RU2229586C1 - Controller valve - Google Patents

Abstract

FIELD: hydrocarbons extraction technology and equipment. SUBSTANCE: device has body with one or several upper and lower admission channels, outer packing elements and fixing means. Inside fixing means, at least one controller means in form of chamber of bellows or piston with a rod and/or closure with respective saddle. Closure is mounted under and/or above the saddle, and/or inside the saddle, and/or between saddles, may be either free or spring-loaded, and/or in rigid connection with the rod of bellows or piston chamber. Chamber is made with or without means for charging with compressed gas, and is placed in the body in upper or lower part, according to direction of its rod either downwards or upwards. Effective diameter of bellow or piston is greater than or equal to contact diameter of closure with the saddle. EFFECT: extended functional capabilities of controller valve, increased effectiveness and reliability during testing and/or operation of one or more layers of one pumping, fountain, gas-lifting or delivery well. 16 cl, 31 dwg

Description

The invention relates to the field of hydrocarbon production (oil, gas, gas condensate) and can be used in the operation and study of one or more disparate formations of one well, in particular, when an open fountain occurs and / or underground repairs are performed without killing the well to cut off the formation (formations) ) from its wellbore, and when killing the well - to exclude the absorption of the solution by the formation (s), in addition, when starting up and complicated operating conditions of the well - to regulate the set value and and the range of the bottomhole pressure (dynamic fluid level), or to stabilize the pressure of the separated fluid flow (gas, oil and water with sand), as well as when studying the supply characteristics (pressure recovery curve - pressure recovery) of the formation for purposefully cutting it off the pipe cavity when a given increase in the dynamic level of the fluid, and with simultaneous and / or alternate injection of the medium into the reservoirs, or the production of fluid from one reservoir and the injection of one well into another reservoir - to control the flow (pressure) of the fluid and / or cutting off the medium flow depending on wellhead pressure.

A device for a pumping well is known (USSR AS No. 1694863, E 21 B 34/06, bulletin No. 44 dated November 30, 91), including a housing with upper and lower passage channels, external sealing elements and a retainer installed in the borehole chamber inside which there is a regulatory body in the form of a chamber of two bellows with a rod, rigidly connected with a shutter under the saddle, and on the case between the bellows there is a chamber for charging the chamber with compressed gas.

Also, a device for a pumping well is known (RF patent No. 2042788, E 21 B 34/06, bulletin No. 24 dated 08/27/95), including a housing with upper and lower passage channels, external sealing elements and a retainer, inside of which there is a regulatory body in the form of a bellows chamber with a rod, rigidly connected with two valves under the saddles, spring-loaded with each other, and the bellows chamber has a node for charging it with compressed gas.

These devices can be used both to control the dynamic level of the fluid, and to cut off the flow of reservoir fluid in the well. However, they cannot be used to control bottom-hole pressure, since the shutter blocks the passage section of the corresponding saddle only with an increase in the dynamic liquid level.

A known valve (RF patent No. 2101466, E 21 B 34/06, 43/00, bulletin No. 1 dated 01/10/98), comprising a housing with through channels, inside of which at least one regulatory body in the form of a camera is placed a piston with a rod and a valve with a corresponding seat, the piston chamber having a unit for charging it with compressed gas. This valve cannot be used to cut off the fluid flow in the well while lowering the fluid level in the pipe cavity.

Known shut-off device (AS No. 1781416, E 21 B 34/06, Bulletin No. 46 dated 12/15/92), comprising a housing installed in the central nipple with upper and lower passage channels, external sealing elements and a latch inside which is located a regulating body in the form of a bellows chamber with a rod, rigidly connected with a shutter under the seat, and the bellows chamber has a unit for charging it with compressed gas to calibrate the shutoff valve to the response pressure. The drawback of the cutter is that it is installed only in the center, because of which there is a likelihood of its release at high pressure drops and / or clogging with mechanical impurities under difficult operating conditions of the well. When the formation is absorbed and / or clogged with sand, it is difficult to remove the cutter from the central nipple using cable technology.

One of the main disadvantages of the known solutions is also that they are not acceptable for simultaneous-separate and / or alternate (periodic) operation of one or more production and / or injection formations of one well, since regulators and cutoffs are installed in the center of the pipe string.

The aim of the invention is to expand the functionality of a well installation with a shutoff regulator, increasing its efficiency and reliability during the study and / or operation of one or several layers of one pumping, flowing, gas lift or injection well.

Efficiency from the use of a unit with a shutoff regulator for a well operated by a pump (for example, ESP, UShGN, etc.) is achieved through: targeted shutting off of the formation (s) from the pipe cavity when the pump stops and the well is repaired without killing; elimination of negative technogenic absorption of saline by the formation (s) of the well, that is, maintaining the filtration inlet characteristics of the formation (s) and reducing the time to bring the well to the process mode when shutting down the well; start-up, operation, research and determination of the parameters of disparate well strata both during simultaneous and separate operation of each of the strata; regulation of the value or range of the bottomhole pressure of the well; changes and stabilization of the dynamic fluid level due to the bypass of a portion of the produced fluid from the cavity of the pipe string into the annulus of the well; elimination of the disruption of the fluid supply by the pump during operation of the main reservoir due to the selection of additional fluid (for example, water) from the auxiliary disconnected lower or upper reservoir, namely, when the dynamic level of the fluid in the wellbore decreases to its dangerous (predetermined) value; regulating pressure and / or cutting off the separated fluid flow (gas, oil and water with sand) in difficult operating conditions; controlling the pressure of associated gas in the annulus, as well as eliminating the possibility (with a high gas factor) of flowing a well through the annulus.

Efficiency from the use of a unit with a shutoff regulator for a gas lift (continuous, periodic, downhole) and fountain (oil, gas, gas condensate) wells is achieved by: eliminating the open fountain and / or performing underground repairs without killing the well by cutting off the formation (s) from its trunk, disconnecting the lift from the packer and extracting the pipe string from the well; elimination of negative-technogenic absorption of the solution by the formation (s) of the well, that is, maintaining the filtration inlet characteristics of the formation (s) and reducing the time to bring the well to the process mode when killing the well; start-up, operation, research and determination of the parameters of disparate well strata both during simultaneous and separate operation of each of the strata; preventing a decrease in bottomhole pressure at the depth of the formation (s) below its permissible minimum value (for example, the saturation pressure of gas in oil) during the launch and operation of the well; regulation of the value or range of variation of flow rate and / or bottomhole pressure in the well; the possibility of rope operations and in-depth studies along the entire length of the pipe string.

Efficiency from the use of a unit with a shutoff regulator for injection and / or producing reservoirs of one well is achieved due to: simultaneous and / or sequential pumping of the medium into several separated layers of one well, adjusting the design flow rate (pressure) for each of them; ensuring injection of the medium into the injection formation, cutting off another producing well formation or, conversely, extracting fluid from one formation, cutting off another injection well formation; ensuring the design production of the medium from one layer and pumping it into another layer of one well.

Efficiency from the use of a unit with a shutoff regulator during well exploration is achieved due to: targeted cutting off of the formation from the cavity of the pipe string (wellbore) for a given increase in the dynamic fluid level during the study of the supply characteristics (HPC) of the formation of a fountain, gas lift or pump well.

The purpose of the invention is achieved by the following solutions:

- the shutter is installed under and / or above the seat, and / or inside the seat, and / or between the seats, freely and / or spring-loaded, and / or is rigidly connected to the stem of the bellows chamber or piston, the latter being made without or with its charging unit compressed gas and is placed in the housing above and / or below, respectively, in the direction of its rod down and / or up, while the effective diameter of the bellows or piston is greater than or equal to the contact diameter of the valve with the seat, in order to expand the functionality of the shutoff regulator, in particular: for downhole regulation pressure during operation, cutting off the flow of formation fluid with an open fountain and / or stopping the well for underground repair without killing it, eliminating the flow of fluid from the wellbore into the reservoir when killing or pressure testing the well, as well as stabilizing the dynamic level of the fluid and eliminating the interruption of the pump fluid when starting and operating a well;

- the bellows or piston chamber without a charging unit can be hermetically isolated or hydraulically connected to the cavity of the housing or the space behind the housing, while a force-controlled spring element is installed in the chamber to control the opening and closing pressure;

- the rod or shutter may be equipped with a rod that is placed in the saddle with the possibility of movement inside it and the formation of an annular cross-section with it, and the area of the latter is less than the cross-sectional area of the upper and / or lower passage channels of the housing, to narrow the flow of medium in the saddle section ;

- two opposite saddles with the same or different bore diameters can be installed in the housing under or above the bellows or piston chamber, and one double-acting shutter is freely or rigidly connected to the bellows or piston chamber stem or mounted freely or spring-loaded or rigidly connected two shutters, with the possibility of tightly closing the passage section of each of the seats, to cut off the flow of formation fluid, both with an increase in the dynamic fluid level to a predetermined value, and with a decrease bottomhole pressure below its minimum allowable value;

- two opposite saddles with the same or different bore diameters can be installed in the housing under or above the bellows or piston chamber, and two shutters are placed between them, one of which is spring-loaded, for regulating bottom-hole pressure and / or eliminating the flow of fluid from the wellbore into the formation when killing or crimping a well;

- the cross-sectional area of the lower saddle may be smaller or larger than the annular cross-sectional area between the saddle and the rod to narrow the medium flow, respectively, in the flow section of the lower or upper saddle, depending on the operating conditions of the well;

- in the housing under or above the bellows or piston chamber, a baffle can be made with an axial through-hole for the diameter of the rod or rod to separate the outer cavity of the bellows or piston chamber; in this case, communicating holes are made hydraulically connected to the outer cavity of the bellows chamber or a piston for installing a shutoff regulator in a conventional well chamber, for example, KT1-73B and KT1-89B, where its position is balanced against pressure;

- in the housing, the saddle above or below the valve can be made with an axial sealing hole for the diameter of the rod or rod and not axial with one or more longitudinal through and transverse holes, the latter being hydraulically connected to the seat cavity on one side and upper or upper on the other through channels of the housing, to balance the position of the regulator-cutoff in a conventional borehole chamber from a differential pressure;

- in the housing, the saddle with an internal shutter can be made with a muffled end and not axial with one or more longitudinal through and transverse openings, the latter being hydraulically connected on one side to the seat cavity and, on the other hand, with upper or upper passage channels of the housing, to exclude the internal sealing element, improving reliability and balancing the position of the regulator-cutoff in a conventional well chamber from a pressure drop;

- an auxiliary bellows can be installed in the housing, rigidly connected at one end to the housing and at the other end to the rod of the bellows chamber, a hermetically insulated cavity being formed between the bellows, the auxiliary bellows being made with a relatively smaller diameter, which is equal to the diameter of the valve in the saddle for it balancing, while on the body are made communicating holes hydraulically connected to the bellows chamber, for the possibility, without charging the bellows chamber with compressed gas, of closing the regulator-compartment To account for the difference in area of bellows with an increase of the dynamic fluid level in the pump well;

- two consecutive regulatory bodies with the same or different technical characteristics (bellows diameter, shutter and seat diameter, shutter stroke, etc.) and / or parameters (charging pressure of the bellows chamber with compressed gas, spring force, shutter opening pressure in saddle, etc.), and the lower shutter is installed above the corresponding saddle to regulate the pressure of the medium flow to itself and to prevent the bottomhole pressure from falling below its predetermined value, and the upper shutter is placed under the corresponding a unit for cutting off the flow of the medium with an increase in the dynamic level of the liquid, while in the case above the lower chamber of the bellows internal passage openings are made;

- two opposing regulatory bodies with the same or different technical characteristics and / or parameters can be installed in the housing, the lower and upper valves being installed above the corresponding seats, respectively, to cut off the medium flow and regulate the pressure to itself;

- in the case, the rod or stem of the bellows or piston chamber can be equipped with an opposing element that provides instant opening and / or closing of the valve in the seat, to exclude pulsation of the valve and to expand the range of opening and closing pressure of the shutoff regulator;

- the valve in the saddle, depending on the operating conditions, can have a spherical seating surface or can be made in the form of a ball or cone, or a hollow piston with passage channels, or a blind piston in the housing;

- upper and / or lower passage channels of the housing, depending on operating conditions, can be made with constant or variable cross-section in the form of cylindrical holes or rectangular or square, or triangular slots;

- external sealing elements on the body can be installed above the lower passage channels for installing the shutoff regulator in the central nipple or above and below the upper passage channels to install it in the borehole chamber.

Figure 1 shows the regulator-cutter with a free shutter above or below the saddle when the closed position in the saddle; figure 2 - regulator-cutter with two opposite saddles and between them a double-acting shutter with its closed position in the lower saddle; figure 3 is the same, only with open sections of the saddles; figure 4 is the same, only when the shutter is closed in the upper saddle; figure 5 - regulator-cutter with two spring-loaded gates between each other when their closed position in the respective saddles; Fig.6 is the same, only with opposite saddles and between them with two rigidly connected valves with the open position of the saddles; Fig.7 is the same, only with a lower spring-loaded shutter in the corresponding saddle; on Fig - cutter with an internal baffle chamber of the bellows; Fig.9 - cutter and its saddle with longitudinal through and transverse holes; figure 10 is the same, only its saddle with a muffled end; 11, 12 and 13 - the regulator-shutter in the execution of the shutter in the form of a ball, a blind piston and a hollow piston with through channels; on Fig - regulator-cutter with two consecutive regulatory bodies; on Fig - the same, with only two opposite regulatory bodies; in Fig.16 - regulator-cutter in the Central nipple; on Fig - regulator-cutter in a conventional well chamber; on Fig - regulator-cutter in the borehole chamber with a supply channel; on Fig, 20 - pumping unit with a regulator-cutter installed in the nipple or borehole chamber under the plug-in pump; in Fig.21, 22 is the same, only installed separately, below the pump, in a nipple or borehole chamber; on Fig - pumping unit with a regulator-cutter for two disconnected formations of one well; on Fig - pumping unit with a regulator-cutter to prevent disruption of the pump in difficult operating conditions of the well; on Fig, 26 - pumping unit with a regulator-cutoff (in two versions) for the operation of wells when removing sand from the reservoir; on Fig - pumping unit with a regulator-cutter to prevent hydrate and paraffin formation in the well; on Fig, 29 - installation with a regulator-cutoff (in two versions) to study the characteristics of the wellbore; on Fig - installation with a regulator-cutter for injection, fountain and gas lift wells with simultaneous and / or alternate operation of several injection and / or producing strata; on Fig is the same, only for a gas well.

The regulator-cutter consists (figure 1-15) of the housing 1 with one or more upper 2 and lower 3 throughput channels of constant or variable cross-section (for example, in the form of cylindrical holes, rectangular, square or triangular slots, etc.), lower outer 4 and / or upper 5 sealing elements (cuffs) and lower or upper retainer 6 (for example, in the form of a collet, a spring ring, a latch, a locking device, etc.). At least one regulating body in the form of a bellows chamber 7 or a piston 8 with a stem 9 and a shutter 10 (for example, in the form of a ball, cone, sphere, blind or hollow piston, etc.) is located inside the seat 11. Inside the chamber 11. Camera 7 of the bellows or piston 8 may have openings 12 with a charging unit 13 (for example, in the form of a slide valve, etc.) for filling it with compressed gas.

The shutter 10 (see Fig. 1) can be installed above or below the seat 11 freely (not rigidly connected to the stem 9) to ensure reliability and tightness of the pair "shutter 10 - seat 11" under dynamic loads of the bellows or piston 8. For low-flow rates wells, the free shutter 10 can additionally be spring-loaded with a spring 14, to ensure reliable closure by the shutter 10 of the passage section of the saddle 11.

The shutter 10 can be rigidly connected with the bellows or piston 8 through the rod 9 and / or the rod 15, but it is possible to violate the tightness of the pair "shutter 10 - seat 11" under dynamic loads and pulsation of fluid pressure in the well. In the housing 1, the rod 15 or the rod 9 can be equipped with a counteracting element 16 to create additional resistance to the movement of the bellows or piston 8 at the time of opening and / or closing the shutter 10 in the seat 11 in order to control a wide pressure range of response of the shutoff regulator.

In the housing 1, two opposite saddles 11 and 17 with the same or different bore diameters can be installed, and between them freely placed (see figure 2) or rigidly connected to the rod 9 of the chamber 7 of the bellows or piston 8 (see figure 3, 4) one double-acting shutter 10 with the possibility of hermetically closing the passage section of each of the seats 11 and 17, to provide the possibility of both controlling bottom-hole pressure by the shutter 10 when the fluid flow passes through the lower saddle 17 (and also to exclude the backflow through it with a free shutter 10 and in the process of crimping and killing the well), and shutting off the shutter 10 of the fluid flow through the upper saddle 11 with an increase in the dynamic level of the fluid.

In the chamber 7 of the bellows or piston 8 without the charging unit 13, a controllable spring element 18 can be installed (see FIG. 4) to control the opening and closing pressure of the shutter 10 in the seat 11 and / or 17 by changing the spring force, while the chamber 7 hermetically isolated or hydraulically connected to the internal or external space of the housing 1.

Also in the housing 1 can be installed between the saddles 11 and 17 freely or spring-loaded with a spring 14 (see figure 5), or rigidly interconnected (see figure 6) two shutters 10 and 19, with the possibility of hermetically closing the passage section of each from the seats 11 and 17, to provide the possibility of both regulating the bottomhole pressure and cutting off the fluid flow through the regulator-shutoff.

In the housing 1, between the saddles 11 and 17, two shutters 10 and 19 can also be placed, but only one of them 19 is spring-loaded with a spring 14, and the other 10 is interconnected via a rod 15 and / or a rod 9 with a bellows or piston 8 of the chamber 7 (see Fig. 7), for the possibility of both regulating the bottomhole pressure and / or eliminating the backflow of fluid during pressure testing and killing the well, and cutting off the fluid flow through the regulator-cutter with increasing dynamic fluid level.

In order to be able to use the shutoff regulator in a conventional borehole chamber (for example, type KT1-73B, KT1-89B without a supply channel from below), a partition 20 with an axial through hole 21 for a diameter of rod 15 or rod 9 can be made in its body 1, for disconnection of the outer cavity 22 of the chamber 7 of the bellows or piston 8, and the housing 1 from the outside has communicating holes 23 hydraulically connected to the outer cavity 22 of the chamber 7 of the bellows or piston 8 (see Fig. 8).

To be able to use the shutoff regulator also in a conventional borehole chamber in its housing 1, the seat 11 can be made with an axial sealing hole 24 for the diameter of the rod 15 or rod 9 and not axial with one or more longitudinal through 25 and transverse 26 holes, the latter with one the sides are hydraulically connected to the cavity of the saddle 11, and on the other hand, the upper or upper passage channels 2 of the housing 1 (see Fig. 9). The saddle 11 can also be hollow with a muffled end 27 and a shutter 10 is installed inside it, which is interconnected with the rod 15 through the upper hole of the saddle 11 (see Fig. 10).

In order to avoid charging the chamber 7 of the bellows 8 with compressed gas and to ensure that the shutoff regulator is also opened from reducing the pressure of the liquid in the well in the housing 1, an auxiliary bellows 28 can be installed rigidly connected at one end to the housing 1, and the other end to the rod 9 of the chamber 7 of the bellows 8, and a hermetically sealed atmospheric cavity 29 is formed between the bellows 8 and 28 (see FIGS. 11, 12 and 13). Moreover, the diameter of the bellows 8 is made larger than the diameter of the auxiliary bellows 28, the latter being equal to the diameter of the shutter 10 in the seat 11 to balance it. Also on the housing 1 are made communicating holes 30, hydraulically connected to the chamber 7 of the bellows 8 through the holes 12.

In order to be able to control a wide range of bottomhole pressures during well operation, an additional regulating body in the form of a bellows chamber 31 or a piston 32 with a rod 33 and / or a rod 34 and a shutter 35 in the seat 36 can be installed in the housing 1 (see Fig. 15), while the chamber 31 has openings 37 with a charging unit 38 for filling it with compressed gas.

In the process of operation, the shutoff regulator can be installed in the central nipple 39 and fixed with a latch 6 in the groove 40 to prevent its ejection during well operation (see Fig. 16). It can also be installed in a pocket 41 of the borehole chamber 42 with passage channels 43 and a lower muffled end 44 without (see FIG. 17) or with a supply channel 45 from below (see FIG. 18). At the same time, the nipple 39 or the borehole chamber 42 with the shutoff regulator descends on the shoe of the pipe string when the elevator is lowered with a lock for the plug-in sucker rod pump 46 (see Figs. 19, 20) or it descends and is installed below the ESP pump, USGGN with a packer (packers) ) 47 and the guide element of the disconnector of the column 48 in the well, having one or more layers (see Fig.21-24).

The controller-cutoff operates in the pumping well (Fig.19-27) as follows.

The bore of the shutoff regulator is closed when the well is launched for pumping operation. The hydrostatic pressure (RT) of the silencing solution in the pipe at the depth of each shutoff regulator (see Figs. 1-10, 14, 15) acting externally on its bellows or piston 8 is greater than the charging pressure (Pc) or spring force 14 (RP) in the chamber 7, due to which the bellows or piston 8 is in the upper extreme position. Moreover, if the shutter 10 is rigidly connected to the bellows or piston 8 or spring-loaded, then the rod 15 rises above the seating surface of the seat 11 and the shutter 10 sits in the saddle 11, and if the shutter is in a free state, then it sits in the saddle 17. If in the housing 1, the chamber 7 does not have a spring 14 and a node for charging with compressed gas (see Figs. 11-13), then the pressure of the fluid in the well acts from the inside on the bellows 8, thereby closing the passage of the saddle 11 from the top with a shutter 10.

After starting the pump 46 into operation, the liquid level in the well decreases and reaches a predetermined value at which the bellows or piston 8 with the rod 15 (under excess pressure of the compressed gas in the chamber 7-Pc) moves the shutter 10 from the seat 11, thereby opening the regulator's passage - a cutoff device for passing the medium from the formation to the well. In this case, the formation medium (Q) enters the cavity of the housing 1 through channels 3 (see Fig. 16, 18) or channels 2 (see Fig. 17).

During operation of the pumping well, the shutoff regulator (see Figs. 1-4, 6, 14, 15) controls the bottomhole pressure, in particular, eliminates the decrease in bottomhole pressure below its permissible value, which is determined from the development design. This process is as follows. When the bottomhole pressure decreases, the bellows (or piston) 8 or 32 with the rod 15 or 34 under excess pressure Pc moves the shutter 10 or 35 to the seat 17 or 36, reducing its cross-section, thereby reducing the flow rate of the medium through the shutoff regulator and, accordingly, bottomhole pressure increases.

If the pump 46 stops working (for example, for repairing a well), the liquid level in the well above the shutoff regulator increases and, accordingly, the fluid pressure acting on the bellows or piston 8 increases. When the fluid pressure reaches its predetermined depth, the shutter 10 moves up (Figs. 1-10, 14, 15) or down (Figs. 11-13) blocking the passage section of the seat 11 and cutting off the flow of formation fluid for underground repair of the well without jamming the solution. Also, when killing the well, the shutter 10 in the seat 17 or 11 performs the function of a check valve to prevent the formation from absorbing the solution.

The regulator-cutter (Fig.1-5, 8-10), passing through a liquid during pump operation, also allows you to stabilize the dynamic fluid level in the annulus of the well due to the additional production of fluid from the lower or upper auxiliary (water) formation (see 23, 24) or pouring part of the produced fluid from the pipe string into the annulus through the shutoff regulator in the borehole chamber 42 above the pump 46 (FIG. 23) while lowering the fluid level below its permissible value.

When operating wells with ESP (or USGN) in difficult conditions under or above the packer (for a single-pack system) or between packers 47 (for a two-pack system), several shutoff controllers 42, 49 and 50 are installed (see Figs. 25, 26). In this case, the flow of formation fluid is divided into flows of gas, oil and water with sand, and they are directed into the cavity of the pipe through the appropriate cutoff regulators 50, 49 and 42, for example, to accumulate sand in the sand collector and / or in the bottom of the well, given that sand settles faster in water than in a water-oil emulsion. If it is necessary to wash the sand, first lift the pump 46 (see Fig. 25) from the well and then lower the auxiliary pipe string with a liner in the form of pipes of smaller diameter inside the cut-off device. Next, liquid (water) is pumped into the cavity of the auxiliary pipe string and the sand is washed. During the washing process, the shutoff regulators 50, 49 and 42 are closed from the fluid pressure, which eliminates the absorption of fluid by the reservoir. In this case, the installation can be equipped with a valve device (which opens when the overpressure in the pipe string increases) or channels 51, for the possibility of crimping the lower (mechanical) packer 47 for tightness (bottom and top), and / or disposal of sand and water in the auxiliary formation , and / or flushing the well. In the presence of a mechanical packer 47 (see Fig. 26), the washing is carried out after its temporary release. To ensure flushing, the non-return valve from inside the ESP pump 46 is excluded and instead of it, a separate removable non-return valve 52 is installed above the pump 46, which is removed from the well by cable technology before flushing and / or disposal. In order to increase the reliability of the pump 46, it is connected to the sub 53 from the inside and a casing 54 is mounted outside it, connected to the shank 55 from the pipe string. The installation with a shutoff regulator (see Figs. 25, 26), in general, is used to operate a pumping well when sand is removed from the formation, to protect and reduce the likelihood of flight of ESP 46, for washing sand in the bottom of the well, and for downhole separation of sand, water, oil and gas, as well as continuous and / or periodic disposal of sand and / or water into the auxiliary formation.

The shut-off regulator in the borehole chamber 42 (see Fig. 27) can be used to prevent hydrate and paraffin formation by reducing the heat loss of the formation fluid in the lift using a heating cable 56 tightly fixed outside the lift, the temperature of which is regulated in a predetermined optimal range with using the control station (when the temperature of the cable and / or fluid flow rises, the station turns off automatically). At the same time, with the help of a shutoff regulator (installed at a depth of, for example, 10-50 m from the wellhead, i.e., above the permafrost zone), the dynamic fluid level in the annulus of the well below the zone of perpetual gas is squeezed and maintained (excluding or controlling the flow of associated gas) permafrost due to the regulation of gas pressure, thereby reducing fluid temperature loss in the lift, since the thermal conductivity of the gas is much less than the thermal conductivity of the liquid.

The shut-off regulator works when examining a well (see Figs. 28, 29) with one or more depth devices 57 (for example, a pressure gauge, flow meter, etc.). At the same time, the pipe string above the packer 47 may be equipped with a borehole chamber 58 with a blind plug or a circulation valve. In the course of well research, in particular, to determine the reservoir pressure drop, the liquid level in the pipe string is reduced (for example, by swabbing or injecting gas through the borehole chamber 58) and open the shutoff regulator 42. After the fluid flows from the formation into the pipe cavity, it closes when predetermined growth of the liquid column, which makes it possible to register the value of the bottomhole pressure in time without interference with the operation of the elevator.

The regulator-cutter with one or two valves (see Fig.1-4) in the form of a ball, sphere or cone 10 above the seat 11 or 17, or in the form of a deaf or hollow piston 10 in the seat 11, can be used for fountain, gas lift or injection well. It can function from bottomhole (P3) and / or pipe pressure (Pt), that is, a bellows or piston 8 with a rod 15 moves upward under excessive pressure, thereby the shutter 10 moves away from the seat 11 or 17, opening its passage section. And when the pressure Pz and / or Pt decreases, on the contrary, the shutter 10 closes the passage section of the seat 11.

The shutoff regulator controls the operation of the formation and cuts off the bottomhole zone in the fountain (oil, gas and gas condensate) or gas lift well (see Fig. 30, 31), in the particular case, when the pressure in the pipe string (PT or Pg) decreases and / or with a pressure drop at the depth of the bottomhole formation zone (Pt or Pz), as well as with an open fountain. In the event of a drop in pressure in the pipe string and / or at the bottomhole zone of the well (for example, for gas lift when gas is supplied through a working valve), the shutoff controller reduces the liquid cross-section (acts as a pressure regulator before and / or after itself), and in in the event of a significant decrease in pressure, it closes completely (acts as a shut-off device).

For an injection well, the medium is injected into the formation through a flow regulator-cutoff in the borehole chamber 42 (see Fig. 30) installed at a depth of the perforation interval. This installation is also used for simultaneous and / or alternate (periodic) operation of one or more producing and / or injection formations of one well. At the same time, for each wellbore, appropriate shutoff regulators (which open at different pressures) in the borehole chambers 42 are selected depending on the design flow rate or pressure, and depending on the injection and / or production conditions, one or some of them can be installed blind plugs and / or shutoff regulators with a regulating body in the form of a saddle 11 (fitting) with a shutter 10 in the borehole chambers 42. The injected medium from the cavity of the pipe string at a given pressure enters the reservoir through the regulator compartment spruce in the borehole chamber 42, and the minimum pressure of injection of the medium into the reservoir can be considered the pressure of its opening. To alternately pump the medium into the reservoirs, the shutoff regulator can be changed to a blank plug, or the injection is carried out at a lower wellhead pressure corresponding to the closing pressure of one shutoff regulator. In addition, the shutoff regulator is used to pump the medium into the injection reservoir when cutting off the production reservoir, or to extract fluid from the production reservoir when cutting off another injection reservoir of one well. This operation is performed by periodically changing the shutoff regulator to a blank plug or vice versa, in the borehole chamber 42 (at the reservoir level), or by using the shutoff regulator for each corresponding formation with the possibility of eliminating the flow of medium into the producing formation when it is pumped into the injection formation , and when producing fluid from the producing formation, on the contrary, exclude its flow into the injection formation of one well.

Claims (16)

1. The regulator-cutter, consisting of a housing with one or more upper and lower passage channels, external sealing elements and a latch, inside of which is placed at least one regulatory body in the form of a bellows chamber or piston with a rod and / or shutter with a corresponding a seat, characterized in that the valve is installed under and / or above the seat and / or inside the seat and / or between the seats, is freely and / or spring loaded, and / or is rigidly connected to the stem of the bellows or piston chamber, the chamber being made without or with charging unit e compressed gas and positioned in the housing top and / or bottom, respectively, in the direction of its stroke in the downward and / or upward, the effective diameter of the bellows or piston is greater than or equal to the contact diameter with the shutter seat. 2. The shut-off controller according to claim 1, characterized in that the bellows or piston chamber without a charging unit can be hermetically isolated or hydraulically connected to the housing cavity or space behind the housing, while a force-controlled spring element is installed in the chamber. 3. The regulator-cutter according to claim 1 or 2, characterized in that the rod or valve is equipped with a rod that is placed in the saddle with the possibility of movement inside it and the formation of an annular cross-section with it, and the area of the latter is less than the cross-sectional area of the upper and / or lower passage channels of the housing, to narrow the flow of medium in the section of the saddle. 4. The regulator-cutter according to one of claims 1 to 3, characterized in that two opposite saddles with the same or different bore diameters are installed in the housing under or above the bellows or piston chamber, and between them it is freely or rigidly connected to the bellows chamber stem or piston, one double-acting shutter is either installed freely or spring-loaded, or two shutters are rigidly connected, with the possibility of hermetically closing the passage section of each of the seats. 5. The shut-off regulator according to one of claims 1 to 3, characterized in that two opposite seats with the same or different bore diameters are installed in the housing under or above the bellows or piston chamber, and two shutters are placed between them, one of which is spring loaded, to exclude reverse fluid flow. 6. The shut-off regulator according to claim 3 or 4, characterized in that the lower saddle cross-sectional area is smaller or larger than the annular cross-sectional area between the saddle and the rod, to narrow the medium flow, respectively, in the flow section of the lower or upper saddle, depending on operating conditions wells. 7. The shut-off regulator according to claim 1 or 2, characterized in that in the housing under or above the bellows or piston chamber a partition is made with an axial through-hole for sealing the diameter of the rod or rod to separate the outer cavity of the bellows or piston chamber, while on the housing communicating holes are made, hydraulically connected to the outer cavity of the bellows or piston chamber. 8. The shut-off regulator according to claim 1 or 2, characterized in that in the housing the seat above or below the valve is made with an axial sealing hole for the diameter of the rod or rod and not axial with one or more longitudinal through and transverse holes, the latter on one side hydraulically connected to the seat cavity, and on the other hand, the upper or upper passage channels of the housing. 9. The regulator-cutter according to claim 1 or 2, characterized in that in the housing the saddle with an internal shutter is made with a closed end and not axial with one or more longitudinal through and transverse openings, the latter being hydraulically connected to the seat cavity on one side, and on the other hand, the upper or upper throughput channels of the housing. 10. The shut-off controller according to claim 1 or 2, characterized in that an auxiliary bellows is installed in the housing, rigidly connected at one end to the housing and at the other end to the rod of the bellows chamber, while a hermetically insulated cavity is formed between the bellows, the auxiliary bellows made relatively with a smaller diameter, which is equal to the diameter of the valve in the seat for balancing, while communicating holes are made on the body, hydraulically connected to the bellows chamber. 11. The shut-off regulator according to claim 1 or 2, characterized in that two consecutive regulating bodies with the same or different technical characteristics and / or parameters are installed in the housing, the lower shutter installed above the corresponding seat to control the pressure of the medium flow to itself and to exclude it lowering the bottomhole pressure below its predetermined value, and the upper shutter is placed under the corresponding seat to cut off the fluid flow with increasing dynamic fluid level, while in the case above the lower bellows chamber or a piston formed inside the passage openings. 12. The shut-off regulator according to claim 1 or 2, characterized in that two opposing regulating bodies with the same or different technical characteristics and / or parameters can be installed in the housing, and the shutters are installed above the corresponding seats to cut off the medium flow and / or pressure regulation up to yourself. 13. The regulator-cutter according to one of claims 1 to 11, characterized in that in the housing the rod or stem of the bellows or piston chamber is equipped with an opposing element. 14. The shut-off regulator according to one of claims 1 to 12, characterized in that the valve in the saddle has a spherical seating surface or is made in the form of a ball, or cone, or a hollow piston with passage channels, or a blind piston in the housing. 15. The regulator-cutter according to one of claims 1 to 13, characterized in that the upper and / or lower passage channels of the housing are made with constant or variable cross-section in the form of cylindrical holes, or rectangular, or square, or triangular slots. 16. The shut-off regulator according to one of claims 1 to 14, characterized in that the outer sealing elements on the body are installed above the lower passage channels for installing the valve in the central nipple or above and below the upper passage channels to install it in the borehole chamber.

Images