RU2612416C1 - Plant for oil production with one pump from different intervals of horizontal wellbore (versions) - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: plant comprises two shanks of different lengths coupled with the pump inlet, wherein one of the shanks is equipped with a side channel having a controlled piston valve connected to a rod with a piston of an actuating cylinder, the inner cavity of which is linked with the surface via a tube to move the piston by overpressure, to compress the recoil spring, and to overlap the side channel by cutting off the fluid produced from the well. Instead of the spring the fluid pressure in the pump outlet can be used to return the piston to the original state, for this the other cylinder cavity may be provided with another tube that communicates with the pump outlet. The shanks are lowered into the borehole in parallel, the short one is equipped with a controlled valve and the long one is provided with an inlet in the remote area of the horizontal wellbore. The long shank can be communicated with the pump inlet through an overflow duct connected with the piston valve body to open in overlapping the side channel of the short shank, an additional shank can be lowered into the well connecting the pump inlet to the middle area of the horizontal wellbore. The piston may be two-spring-biased, one of which is designed pre-compressed to about the middle of the working stroke of the piston.

EFFECT: increased efficiency of oil production with one pump from different intervals of the horizontal wellbore.

7 cl, 7 dwg

Description

The invention relates to the oil and gas industry, in particular to means of operating wells with horizontal shafts, including using thermal methods.

One of the most effective methods for operating highly viscous oil fields is the SAGDI method, which involves the injection of steam into one horizontal well and the extraction of oil from another parallel to it. With a large length of the horizontal part of the boreholes, it is important from the point of view of uniformity of the temperature front and oil recovery that uniform selection of production along its entire length is possible, which can be ensured by selection of well production by one pump from several points of the horizontal wellbore.

A known installation for simultaneous and separate operation of the layers (RF patent No. 2339795, IPC EV 43/14, publ. Bull. No. 33, 11/27/2008), including an electric centrifugal pump (ESP), the motor of which is placed in a casing with shanks connected with different layers connected to the casing using electrovalves controlled by the control station.

The closest in technical essence to the proposed installation is the equipment for simultaneous and separate operation of a multilayer well (RF patent No. 2451164, IPC ЕВВ 43/14, publ. Bull. No. 14, 05/20/2012) containing pipe columns connected to the pump, spool valve controlled by a hydraulic cylinder with a spring-loaded piston.

The disadvantages of the equipment are the complexity of the design and the impossibility of its application for the selection of products from different intervals of the horizontal trunk.

The technical problems solved by the proposed installation are to simplify the design and create opportunities for the operation of several intervals (zones) of the horizontal trunk.

These technical problems are solved by installing one oil pump for oil production from different intervals of the horizontal wellbore, including two shafts of different lengths connected with the pump inlet, one of the shanks being equipped with a side channel with a controllable spool valve connected by a rod to the piston of the power cylinder, whose inner cavity communicated by a tube with a surface for moving the piston with overpressure, compressing the return spring and blocking the side channel with cutting off the produced fluid from the well azhiny.

What is new is that the liners are lowered into the well in parallel, the short one is equipped with a controllable valve, and the long one is provided with an inlet in the remote zone of the horizontal wellbore.

Also new is the fact that the long shank is connected to the pump inlet through a transfer channel connected to the valve body with the possibility of opening a short shank when the side channel is closed.

Also new is the fact that an additional liner has been lowered into the well, communicating the pump inlet with the middle zone of the horizontal wellbore.

Also new is the fact that the piston is spring-loaded with two springs, one of which is pre-compressed to about the middle of the piston stroke.

The indicated technical problems are also solved by the installation for oil production by one pump from different intervals of the horizontal wellbore, including two shafts of different lengths connected with the pump inlet, one of the shanks being equipped with a side channel with a controlled spool valve connected by a rod to the piston of the power cylinder, one of the internal cavities of which are communicated by a tube with a surface for moving with an overpressure of the piston, overlapping the side channel with cutting off the produced fluid from the well, and the other I cylinder cavity is equipped with another tube.

What is new is that the liners are lowered into the well in parallel, the short one is equipped with a controllable valve, and the long one is provided with an inlet in the remote zone of the horizontal wellbore, the second pipe being in communication with the pump outlet.

Also new is the fact that the long shank is connected to the pump inlet through a transfer channel connected to the valve body with the possibility of opening a short shank when the side channel is closed.

Also new is the fact that an additional liner has been lowered into the well, communicating the pump inlet with the middle zone of the horizontal wellbore.

In FIG. 1 shows an installation diagram, FIG. 2 is a variant of the installation scheme with alternate operation of the intervals, in FIG. 3 is a variant of the circuit with an additional shank, in FIG. 4 is a variant of the circuit with an additional spring, in FIG. 5 is a variant of an installation diagram without a spring; FIG. 6 is a variant of the installation diagram without a spring with alternate work of the barrel intervals, in FIG. 7 is a variant of the installation diagram without a spring with an additional shank.

The installation of FIG. 1 contains an ESP 1 with a casing 2, which is closed at the input node 3 with openings 4, communicated by the exit 5 with a column of elevator pipes 6. From the bottom, a long shank 7 connected to it by a hole 8 is connected to it, and a short 9, to which the housing 10 is attached the spool valve with the side channel 11. Inside the body 10 moves the spool 12, connected by a rod 13 to the piston of the actuator 15, supported by a return spring 16. The inner cavity 17 of the actuator 15 is connected by a tube 18 to the surface (not shown).

The inlet 19 of the long shank 7 is located in the remote zone 20 of the horizontal shaft 21 with a perforated production string (EC) 22 in the reservoir 23.

Installation details not mentioned in the description of its operation are not indicated by positions.

The installation of FIG. 2 contains the same basic structural elements as in FIG. 1, but differs in that the long shank 7 is communicated by a transfer duct 24 with an opening 25 in the valve body 10, and the opening 8 is plugged.

The installation of FIG. 3 contains the same basic elements as in FIG. 1 and 2, but differs in that the casing 2 is provided with an additional shank 26 communicated by the inlet 27 with the middle zone 28 of the horizontal barrel 21. The shank 26 is shown in the drawing inside the long shank 7, although it can be made externally parallel to the long shank 7.

The installation of FIG. 4 contains the same basic elements as in FIG. 1 and 2, but differs in that an additional spring 29 is installed inside the power cylinder 15, pre-compressed with the sleeve 30 approximately to the middle of the piston stroke 14.

The installation of FIG. 5 contains the same basic elements as in FIG. 1, but differs in that there is no return spring 16, the stem 13 is sealed with a seal 31, and the other cavity 32 of the actuator 15 located on the other side of the piston 14 is provided with a second tube 33 connected to the output 5 of the pump 1.

The installation of FIG. 6 contains the same basic elements as in FIG. 2, but there is no return spring 16, the rod 13 is sealed with a seal 31, and the other cavity 32 of the power cylinder located on the other side of the piston 14 is provided with a second tube 33 with the output 5 of the pump 1.

The installation of FIG. 7 contains the same basic elements as in FIG. 3, but there is no return spring 16, the rod 13 is sealed with a seal 31, and the other cavity 32 of the power cylinder 15, located on the other side of the piston 14, is equipped with a second tube 33 connected to the output 5 of the pump 1.

In addition, in all variants of the schemes except the remote 20 and middle 28 zones of the horizontal trunk 21, there is a proximal zone 34 of this trunk 21.

In all designs, the spool 10 has travel limiters in the upper and lower positions, not shown in the drawings. The limiters can be placed in the housing 10, the power cylinder, on the casing, etc.

The installation works as follows.

In the absence of pressure in the tube 18 in FIG. 1, the piston 14 under the action of the spring 16 is in the lower position, the spool 10 abuts against the lower limiter. In this case, the side channel 11, in communication with the short shank 9, is open and the fluid coming from the formation 23 through the perforation of the EC 22 from the near zone 34 and the middle 28 of the horizontal barrel 21 moves through the side channel 11, the short shank 9 to the inlet of the pump 1 and is pumped them through the exit 5 and the column of elevator pipes 6 to the surface.

At the same time, the production of the reservoir from the remote zone 20 of the horizontal shaft 21 through the inlet 19, the long shank 7 enters the casing 2, where, mixed with the products from the near 34 and middle 28 zones, it is also pumped to the surface by pump 1.

To equalize the temperature front in thermal wells and to equalize the selection of fluid from the formation 23, fluid or gas is supplied from the surface as necessary under pressure through a tube 18 to the cavity 17 of the power cylinder 15. The piston 14 moves fluid upward through the rod 13 of the spool 12, which, moving in the housing 10, overlaps the side channel 11 and abuts against the upper stop, while the return spring 16 is compressed. At the inlet of the pump 1, liquid enters from a remote 20 and a little from the middle 28 zones of the barrel 21. The installation works in this position until the temperature front of the liquid is aligned, then the pressure in the tube 18 is again reduced. The piston 14 is returned to its original position by the action of the spring 16, lateral the valve 11 opens and again the product from all areas of the barrel 21 enters the inlet of the pump 1.

Thus, they are constantly adjusting the temperature front and fluid withdrawal.

The installation of FIG. 2 works as follows.

In the absence of pressure in the tube 18, the piston 14 is in its lowest position. In this case, the lateral channel 24 and the hole 12 in the housing 10 are blocked by a slide valve 12, which is in its lowest position. At the inlet of the pump 1, fluid comes from the near 34 and a little from the middle 28 zones of the barrel 21.

When liquid or gas is supplied to the tube 18, the piston 14 moves the spool 12 to its highest position. In this case, the lateral channel 11 is closed, and the hole 25 and channel 24 are opened and products from the remote 20 and a little from the middle 28 zones of the horizontal shaft 21 enter the input of the pump 1.

Periodic switching regulate the temperature front and the uniform selection of fluid from the reservoir 23.

The operation of the installation of FIG. 3 is characterized in that through an additional shank 26 and its inlet 27, they continuously withdraw fluid from the middle zone 28 of the horizontal barrel 21 and periodically switch over, as in the diagram of FIG. 2, regulate the selection of the near 34 and remote 20 zones of the horizontal trunk 21.

The operation of the installation of FIG. 4 occurs as follows. In the absence of pressure in the tube 18, the piston 14 is due to the pressure of the spring 16 in its lowest position and the spool 12 abuts against the lower stop. In this position, the hole 25 and the transfer channel 24 are blocked by a slide valve, and the side channel 11 is open. The input of the pump 1 receives products from the near 34 and partially from the middle 28 and remote 20 zones of the barrel 21.

When a liquid or gas is supplied under pressure, for example, 5 MPa, into the tube 18, the piston 14 is moved all the way to the additional spring 29 pre-compressed by the sleeve 30. To further move this pressure, it is not enough and the spool 12 stops in an intermediate position, while it is half closes the hole 25 and the side channel 11. At the inlet of the pump 1, the product comes from the near zone 34, remote 20 and partially from the middle 28. To ensure selection only from the remote zone 20, increase the pressure in the tube 18, for example, to 10 MPa, the piston Hb overcomes the precompression force of the spring 29 and further compressing both springs 16 and 29, the spool 12 translates to the uppermost position up to the stop into the upper stopper. At the same time, the spool 12 overlaps the side channel 11 and the output of the pump 1 receives the products of the formation 23 along the long shank 7 from the remote zone 20.

Thus, this scheme allows you to select products simultaneously from the remote 20 and near 34 zones of the barrel 21 and separately from each of them.

The operation of the installation of FIG. 5 differs from the operation of the installation of FIG. 1 in that in the absence of pressure of the working agent in the tube 18, the piston 14 is pressured by the fluid from the outlet 5 of the pump 1, transmitted through the tube 33 to another cavity 32 of the power cylinder 15, formed by sealing the seal 31 of the rod 13, holds the piston 14 in the lower extreme position with emphasis into the lower limiter. When this side channel 11 is open and the input of the pump 1 enters the products of the reservoir 23 from the near 34 and remote 20 zones of the barrel 21.

To close the channel 11 and transfer to selection from the remote zone 20, a working agent is fed into the tube 18 with a pressure exceeding the pressure at the outlet 5 of the pump 1. To return the spool 12 to the lower position, the pressure in the tube 12 is removed and the piston 14 is pressurized at the outlet 5 pump 1 moves to its lowest position.

The operation of the installation according to the circuit of FIG. 6 occurs in the same way as in the installation according to the circuit of FIG. 2, and the translation of the spool 12 from the lowest to the highest position is carried out, as in the installation of FIG. 5.

The operation of the installation according to the circuit of FIG. 7 is carried out in the same way as in the installation of FIG. 3, just as in the installation according to the circuit of FIG. 2, and the translation of the spool 12 from the lowest to the highest position is carried out, as in the installation of FIG. 5.

Thus, the proposed installation allows the selection of products from the reservoir from two or three zones of the horizontal wellbore, depending on the length of the wellbore and heterogeneity of the formation with the possibility of regulating selections from these zones.

Claims (7)

1. Installation for oil production by one pump from different intervals of the horizontal wellbore, including two shanks of different lengths connected with the pump inlet, one of the shanks being equipped with a side channel with a controlled spool valve connected by a rod to the piston of the power cylinder, the inner cavity of which is connected by a tube with a surface for moving the piston overpressure, compressing the return spring and blocking the side channel with cutting off the produced fluid from the well, characterized in that the liner lowered into the borehole in parallel, the short one has a controllable valve and is provided with a long entrance in a remote area of the horizontal wellbore. 2. Installation for oil production by one pump from different intervals of the horizontal wellbore according to claim 1, characterized in that the long shank is in communication with the pump inlet through a transfer channel connected to the spool valve body with the possibility of opening the short shank when the side channel is closed. 3. Installation for oil production by one pump from different intervals of the horizontal wellbore according to claim 2, characterized in that an additional liner is lowered inside the well, communicating the pump inlet with the middle zone of the horizontal wellbore. 4. Installation for oil production by one pump from different intervals of the horizontal wellbore according to claim 2, characterized in that the piston is spring-loaded with two springs, one of which is pre-compressed to about the middle of the piston stroke. 5. Installation for oil production by one pump from different intervals of the horizontal wellbore, including two shanks of different lengths in communication with the pump inlet, one of the shanks being equipped with a side channel with a controllable spool valve connected by a rod to the piston of the power cylinder, one of whose internal cavities communicated with a tube with a surface for moving the piston with overpressure, blocking the side channel with cutting off the produced fluid from the well, and the other cavity of the cylinder is provided with another tube, tlichayuschayasya in that the shanks lowered into the borehole in parallel, the short one has a controllable valve and is provided with a long entrance in a remote area of the horizontal wellbore, the second tube in communication with the pump outlet. 6. Installation for oil production by one pump from different intervals of the horizontal wellbore according to claim 5, characterized in that the long liner is in communication with the pump inlet through the transfer channel connected to the valve body with the possibility of opening the short liner when the side channel is closed. 7. Installation for oil production by one pump from different intervals of the horizontal wellbore according to claim 6, characterized in that an additional liner is lowered into the well, communicating the pump inlet with the middle zone of the horizontal wellbore.

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