RU2609036C1 - Well sucker-rod pump with double-acting pump - Google Patents

Abstract

FIELD: oil industry.

SUBSTANCE: invention relates to oil producing industry and can be used in operation of flooded wells. Installation includes a piston, a cylinder with a lower pressure valve, a lower inlet with a suction valve and upper inlet openings located above packer and, consequently, above and below piston. Piston is configured for back-and-forth movement. Movement of piston downwards is limited by an inner ledge. There is a pipe string, on which a rod pump is lowered into well. Its outlet through pipe string is communicated with well head, and through lower injection valve - with under-packer space. In upper part of cylinder of rod pump there is a bottomhole-pressure valve configured for back and forth movement. It is rigidly coupled with stem by means of rod pump. Its length is equal to or greater than length of pump stroke. In upper part of cylinder bottom-hole pump there is a retaining valve. It comprises a body with a seat and movable sleeve-valve, placed in cavity of valve body. Pump rod passes through inner cavity of sleeve-valve to seal gap between pump rod and internal cavity of sleeve-valve. Lower part of sleeve-valve tightly interacts with a seat located in lower part of retaining valve body, during stroke of stem with pump rod down. Installation is designed for a well with casing string, two exposed formations and packer located between opened formations.

EFFECT: technical result is improvement of operational reliability, providing higher efficiency of installation during extraction of well product with high gas factor and higher productive capacity due to simplification of pump.

1 cl, 3 dwg

Description

The invention relates to the oil industry and can be used for the operation of highly watered wells in a more economical mode.

A double-acting pumping system is known, comprising a casing with two exposed layers, a pump running on a pipe string located in the casing with the formation of an annulus between them, which is separated by a packer located between the opened layers, the pump being equipped with a plunger, pressure valve and piston connected to the plunger, made with the possibility of reciprocating movement, the upper and lower inlet openings with suction valves located above the packer and with responsibly above and below the piston, wherein the outlet of the pump through the top of the pipe string via a delivery valve communicated with a wellhead, and bottom - through a lower discharge valve with packer space. This embodiment of the installation allows a significant part of the associated water to be pumped into the underlying layer opened by the well without raising it to the surface, thereby reducing the cost of oil (US patent No. 5497832, IPC ЕВВ 43/38, Е21В 43/40 from 03/12/1996).

The disadvantages of the known device is:

- relative design complexity;

- an increase in diametric dimensions due to the protruding upper case of the upper inlet valve.

The closest solution is to install a borehole pump with a double-acting pump, containing a piston, a restrictive bushing, a cylinder with a lower discharge valve, a packer installed between the beds, upper and lower inlets with suction valves located above and below the piston, a plunger with an upper discharge valve made, like a piston, with the possibility of reciprocating motion, while the downward movement of the piston is limited by an internal ledge, a pipe string, on which down into the well rod pump, whose output is communicated through the tubing string from the wellhead and through the bottom discharge valve - with packer space (patent RU №2364708, IPC E21B 43/00, E21B 43/38, from 20.08.2009).

The disadvantages of the known device are:

- significant diametrical dimensions due to the protruding body of the upper inlet valve;

- relative design complexity;

- insufficient operational reliability.

The technical task of this invention is to increase operational reliability, ensure the operability of the installation during the selection of well products with a high gas factor and increase the production capacity of the installation by simplifying the design of the upper part of the pump, and also by using the principle of forced valve actuation.

These goals are achieved by installing a downhole sucker rod pump with a double-acting pump for operating a well with a casing string, two open seams and a packer located between the open seams containing a piston, a cylinder with a lower discharge valve, a lower inlet with a suction valve and upper inlets located above the packer and, accordingly, above and below the piston, the piston with the possibility of reciprocating motion, while the downward movement of the piston is limited internally ledge, a pipe string on which a sucker rod pump is lowered into the well, the outlet of which is connected through the pipe string to the wellhead, and through the lower discharge valve with a sub-packer space, while a suction-discharge valve with a reciprocating-reciprocating valve is placed in the cylinder of the sucker pump a movement rigidly connected to the rod string by means of a pump rod, the length of which is equal to or greater than the stroke length of the pump, and a holding valve containing a housing with a one-piece and relatively movable valve-valve, while the pump stem passes through the internal cavity of the valve-valve with the possibility of sealing the gap between the pump rod and the internal cavity of the valve-valve, and the lower part of the valve-valve tightly interacts with the seat located in the lower part of the valve body holding, during the course of the column of rods with the rod down.

What is new is that both the intake and discharge valve that is movably located in the cylinder pump of the sucker rod and the retaining valve located at the top of the cylinder are forced to open (close and close), which increases operational reliability and at the same time ensures the operability of the unit during well selection high gas factor products.

In FIG. 1 shows a longitudinal section of a double-acting sucker-rod pumping unit; on the left half of the section, the rod string moves down (filling the upper cavity of the cylinder with oil and injecting the separated water into the under-packer space), and the upward stroke (pumping oil to the wellhead and filling the bottom parts of the cylinder of separated water).

In FIG. 2 shows an embodiment of a suction-discharge valve with a stem, and in FIG. 3 is a cross section AA of a sucker rod pump.

The installation comprises a casing string 1 with two exposed layers 2, 3, a pump 4, a pump stem 5, a tubing string 6 located in the casing 1 with the formation of an annulus 7 between them, which is disconnected by the packer 8. The pump 4 is equipped with a suction-discharge valve 9 and a piston 10, arranged for reciprocating movement, a cylinder 11 with a lower inlet 12, a suction valve 13, a discharge valve 14 and upper inlets 15 located above the packer 8 and, respectively, above and below shnya 10. The output of the pump 4 from above through a string of pump pipes 6 is communicated through a retaining valve 16 with a wellhead (not shown), and from below through a pressure valve 14 with a pouch space 17. The holding valve 16 comprises a valve body 18 with a seat 19 fixed in the lower part of the valve body 18 and placed in the internal cavity of the valve body 18 is a limitedly movable glass-valve 20, while the rod of the pump 5 passes through the inner cavity of the glass-valve 20 with the possibility of sealing the gap between the rod of the pump 5 and the inner her cavity of the glass-valve 20, and the lower part of the glass-valve 20 hermetically interacts with the seat during the course of the rod string with the pump rod 5 down.

The piston 10 is located in the cylinder 11 of the pump 4 with the possibility of limited reciprocating motion. From above, the movement of the piston 10 is limited by a movable intake-discharge valve 9, and from below by an internal ledge 18, which does not allow the piston 10 to leave the cylinder 11 cavity.

The installation works as follows.

After descent on the column of pump pipes 6 of the cylinder 11, together with the piston 10, the suction and discharge valves, to a predetermined depth and the installation of the packer 8, between the layers 2, 3, on the rod string (not shown) and the pump rod 5 with a glass mounted on it -valve 20 to the stop of the intake-discharge valve 9 through the piston 10 to the stop 21, after adjusting the length of the rod string, the installation is put into operation.

Highly watered products from the reservoir 2 enter the annulus 7 of the casing 1. Oil 22, which has a lower density, floats upward, and in the lower part of the annulus 7, below the upper inlets 11 and up to the packer 8, there will be separated water 23 like a liquid having a high density.

The installation drive (not shown) informs the rod string (not shown), the pump rod 5 and the associated intake-discharge valve 9 in a reciprocating motion.

With the beginning of the stroke of the rod string up, the intake-pressure valve 9 is forcibly closed, at the same time, the holding valve 16 is forced to open, from this moment a portion of oil 22 is pumped into the cavity of the pumping pipes 6 and then to the wellhead (not shown). Moreover, in the cavity of the cylinder 11 between the intake-discharge valve 9 and the piston 10, the pressure becomes less than the pressure of the liquid in the cavity of the cylinder 17 under the piston 10, which is currently equal to the pressure of the liquid column in the annulus 7, since this pressure acts on the piston 10 bottom through the lower inlet 12 and the open suction valve 13.

Thus, when the intake-discharge valve 9 moves upward, the piston 10 will follow the intake-pressure valve 9 upward, and in this case, water 22 enters the cylinder cavity 11, under the piston 10, through the lower inlet 12 and the suction valve 13 .

The piston 10 rises behind the intake-discharge valve 9 until the cavity between the intake-discharge valve 9 and the piston 10 communicates with the upper inlet openings 11, after which the intake-discharge valve 9 (see Fig. 1) continues to move upwards, and the piston 10 stops, since the pressure above and below it equalizes and becomes equal to the height of the liquid column in the annulus 7. With the further course of the intake-discharge valve 9 upward, the volume of the cavity under the intake-discharge valve 9 increases, and in it Through the upper inlet openings 11 and the open suction valve 13 under the intake-discharge valve 9, oil 22 enters the pressure of the liquid in the annulus 7 until the intake-discharge valve 9 stops in its highest position.

With the beginning of the stroke of the intake-discharge valve 9 downward, the pressure of the liquid in the cylinder 17 above the intake-discharge valve 9, between the intake-discharge valve 9 and the piston 10, as well as under the piston 10, is compared, and with the further progress of the intake-discharge valve 9 down opens discharge valve 15.

Moving down, the open intake-discharge valve 9 reaches the piston 10 and, under the influence of the weight of the rod string, moves it down. At the same time, due to the weight of the rod string under the piston 10, a pressure is created that exceeds the reservoir pressure of the lower layer 3. The discharge valve 15 opens, and the water 22, which flows through the lower inlet 12 to the pump 4, is pumped up during the previous stroke of the rod string, this pressure into the under-packer space 16 and is pressed into the lower layer 3.

Thus, during the operation of the installation, the main amount of water 23 from the reservoir 2 is pumped into the lower layer 3, and oil 22 with a small amount of water is supplied to the day surface.

Then the cycles are repeated.

During the operation of the well, the water cut of the selected products may vary. With a reduction in water cut, the distance by which the intake-discharge valve 9 moves upward relative to the upper inlet openings 11 must be reduced, and the distance by which the lower end of the intake-discharge valve 9 moves downwardly relative to the upper inlet 11, which is achieved by lowering the rod string, must be increased accordingly. way down. As a result, more water 23 will be pumped into the lower reservoir 3 and less oil 22, but with less water cut, will rise to the surface. In this case, the rate of fluid withdrawal from the reservoir 2 will continue.

With a decrease in the wellfare of well production, the rod string must be raised, while the selection of oil 22 will increase, and the amount of water 23 injected into the lower layer 3 will decrease.

Using the proposed installation of a downhole sucker rod pump with a double-acting pump will increase operational reliability by simplifying the design of the installation, as well as increasing the efficiency of production from waterlogged wells due to the ability to control the rate of oil extraction and water injection into the lower reservoir.

Claims (1)

A borehole sucker-rod pumping unit with a double-acting pump for a well with a casing string, two open layers and a packer located between the open layers, containing a piston, a cylinder with a lower pressure valve, a lower inlet with a suction valve and upper inlets located above the packer and, respectively, above and below the piston, the piston with the possibility of reciprocating motion, while the downward movement of the piston is limited by an internal ledge, a pipe string on which to the well Inu, a sucker-rod pump was launched, the outlet of which through a pipe string is connected with the wellhead, and through the lower discharge valve, with a sub-packer space, characterized in that a suction-discharge valve with the possibility of reciprocating movement is rigidly connected to the upper part of the cylinder of the sucker pump a rod string by means of a pump rod, the length of which is equal to or greater than the stroke length of the pump, and a holding valve is placed in the upper part of the cylinder of the rod pump, comprising a housing with a seat and a slide a throat-valve located in the cavity of the valve body, while the pump stem passes through the inner cavity of the valve-valve with the possibility of sealing the gap between the pump rod and the inner cavity of the valve-valve, and the lower part of the valve-valve hermetically interacts with the seat located in the lower parts of the valve body holding, during the course of the rod string with the pump rod down.

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