UA47953A - Device for well productivity increasing - Google Patents

Abstract

A device for a well productivity increasing contains a case, having a mechanism for the pipes delimitation, a branch pipe with the radial holes, installed in the case with a help of an adapter. In the branch pipe there is a plugged at the bottom end mobile cylindrical extension with the radial holes, which do not coincide with the branch pipe holes in the lover extension position, and coincide with the holes in the upper extension position. To the lower part of the extension a rod is rigidly secured, which is inserted into plug axial hole, installed in the lower part of the branch pipe and containing a sealing unit for the gap between the rod and the axial hole internal surface sealing. For this an internal diameter of the axial hole in the branch pipe is made smaller. And the internal diameter of the plug axial hole in the upper part is made larger so that in the upper extension position a pressure from the lower part be capable to transmit through the plug hole to the lower part of the extension. More to it, above the branch pipe the check valves are installed.

Description

Description of the invention

The invention relates to the oil and gas production industry, in particular to devices for development of wells 2 and increasing the productivity of the formation by cleaning the near-bore zone and drilling the well.

A well-known device for creating an instant depression on the formation, which contains a diaphragm installed in a column of pump-compressor pipes with radial channels, a packer and a circulation sleeve placed between the packer and the diaphragm, which is made with through radial slots, and the area of the axial channel in its upper part is smaller radial channels of pump-compressor pipes (a.s. USSR 977731, 1981).

The disadvantages of this device are that when excess pressure is created in the annular space to rupture the diaphragm, in wells in which the reservoir pressure is lower than the break-out pressure, the absorption of the squelch liquid occurs, which uses water or aqueous solutions, which leads to the hydrophilicization of the filtration channels and the reduction permeability for oil and gas and the introduction of contaminating material into the near-outbreak zone of the reservoir. This factor leads to a decrease in the efficiency of work and, in addition, with a significant absorption of the well fluid by the layer 12, it is impossible to achieve a rupture of the diaphragm.

A known device for creating an instant depression on a layer containing a body with radial holes, a diaphragm placed inside the body and a movable bushing with radial holes and an axial channel in the upper part with a cross-sectional area smaller than the total area of the radial holes of the body and limiters for the movement of the bushing are placed inside the body, and the latter from below is made with a blind end with holes along its circumference, and the limiters are made in the form of stops with axial channels, and the lower stop is installed under the sleeve with the possibility of overlapping holes in the blind end of the sleeve, the total area of which is equal to the area of the axial channels of the stops and the sleeve (patent of Ukraine for the invention Mo 16034, 1997).

When using this device, there is no absorption of the squelch liquid by the formation, which significantly increases the efficiency of work on cleaning the near-outbreak zone. However, it has a significant drawback due to the fact that a high 22 momentary depression of pressure on the formation can be created only once by destroying the membrane that overlaps the internal section of the pipes, although for complete cleaning of the formation zone in many wells, it is necessary to create multiple cycles cycle depressions.

The task of the invention is to create a device for increasing the productivity of wells, which would allow for an increase in the efficiency of cleaning the near-outbreak zone of the formation and the outcrop of the well due to the creation of multiple cycles of pressure depressions. oh

The task is solved by the fact that in the device, which includes a housing, which contains a mechanism for hermetically separating the pipes, the latter consists of a pipe with radial holes installed in the housing with the help of an adapter, located in the pipe of a movable cylindrical sleeve with a number of radial holes, which is blocked from below in the lower position, the bushings do not coincide with the radial holes of the nozzle and coincide with them in the upper position of the bushing, to the lower part of which a rod is rigidly attached, M, which enters the axial hole of the plug, which is installed in the lower part of the nozzle and has a sealing unit for sealing the gap between the rod and the inner surface of the axial hole, and the inner diameter of the axial hole of the nozzle in the upper part is reduced and the formed ledge serves as a limiter for the movement of the bushing, and the inner diameter of the axial hole of the plug in the upper part is increased in such a way that in the upper position of the bushing, the pressure from the bottom of the device passed on through the hole of the plug to the lower part of the sleeve and, in addition, above the nozzle, non-return valves are installed, which pass the liquid from the pipes into the annular space and

From" exclude the return movement. The outer diameter of the nozzle and the diameters of the radial holes in the nozzle and bushing are chosen so that the area of the annular cross-section between the nozzle and the body or pump-compressor pipe is not less than the total area of the radial holes of the nozzle and the total area of the radial holes of the bushing, as well as the cross-sectional area of the internal axial opening of the nozzle in its upper part. The diameter of the rod is determined by the formula:

In z r,

I"e) 4. - Snake" from 0)

Re i-y de; ast - rod diameter; O ut - the outer diameter of the movable sleeve; rv - design pressure from above above the device; p, - design pressure from below under the device;

The scheme of the device is shown in fig.

The device consists of a body 1, which contains a nozzle 2 with radial holes in the middle part,

Which is connected to the body with the help of a translator Z. A pump-compressor pipe can also be used as a body. Inside the spigot 2 with a minimum clearance, there is a cylindrical sleeve 4 plugged from the bottom with radial holes in the lower part, which in the lower position of the sleeve do not coincide with the radial holes of the body and coincide with them in the upper position of the sleeve. The gap between the sleeve and the nozzle is also sealed by sealing rings 5. A rod 6 is rigidly attached to the lower end surface of the sleeve 4, which enters with a minimum tolerance into the axial hole of the plug 7, which is installed in the lower part of the nozzle 2 and has a sealing assembly 8 for sealing the gap between rod and the inner surface of the axial hole. The inner diameter of the axial hole of the nozzle 2 in the upper part is reduced and the formed ledge serves as a limiter for the movement of the sleeve 4, and the inner diameter of the axial hole of the plug 7 in the upper part is increased in such a way that in the upper position of the sleeve 4, the pressure from the bottom of the device is transmitted 65 through the hole of the plug to the lower part of the sleeve. Above the nozzle 2 in the housing 1, non-return valves 9 are installed, which allow the liquid from the pipes into the annular space and exclude the reverse movement. The housing 1 is connected to the pipes 11 with the help of coupling joints 10. The pipes 11, on which the device is installed, go down into the production column 12, which has perforation intervals 13 opposite the productive layer 14. Below the device, a packer 15 can be installed on the pipes, which hermetically demarcates the annular space.

Before carrying out work in the well, in accordance with the planned amount of pressure depression on the reservoir, the depth of descent of the device and the required diameter of the rod 5 are calculated. For example, the productive reservoir is located at a depth of 2000 m, the formation pressure at the depth of descent of the device, for example, 1900Ω, is equal to 20MPa and it is planned to create a reservoir pressure depression 19mMPa. In order for sleeve 4 to be in the lower position and the space above the device and below it to be disconnected, the pressure above the device must be greater than or equal to 7/0 "MPa, which can be created either by compressed gas pressure or weight column of liquid above the device. The internal diameter of the device body corresponds to the internal diameter of the pump-compressor pipes and is equal to, for example, 6.9 -102m, and the diameter of the movable sleeve is 4.4. 1072m.

The diameter of the rod for the specified parameters of this well can be found using the formula (1): -2 I 106 - 4 - 4.410 Lbloye -98-107(m), that is, the diameter of the rod should be 9.8 mm.

The device works as follows.

The pump-compressor (drill) pipes 11, on which the body 1 of the device and the packer 15 are installed, are lowered into the well and installed in the production column 12 as close as possible to the productive layer 14.

Bushing 4 is held by gap seals or other fixing mechanisms in the upper initial position, so the radial holes of nozzle 2 and bushings 4 are aligned and the pump-compressor pipes are filled with well fluid during descent into the production string. Next, with the help of a source of compressed gas (natural oil or high-pressure gas lift gas, a compressor), gas is pumped into the pump-compressor pipes 251. At the same time, at the initial moment of gas injection under the action of excess pressure and high-speed "4, the pressure of the liquid moving through the device, the bushing 4 moves to the lower position, the radial holes of the bushing and the nozzle are displaced, the space above and below the device is separated and the well fluid in the productive layer does not enter, but is pushed into the annular space through the non-return valves. Gas injection continues until it breaks through the non-return valves into the annular space. At this moment, the gas pressure in the pipes reaches its maximum value, that is, for the conditions of this well, 19 MPa. Bushing 4 is in the lower position, the pipes above and below the device are disconnected, the pressure above the device is 19 MPa, and below the device is 20 MPa.

Further, the compressed gas from the pipes is released into the oil and gas collection system and the pressure in the pipes decreases quickly, but they are not filled with Ф liquid, because the non-return valves do not allow water to pass from the annular space, and the sleeve /-|Yich« 4 is in the lower position and also does not pass fluid from the reservoir into the pipes.

З The loads that will act on the movable sleeve from above (E c) and from below due to pressure on the end surface t of the rod (ЕН) are determined, respectively, by the formulas: хи, ве Ryba P (2) « у; - s E-R.D -R "Tv (3) t n p t p 4 i? where Re, P - respectively, the pressure on the sleeve from above and below (in the lower position of the sleeve); Zvt, Zst - Correspondingly, the cross-sectional area of the sleeve and rod; Ot, dst - Correspondingly, the outer diameter of the sleeve and rod. і" When the gas pressure in the pipes decreases, for example, to 5 MPa, a load will act on the sleeve from above: - 5 314-(444107)

E, - 5.10. «« 7, b(t) (Te; 4 sl 50 a from the bottom on the sleeve rod: -

Fk -20406.34-0.8-10 Y uv(t) n 4 3 z and it is obvious that the sleeve will be in the lower position. | only when the gas pressure in the pipes decreases below 1MPa, the load on the sleeve from above will become less than 1.5t, i.e. less than the load on the stem of the sleeve from below, and it will move to the upper position. At this moment, the radial holes of the nozzle and bushing

P" combine and the space under the device with a pressure of 20 MPa will connect with the space in the pipes above the device with a pressure of about 1 MPa and an instantaneous high pressure depression of 19 MPa will be created on the formation. Under the influence of this high pressure depression, the reservoir fluid enters the well at a high speed, carrying with it the products of pollution 60 of the near-welling zone. When the sleeve 4 is moved to the upper position, the rod 6 comes out of the sealing assembly 8 and the pressure under the sleeve no longer acts on the cross-sectional area of the rod, but through the axial hole in the plug on the entire lower surface of the sleeve, that is, the load on the sleeve will be the same on its the upper and lower surfaces, as a result of which it will be in the upper position during the entire time of filling the pipes with reservoir fluid. 65 After the pipes are filled with formation fluid containing formation contamination products, the above-described operations are repeated again: liquid is forced out of the pipes by compressed gas into the annular space, while the movable sleeve moves to the lower position under the influence of the pressure drop, the fluid is displaced in the pipes to the depth of installation of non-return valves, vented gas pressure in the pipes, carry out the next high momentary depression of the pressure on the reservoir and expect the pipes to be filled with reservoir fluid containing reservoir contamination products. After creating several cycles of instantaneous high pressure depressions, reservoir fluid with pollution products from the annular space is pushed to the surface and these cycles are repeated until clean water or oil flows from the annular space.

The stand can be used without the use of a packer. In this case, a high instantaneous depression of pressure will be created on the reservoir, similar to the mechanism described above, but here 7/0 will occur simultaneously with the inflow of reservoir fluid and the fluid will flow at a high speed from the annular space into the pipes, which will create a high-speed pressure in the interval of the productive reservoir and will contribute to its better cleaning. In this technology, in addition to depression, pressure repression will also act on the formation, which will take place when liquid is displaced from the pipes.

The technical result of the invention is that the use of the device allows for multiple creation of high instantaneous pressure depressions, due to which a complete cleaning of the near-outbreak zone /5 of the formation is achieved and the productivity of oil and gas pipeline production and gas injection wells is increased.

Claims (2)

The formula of the invention 1. A device for increasing the productivity of wells, which includes a housing containing a mechanism for hermetically separating pipes, which is characterized by the fact that it additionally contains a nozzle with radial holes installed in the housing with the help of an adapter, a movable cylindrical sleeve with radial holes located in the nozzle and plugged from below, which in the lower position of the sleeve do not coincide with the radial holes of the nozzle and coincide with them in the upper position of the sleeve, to the lower part of which a rod is rigidly attached, which enters the axial hole of the plug, which is installed in the lower part of the nozzle and contains a sealing assembly for sealing the gap between the rod and the inner surface of the axial hole, "at the same time, the inner diameter of the axial hole of the nozzle in the upper part is reduced and the formed ledge serves as a limiter for the movement of the bushing, and the inner diameter of the axial hole of the plug in the upper part is increased so that in the upper position of the bushing, the pressure from below is transmitted through the hole by plugs on the lower part of the bushing, in addition, check valves are installed above the nozzle, which allow liquid from the pipes into the annular space and exclude reverse movement. t) 2. The device for increasing the productivity of wells according to claim 1, which is characterized by the fact that the outer diameter of the nozzle and the diameters of the radial holes in the nozzle and sleeve are selected in such a way that the area of the annular section between the nozzle and the body (or pump-compressor pipe) is not less of the total area of the radial holes of the spigot and the total area of the radial holes of the sleeve, as well as the cross-sectional area of the internal axial opening of the spigot in its upper part. Z. The device for increasing the productivity of wells according to claim 1, which differs in that the diameter of the rod is determined by the formula: " , - 2 UR s 4. - ri xh c st BE "" Rk where: adst - diameter of the rod; О т - outer diameter of the movable sleeve; рв - design pressure from above above the device; р, - design pressure from below under the device. -и se) 1 сю» 60 b5