RU2400615C1 - Device for pulse pumping of liquid to formation - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: device for pulse pumping of liquid to formation includes housing, branch pipe with central channel, which is concentrically located in housing, and equipped with openings and a nut. Branch pipe is rigidly connected from above to reducer. Hollow cylindrical valve is rigidly connected from below to the branch pipe which is inserted in the housing with possibility of tight longitudinal movement. Spring is installed between nut and housing. In housing there is internal cylindrical recess below which there is lower cylindrical recess in the housing equipped with radial channels. In hollow cylindrical valve there are two rows of holes as to height, between which an internal plug is installed. Hollow cylindrical valve is equipped from above with annular projection provided with possibility of tight restricted downward movement relative to internal cylindrical recess of the housing. Cavity of internal cylindrical recess of the housing is interconnected above annular projection by means of openings with central channel, in which there arranged above openings is process constriction made in the form of replaceable sleeve installed inside central channel. Lower cylindrical recess of the housing is provided with possibility of being interconnected with lower row of through holes of hollow cylindrical valve.

EFFECT: increasing operating efficiency of the device.

1 dwg

Description

The invention relates to the oil and gas industry and can be used in the development of oil fields for pulsed injection of fluid into the reservoir.

A device for pumping fluid into the reservoir (patent RU No. 2241825, IPC 8 EV 43/18, published in Bulletin No. 34 of December 10, 2004), comprising a hollow body with a lid, a bottom and outlet channels for communicating the body cavity with the bottomhole zone of the well, a movable working body and the feed channels of the working agent, the device is equipped in the upper part of the body with a movable nozzle with supporting surfaces and an inlet channel in the form of a radial hole for injecting fluid from the bottom of the well into the feed channels of the working agent with a decrease in pickup Azhinov, wherein the outlet channels have reported one of the housing cavities with the cavity under the support surfaces of the nozzle and working fluid supply conduits are in the form of the mixing chamber.

The disadvantages of this device are:

- firstly, the complexity of the design, due to the large number of nodes and parts;

- secondly, the complexity of manufacturing parts, such as a movable body, a movable nozzle leads to an increase in the cost of the device;

- thirdly, the low efficiency of the device, since the amplitude of the oscillations of the pulsed fluid injection is not regulated.

The closest in technical essence downhole pulsator (patent for utility model No. 53363, ЕВВ 43/00, published in Bulletin No. 13 of 05/10/2006), including a housing concentrically placed inside the housing pipe with windows, while the pipe is plugged with a nut and the spring-loaded valve is rigidly connected with the sub, while the nozzle is equipped with an internal cylindrical selection, and the valve is made in the form of a hollow cylinder, muffled from below and equipped with an annular protrusion from above; moreover, the annular protrusion of the valve is located in the inner cylindrical sampling of the nozzle, while the valve is equipped with through holes on the side surface and installed in the nozzle with the possibility of tight axial movement within the inner cylindrical sampling of the nozzle with the possibility of partial mutual overlap of the through holes of the valve and the windows of the nozzle.

The disadvantages of this device are:

- firstly, limited functionality, since pulsed fluid injection occurs only at low pressure and low fluid flow rates, which at high pressure, and especially with an increase in fluid flow, leads to the fact that the spring remains practically in a compressed state, due to why the device goes into a stable (constant) download mode;

- secondly, the low efficiency of the device, since the amplitude and frequency of oscillations are not regulated, that during a long injection process at a low flow rate and low frequency of fluid oscillations, the bottom-hole zone of the injection well is clogged, which reduces its injectivity, therefore, to accelerate the process of self-cleaning the bottom-hole zones it is necessary to increase the flow rate and pressure of the fluid in the pulse device and create a higher frequency and amplitude of the fluid. To increase the depth of formation cleaning, it is necessary to increase the amplitude, and since the hydraulic resistance of the layers is different, depending on their physicochemical properties, it is necessary to adjust the amplitude and frequency of vibrations in order to select the optimal value for the effective operation of the device.

An object of the invention is to increase the efficiency and expand the functionality of the device with a pulse injection of fluid into the reservoir.

The stated technical problem is solved by a device for pulsed fluid injection into a reservoir, including a housing, a nozzle concentrically located in the housing with a central channel, windows and nut, rigidly connected to the sub, a spring, a hollow cylindrical valve equipped with an internal plug and side through holes, and at the top an annular protrusion made with the possibility of limited tight movement down relative to the inner cylindrical sample.

New is that the hollow cylindrical valve is rigidly attached from the bottom to the nozzle, which is inserted into the housing with the possibility of longitudinal tight movement, the nut being installed on the outer surface of the nozzle between the housing and the sub, while the spring is installed between the nut and the housing, the inner cylindrical selection is made in case, below which in the case equipped with radial channels, the lower cylindrical sample is made, and the holes of the hollow cylindrical valve are made in two rows in height, m Between them, an internal plug is installed, and the cavity of the inner cylindrical sample of the housing above the protrusion is connected by windows with a central channel, in which technological narrowing is placed above the windows, and the cavity of the internal cylindrical selection of the protrusion by radial channels with space outside the housing, the lower cylindrical selection of which is made with the possibility of communication with the lower row of through holes of the hollow cylindrical valve, and when moving downward relative to the housing with the upper and lower him rows of through holes of the hollow cylindrical valve at the same time, while the area of the passage section of the narrowing of the Central channel does not exceed the total area of the passage sections of the upper or lower row of through holes.

The drawing shows the proposed device for pulsed injection of fluid into the reservoir in longitudinal section.

A device for pulsed injection of fluid into the reservoir includes a housing 1 concentrically located in the housing 1 pipe 2 with a Central channel 3, provided with windows 4 and a nut 5. The pipe 2 is rigidly connected to the sub 6.

The hollow cylindrical valve 7 is rigidly attached from below to the pipe 2, which is inserted into the housing 1 with the possibility of longitudinal tight movement. The pipe 2 and the hollow cylindrical valve 7 can be made in the form of a single part.

A nut 5 is installed on the outer surface of the pipe 2 between the housing 1 and the sub 6.

A spring 8 is installed between the nut 5 and the housing 1. In the housing 1, an inner cylindrical sample 9 is made, below which, in the housing 1, equipped with radial channels 10, a lower cylindrical sample 11 is made. In the hollow cylindrical valve 7, two rows 12 and 13 are made in height. holes between which an internal plug 14 is installed.

The hollow cylindrical valve 7 on top is equipped with an annular protrusion 15, made with the possibility of limited tight movement down by a length L relative to the inner cylindrical sample 9 of the housing 1. The technological narrowing in the central channel 3 of the pipe 2 is made in the form of a replaceable sleeve 16.

The cavity 17 of the inner cylindrical sample 9 of the housing 1 above the annular protrusion 15 is connected by windows 4 with a central channel 3, in which technological narrowing is made above the windows 4, made in the form of a replaceable sleeve 16 mounted inside the central channel 3, for example, on a thread.

The cavity 18 of the inner cylindrical sample 9 under the annular protrusion 15 of the radial channels 10 is in communication with the space (not shown) of the well behind the device, which eliminates the "pistoning" of the fluid during operation.

The lower cylindrical sample 11 of the housing 1 is configured to communicate with the lower row of through holes 13 of the hollow cylindrical valve 7.

When moving the hollow cylindrical valve 7 downward relative to the housing 1, the lower cylindrical sample 11 of the housing 1 is able to communicate with the upper 12 and lower 13 rows of through holes of the valve at the same time.

A device for pulsed injection of fluid into the reservoir works as follows.

Before the device is lowered into a well (not shown), depending on the injectivity of the formation, the device is adjusted, that is, the optimal mode (oscillation frequency, amplitude) of pulse injection is selected.

In the optimal operating mode of the device, the process of impulse exposure to inhomogeneities of a hydrocarbon deposit has significant boundaries, which positively affects the reduction of residual oil saturation (accelerated closed-cell pore impregnation processes) and, as a result, oil recovery in production wells increases.

The inner diameter D of the replaceable sleeve 16 is selected and the stiffness of the spring 8 is adjusted so that, at a certain flow rate of the liquid and pressure, the required oscillation frequency and pulse amplitude are selected, which are selected during bench tests. Moreover, for the operation of the device in a pulsed fluid injection, the area of the narrowing passage S, made in the form of a replaceable sleeve 16 of the central channel 3, should not exceed the total area S ₁ and S ₂ , respectively, of the passage sections of the upper 12 or lower 13 row of through holes, then there is

where n is the number of through holes in one of the rows;

or

where d _{1 is the} diameter of one through hole of the upper row 12, mm;

d ₂ - the diameter of one through hole of the lower row 13, mm

It should be borne in mind that with an increase in fluid flow, the oscillation frequency of the fluid increases, while the inner diameter D of the replaceable sleeve 16 remains unchanged, and with a constant flow of fluid, changing the inner diameter D of the replaceable sleeve 16, you can choose the optimal oscillation frequency of the fluid depending on the hydraulic formation resistance.

It is possible to increase the amplitude of the oscillations of the pulse action on the formation and, accordingly, the pressure difference by increasing the stiffness of the spring by turning the nut 5 into the nozzle 2. And, conversely, to reduce the amplitude of the oscillations of the pulse effect on the formation and, accordingly, the pressure difference, by reducing the spring stiffness by turning the nut 5 on the nozzle 2.

After adjustment, the device for pulsed injection of fluid into the reservoir by means of an adapter 6 is connected to the tubing string (not shown) (not shown) and lowered into the well.

Then they begin to pump liquid (for example, mineralized water) into the well through the tubing string. The fluid flow under the pressure generated from the wellhead through the central channel 3, the replaceable sleeve 16 and then through the windows 4 of the pipe 2 enters the annular space 17, due to the fact that the bottom row of the through holes 13 of the hollow cylindrical valve 7 is hermetically closed by the body 1.

In the cavity 17, a fluid flow under pressure acts on the upper end of the annular protrusion 15 of the hollow cylindrical valve 7, while the latter begins to shift downward relative to the housing 1, (maximum length L), compressing the spring 8, while the annular protrusion 15 of the hollow cylindrical valve 7 moves down the inner cylindrical sample 9 of the housing 1.

At a certain point, the upper 12 and lower 13 rows of through holes of the hollow cylindrical valve 7 begin to communicate through the lower cylinder sample 11 of the housing 1 and the liquid from the central channel of the hollow cylinder valve 7 through the aforementioned upper 12 and lower 13 rows of through holes through the lower cylindrical sample 11 of the housing 1 flows into the central channel of the hollow cylindrical valve 7 below the inner plug 14, from where it enters the reservoir (not shown). In this case, the pressure in the central channel of the hollow cylindrical valve 7 is higher than the internal plug 14, as well as inside the pipe 2 and in the cavity 17, and the hollow cylindrical valve 7 with the annular protrusion 15 rises under the action of the return force of the spring 8, while the upper 12 and lower 13 the rows of through holes are disconnected, the upper row of through holes being hermetically separated by the housing 1 from the lower row of through holes 13 of the hollow cylindrical valve 7, and opposite the lower cylindrical sample 11 of the building ca 1 (see FIG. drawing), wherein the fluid delivery device and therefore under the reservoir ceases, so there is one cycle pulsed liquid injection into the formation.

Further, at the time of tight separation between the upper 12 and lower 13 rows of through holes of the hollow cylindrical valve 7, the pressure in the central channel of the hollow cylindrical valve 7 is higher than the internal plug 14, as well as inside the pipe 2 and in the annular space 17 again increases and repeats, as described above .

These cycles are repeated many times, as described above, while a uniform fluid flow is converted into a pulsed one.

The proposed device for pulsed fluid injection has wide functional capabilities, since it allows you to adjust the amplitude and frequency of oscillations of the fluid during pulsed injection in a wide range of flow and pressure, which improves the efficiency of the device and select the optimal mode for the range of propagation of oscillations (from the point of view of the phase velocity of the propagation of oscillations and the absorption coefficient) in the rock mass taking into account their natural frequencies (shales, from estnyaki and sandstones).

Claims (1)

A device for pulsed fluid injection into a reservoir, including a housing concentrically located in the housing, a nozzle with a central channel, windows and nut, rigidly connected to a sub, a spring, a hollow cylindrical valve equipped with an internal plug and side through holes, and an annular protrusion made at the top with the possibility of limited tight movement downward relative to the inner cylindrical sample, characterized in that the hollow cylindrical valve is rigidly attached to the bottom of the pipe, which the second one is inserted into the housing with the possibility of longitudinal tight movement, the nut being installed on the outer surface of the pipe between the housing and the sub, the spring being installed between the nut and the housing, the inner cylindrical selection is made in the housing, below which in the housing equipped with radial channels, the lower cylindrical sample, and the holes of the hollow cylindrical valve are made in two rows in height, between which an internal plug is installed, and the cavity of the internal cylindrical Orcs of the casing above the protrusion are connected by windows with a central channel in which technological narrowing is placed above the windows, and the cavity of the inner cylindrical sample below the protrusion is communicated by radial channels with a space outside the casing, the lower cylindrical sample of which is configured to communicate with the lower row of through holes of the hollow cylindrical valve, and when moving downward relative to the housing, with the upper and lower rows of through holes of the hollow cylindrical valve at the same time, the area the passage section of the narrowing of the Central channel does not exceed the total area of the passage sections of the upper or lower row of through holes.