrsky, Republic of Bashkortostan, Russian Federation).

Next, a tubing string with a packer (not shown) is lowered into the well so that the packer is 5-10 m above the roof of the formation subject to pulse injection of liquid, for example, a 15% hydrochloric acid solution in order to treat the near-wellbore zone of the formation from contamination and increase the permeability of the near-wellbore formation zones.

After running the device on the tubing string at a given interval, the annulus space is sealed, for this purpose a through-hole packer is planted in the well, after which liquid is added to the tubing string, and the upper end of the string is tied to a pumping unit of any known design, for example, with a TsA-320 pumping unit . After which they begin pulsed injection of liquid (for example, as indicated above, 15% aqueous solution of hydrochloric acid for acid treatment of the formation) into the well through the tubing string at a flow rate of 5-6 l/s.

The fluid flow under the influence of pressure created from the wellhead along the tubing string and the central channel 3 from top to bottom through the replaceable ring 18 and then through the windows 4 enters the cavity 12. In the cavity 12, the fluid flow under the action of excess hydraulic pressure acts on the upper end of the annular protrusion 11 of the hollow cylindrical valve 10, while the latter begins to move down relative to the body 1 (maximum length L), compressing the spring 6, while the annular protrusion 11 of the hollow cylindrical valve 10 moves down along the internal cylindrical recess 8 of the body 1. The rigidly fixed with a hollow cylindrical valve 10 replaces a replaceable sleeve 15, and the blind rod 16, due to the fact that it is rigidly connected by means of a pin 17 to the body 1, remains motionless.

For the device to operate in pulse mode, the following conditions must be met:

where L is the stroke length of the annular protrusion 11 of the hollow cylindrical valve 10, m;

a - window length 14, m;

b - length of the outer cylindrical recess 19 of the blind rod 16, m.

The length - a of the windows 14 must be equal to or greater than the length L - the stroke length of the annular protrusion 11 of the hollow cylindrical valve 10, due to which the hollow cylindrical valve 10 can move down the entire length L. The length of the outer cylindrical sample 19 of the blind rod 16 is made as follows so that the restrictive protrusion 20 does not block the flow of liquid from the lower end of the replaceable sleeve 15. For example, to comply with condition 2 when designing the device, the following dimensions are taken:

As soon as the finger 17 rises to the upper end of the radial windows 14 of the hollow cylindrical valve 10, the blind rod 16 with its lower part, i.e., the outer cylindrical recess 19, having a depth in the cross-sectional area (∆S = S ₁ – S ₂ ) is placed opposite the replaceable sleeve 15. As a result, an aqueous acid solution flows from top to bottom through the central channel 3 through the outer cylindrical sample 19 of the blind rod 16 below the replaceable sleeve 15, from where it enters the formation (not shown), while the pressure in the central channel 3 of the hollow cylindrical valve 10 is higher the replaceable sleeve 15, as well as inside the pipe 2 and in the cavity 12, decreases sharply and the hollow cylindrical valve 10 with the annular protrusion 11 and the replaceable sleeve 15 rises under the action of the return force of the spring 6 and the hole in the replaceable sleeve 15 is hermetically sealed from the inside with the upper part of the blind rod 16.

The flow of liquid under the replaceable sleeve 15 and, accordingly, into the formation stops, so one cycle of pulsed injection of liquid into the formation occurs.

Then, at the moment of hermetically sealed closure of the replaceable sleeve 15 with the upper part of the blind rod 16, the excess hydraulic pressure in the central channel 3 of the hollow cylindrical valve 10 above the replaceable sleeve 15, as well as inside the branch pipe 2 and in the cavity 12 of the internal cylindrical sample 9 of the housing 1 above the annular protrusion 11 increases again .

These cycles are repeated many times, as described above, while the uniform flow of liquid is converted into a pulsed one, while the housing 1 moves cyclically relative to the hollow cylindrical valve 10.

The reliability of the design is increased due to the placement of a blind rod of a stepped design in a replaceable bushing and the fulfillment of condition 2. This eliminates the sticking of dirt and paraffin sludge on both the replaceable bushing 15 and the blind rod 16, and also ensures the full stroke length L, therefore During operation, the stroke length does not shorten and pulse injection does not fade.

Upon completion of injection of a given volume of 15% aqueous solution of hydrochloric acid into the productive formation, for example, in a volume of 10 m ³ . Disconnect the CA 320 pumping unit from the tubing string. Maintain a technological pause for 4 hours.

Next, swabbing is performed (selection from the formation of acid reaction products with formation rock in the bottom-hole zone using a swab along the tubing string).

To do this, a ball 27 is dropped along the tubing string from the wellhead into the device (see Fig. 3), which sits on the landing seat 26 of the hollow sleeve 23. At the wellhead, a CA 320 pumping unit is tied to the tubing string and, using the pumping unit, excess pressure in the device above the hollow sleeve 23 with the destruction of the shear screw 24. As a result, the hollow sleeve 23 moves downwards relative to the tube 21 with the opening of the perforated holes 22 of the tube 21. The hollow sleeve 23 with its lower end rests against the inner annular protrusion 28 of the tube 21, a split spring ring 30, located in the inner cylindrical bore 29 of the tube 21, is fixed in the outer annular bore 25 of the hollow sleeve 23.

As a result, the hollow sleeve 23 is stationary relative to the tube 21.

Disconnect the CA 320 pumping unit from the tubing string. A geophysical lift, for example grade PKS 5, is installed at the wellhead, a swab is lowered into the tubing string, and with the help of the swab, the reaction products of the acid with the formation rock in the bottom-hole zone are taken through the perforated holes 22 of the tube 21 along the tubing string at the wellhead into a trough tank (in Fig. 1-3 not shown).

After swabbing is completed, the device is removed from the well.

Thanks to a tube with perforated holes, the proposed device allows swabbing of the formation into which a pulsed injection of liquid (15% aqueous solution of hydrochloric acid) was performed. Swabbing of reaction products is a technological operation that is necessary after pulsed acid injection, therefore the ability to carry out swabbing without additional tripping, unpacking of the packer and removal of the pipe string allows reducing the duration of work.

Also, thanks to the tube with perforated holes, when lifting the device with the tubing string from the well, liquid from the tubing string is overflowed back into the well, which prevents the overflow of liquid from the tubing string to the wellhead and, as a result, pollution of the environment and the area around the well.

The proposal makes it possible to increase the reliability of the device for pulsed liquid injection and reservoir development, provides the ability to regulate liquid flow during pulsed injection into the reservoir, expands functionality, and eliminates environmental pollution.

Claims (1)

A device for pulsed injection of liquid and development of a reservoir, including a housing, a pipe with a central channel, windows and a nut located concentrically in the body, a spring, wherein the nut is installed on the outer surface of the pipe in its upper part, and the spring is installed between the nut and the housing in which it is made internal cylindrical recess, in the lower part of the internal cylindrical recess of the body, radial channels are made, while at the bottom, a hollow cylindrical valve is rigidly connected to the nozzle inserted into the body, equipped with an annular protrusion on top with the possibility of limited sealed movement down relative to the internal cylindrical recess of the body, and the cavity of the inner the cylindrical recess of the body above the annular protrusion of the cylindrical valve is connected by windows with the central channel, and the cavity of the internal cylindrical recess under the protrusion is connected by radial channels with the space outside the body, while the hollow cylindrical valve below the internal cylindrical recess of the body is equipped with radial windows, below the radial windows the cylindrical valve is equipped with a replaceable bushing, and a blind rod is installed in the replaceable bushing, equipped with a radial through hole on top, into which a pin is installed, inserted into the radial windows of the hollow cylindrical valve and rigidly fixed in the body, while the rod has the possibility of limited reciprocating axial movements together with the body relative to the replaceable bushings with a hollow cylindrical valve, characterized in that a replaceable ring is rigidly installed in the upper part of the branch pipe in the central channel, and an external cylindrical recess is made in the lower part of the blind rod, and at the lower end of the rod is equipped with a limiting protrusion, while during operation of the device when positioned in the upper part of the blind rod opposite the replaceable bushing, the internal hole of the replaceable bushing is hermetically sealed and there is no flow of liquid from top to bottom, and when the lower part of the blind rod is located opposite the replaceable bushing, the liquid flows from top to bottom through the outer cylindrical recess of the blind rod, and on top of the body is equipped with a tube with perforated holes , while inside the tube opposite the perforated holes there is a hollow sleeve installed, hermetically blocking the perforated holes of the tube and fixed with a shear screw relative to the tube, and the hollow sleeve is equipped with an outer annular groove at the bottom, and at the top with a landing seat for a ball dropped from the wellhead into the device, with the tube at the bottom is equipped with an inner annular protrusion, and above the inner annular protrusion there is an internal cylindrical groove in which a split spring ring is placed, which can be fixed in the outer annular groove of the hollow sleeve.