RU2003788C1 - Automatic pressure pulser - Google Patents

Abstract

FIELD OF THE INVENTION This invention relates to oil industry equipment used to treat a bottomhole formation zone to increase well production. In order to increase the processing efficiency in an automatic mode by creating alternating pressure drops, the pulsator is provided with rigidly connected upper and lower housing bushings with longitudinal channels fixed in its cavity to the housing. A piston spring-loaded relative to it is installed in the cavity of the upper housing sleeve with a rod having in its lower part a number of annular conical grooves and forming an air chamber with the upper housing sleeve. A locking sleeve with a groove is mounted on the rod. Balls are placed in the grooves of the rod and the sleeve. A ball shutter is located in the lower housing sleeve with the possibility of interacting with the locking sleeve and the annular piston. The pulsator is also equipped with a floating piston with a radial channel forming a cavity with the lower housing sleeve communicating in the lowermost position of the annular piston through the radial channels of the lower housing sleeve and ring pistons with radial housing channels, and in the extreme upper position of the floating piston with radial channels of the blind sleeve . The annular piston is spring loaded relative to the upper housing sleeve and is located between the lower housing sleeve and the cop. - by a pus. and its lower end forms an annular chamber with the latter. The deaf sleeve has additional radial channels and an axial peripheral channel blocked by a non-return valve. The floating piston is mounted for joint movement with the deaf sleeve and communicates in the extreme position of the last cavity of the pipe string under the pulsator through the additional radial channel of the deaf sleeve and the axial peripheral channel of the lower body sleeve with an annular chamber under the lower end of the annular piston 5 il. 3 s

Description

The invention relates to devices in the oil industry, and in particular to treatment of a bottomhole formation zone to increase well production.

Various types of known pressure pulsers are controlled from the surface by rotating a tool for pumping fluid under pressure.

Known pressure pulsator (ed. St. USSR No. 1456540, class E 21 B 43/25), adopted for the prototype, containing a cylindrical housing with radial channels, upper and lower adapters installed in the housing, a bearing and a sleeve made with annular grooves on the outer and inner surfaces hydraulically connected to each other by radial channels, a hollow rod mounted with a gap relative to the body with periodically communicating radial holes, and a mechanism for converting the rotational movement of the rod into return tno-translational movement of the sleeve. With continuous rotation of the pipe string, this pulsator provides cycles of stimulating the formation alternately with depression and repression with the largest amplitude of pressure fluctuation at the bottom without removing the packer from its place and reinstalling it.

A drawback of the downhole pulsator is that. that in order to create cycles of stimulating the formation alternately with depression and repression with the largest amplitude of pressure fluctuation at the bottom, continuous rotation of the pipe string is required, i.e. continuous controlled manipulations by the operator of the pipe string from the surface are necessary. In deviated and deviated wells, continuous rotation of the pipe string leads, as a rule, to impaired tightness of threaded joints, intensive wear of pipes and production casing, which is the cause of poor-quality or unsuccessful work and associated with this repeated and additional operations. This implies the need to create an automatic pressure pulsator design that would create alternating pressure drops (repression and depression) at the bottom without operator intervention on the surface.

The aim of the invention is to increase the efficiency of baroblasting of the bottom-hole formation zone in an automatic mode by creating alternating pressure changes with guaranteed volumes of inflow and absorption

For this, an automatic pressure pulsator comprising a housing with radial channels connected to a pipe string and telescopically mounted in a cavity

housing a blind sleeve with radial channels for communicating the cavity of the pipe string above and below the pulsator, an annular piston with radial channels mounted in the housing with the possibility of axial movement and hydraulic communication through its radial channels and radial channels of the blind sleeve with radial channels of the housing associated with the housing installed in its upper cavity

5 c lower case bushings with longitudinal channels placed in the cavity of the upper case sleeve by a piston spring-loaded relative to it with a rod having a number of annular rings in the lower part

0 conical grooves and forming an air chamber with an upper housing sleeve, a locking sleeve mounted on the stem with a groove placed in the grooves of the stem and locking sleeve by balls, a ball valve located in the lower housing sleeve with the possibility of interaction with the locking sleeve and an annular piston, a floating piston with a radial channel forming a cavity with the lower housing sleeve communicating in the lowermost position of the annular piston through the radial channels of the lower housing sleeve and the annular piston With radial channels of the housing, and in the extreme 5th upper position of the floating piston - with radial channels of the blind sleeve, the annular1 piston is spring-loaded relative to the upper housing sleeve and is located between the lower housing sleeve and

0-housing, and its lower end forms an annular chamber with the latter, the blind plug has additional radial channels and an axial peripheral channel blocked by a check valve, while

5, the floating piston is mounted for joint movement with the blind sleeve and communicates in the extreme upper position of the last cavity of the pipe string under the pulsator through an additional radial channel of the blind sleeve and an axial peripheral channel of the lower housing sleeve with an annular chamber under the lower end of the ring piston.

This kind of automatic

5 pulsator allows you to create depression on the reservoir with a predetermined volume of inflow and repression of the final period of absorption.

Figure 1 shows a general view of an automatic pressure pulsator; in Fig.2 node I in Fig.1; in Fig.3 - section aa in Fig.1; figure 4 is a section bB in figure 1; Fig. 5 is a diagram of an arrangement of equipment for bottom hole treatment.

The automatic pressure pulsator comprises an upper adapter 1, a housing 2, a lower 3 and an upper 4 housing bushings with longitudinal channels mounted in the cavity of the upper housing piston sleeve

5 and the rod 6, cylinder 7, spring 8, which is rigidly connected with it. The rod 6 has in the lower part a number of conical grooves in the ring (Fig. 2) and forms an air chamber with the upper housing sleeve. The piston stroke N corresponds to the level of accumulated fluid in the pipes to which the spring is calibrated 8. For a prototype pulsator, H is 150 mm, which corresponds to 1000 mm of water. Art. A locking sleeve 9 with a groove is installed on the stem 6, balls 10 are placed in the grooves of the stem and the locking sleeve, and the fingers 11 are rigidly connected in the perpendicular plane. In the lower housing sleeve, a ball lock 12 is located that can lock the piston 13 from axial downward movement. The annular piston is spring loaded relative to the upper housing sleeve by a spring 14, is located between the lower housing sleeve and the housing and forms an annular chamber with them. The annular piston has radial channels a and is sealed on the outer surface with the housing, and on the inside with a lower housing sleeve, in which there are radial channels respectively. In addition, the housing sleeve 3 has an axial channel d and forms a floating piston

15 having a radial channel g and a spring

16, the cavity which communicates in the lowermost position of the annular piston 13 through its radial channels a and channels in the housing sleeve with radial channels

6 hulls. In the floating piston, a blind sleeve 17 is installed with an axial channel and radial channels e, g and k with the possibility of their joint movement. In the lower part of the deaf, the sleeve contains a hydraulic brake consisting of a piston 18 and a ball valve 19 in the adapter housing 20.

In FIG. Figure 1 shows the initial position of the pulsator when the under-packer space under the pulsator through the axial channel of the blind sleeve 17 and the radial channel e communicates with the in-tube above the pulsator. The descent into the well is carried out with the valve closed in the tester located below the pulsator (Fig. 5). After reaching the design depth, packing

and open the INLET TEST inlet valve. Fluid enters the pipes. Due to the increasing column of liquid, the piston 5 together with the rod 6 moves down, together with

5, the locking sleeve 9 moves until the annular conical groove coincides with the ball valve 12, which moves into the annular groove of the sleeve and releases the annular piston 13. Under

By the action of the spring 14, it moves down to the stop, in the lowermost position of the channel a and the annular piston is aligned with channels b and c in the housing and the lower housing sleeve, communicating the annular space with the annular chamber. Due to the borehole pressure, the floating piston 15 moves upward, compressing the spring

16 and overlapping the channel e. At the same time, the anal g is moved into the zone of the annular cage and coincides with the lower channel g in the blind sleeve, communicating the annulus with the under-packer. From this moment, the process of pumping fluid from the well into the formation begins. On the blind sleeve 17

5 annular pressure acts from below, and intratubular pressure from above. This pressure drop tends to shift the sleeve upward, but this is prevented by the hydraulic brake 18. Due to the hydraulic resistance in the piston pair, the sleeve 17 is shifted upward over a finite period of time that determines the absorption period. The stroke of the sleeve 17 is less than the stroke of the floating piston 15, so in the extreme

In the upper position of the sleeve 17, channel e remains closed, channel w is shifted relative to channel d in the floating piston, thus annular space is cut off from the sub-packer. At the same time

0, the lower channel k moves to the area under the floating piston 15, where the in-tube pressure is maintained until this moment. Under the action of pressure in the under-packer space through the axial channel

5, the liquid presses on the annular piston 13 from bottom to top, while the channel a in the piston is displaced relative to the channels b and in the housing, the compartment annular space from the annular chamber. Through the lower radial channel in the housing sleeve and the axial channel to the annular chamber communicates with the under-packer space. In the extreme upper position of the annular piston, the axial channel communicates the annular chamber with

5 by the tube space, as a result of which the pressure above and below the floating piston 15 is equalized, under the action of the spring 16 it is shifted down, the channel and in the blind sleeve

17 exits the piston and communicates the tube space with the under-packer. Further

the floating piston moves downward with the blind sleeve 17. Due to the presence of a ball valve 19 in the hydraulic shutter, this movement occurs without changing the resistance.

The control unit operates as follows.

At the end of the stroke of the annular piston 13 upwards, it grabs the finger 11 with its end face. It enters the groove of the upper part of the annular piston and is rigidly mated to the locking sleeve 9, and displaces it by an amount h, while the annular groove in the sleeve and the ball valve also move by h upward relative to the rod 6. Moving the locking sleeve up is possible due to the fact that the annular piston 13 at this point occupies a position in which the annular conical groove on the inner surface of the piston is higher than the ball a new shutter 12. After the final pressure equalization, the annular piston under the action of the spring 14 moves down until the conical surface of the annular groove fits on the ball 12. From this moment, the open period begins. As the fluid flows into the pipes, the piston 5 and rod 6

move downward by a value of h, which is equal to the distance between adjacent conical grooves on the stem (Fig. 2). The stroke rate h corresponds to a certain volume of supply fluid. Together with the rod, the locking sleeve 9 moves downward until the annular conical groove on its outer surface aligns with the ball valve 12, the latter releases the annular piston 13, which is displaced downward by the action of the spring 14. Thus, the cycle repeats.

From the description of the design and operation of the proposed automatic pulsator

the pressure shows that, compared with the prototype, it provides drainage of the formation for the period of inflow of a well-defined volume of fluid and the absorption of the borehole fluid into the reservoir during

finite time interval. Thus, the proposed automatic pressure pulsator meets the conditions for baroblasting the bottom-hole formation zone with finite volumes of recoverable and injected fluids.

(56) USSR Copyright Certificate No. 1456540, cl. E 21 B 43/25, 1989.

Claims (1)

The claims AUTOMATIC PRESSURE PULSATOR comprising a housing with radial channels connected to a pipe string, a blind sleeve with radial channels telescopically mounted in the housing cavity for communicating a pipe string cavity above and below the pulsator, an annular piston with radial channels mounted in the housing with axial movement and hydraulic communication through its radial channels of the radial channels of the blind sleeve with the radial channels of the housing, characterized in that it is provided with an installation rigidly connected to the housing in its cavity, the upper and lower case bushings with longitudinal channels installed in the cavity of the upper case bush, spring-loaded relative to it by a piston with a rod, having in the lower part of the series of annular conical grooves and forming an air chamber mounted on the rod with the shutter sleeve with the upper case bush and a groove and balls placed in the grooves of the stem and the locking sleeve, a ball lock located in the lower housing sleeve with the ability to interact with the locking sleeve and the annular piston, floating piston with a radial channel, 5 forming a cavity with the lower housing sleeve communicating in the lowermost position of the annular piston through the radial channels of the lower housing sleeve and the annular piston with the radial channels of the housing and in the extreme upper position of the floating piston with the radial channels of the blind sleeve, the annular piston is spring loaded relative to the upper housing sleeve and placed between the lower housing sleeve and the housing and its lower end forms an annular chamber with the latter, the blind plug has additional radial channels and axially peripheral channel, covered with a check valve, wherein the floating piston is mounted for joint movement with the hollow sleeve and the message to the uppermost position 5 of the last cavity of the pipe string under the pulsator through an additional radial channel of the blind sleeve and the axial peripheral channel of the lower housing sleeve with an annular chamber under the lower end of the annular piston. 0 5 AND FIG. / Figure 2 Aa FIG. 3 6 B TO Fig 4 Pipes ATste & a / pishcheli ni / sn catr et YaLlemi rif / tt // rra / nejT6 layers Packer figure 5