RU151716U1 - HYDRAULIC GARIPOV REGULATOR - Google Patents

Abstract

1. A hydraulic regulator comprising a hydraulic channel of high pressure, a movable element, sealing elements and a housing made with a chamber, with an inlet made with the possibility of hydraulic communication with the camera, and with overflow openings made with the possibility of hydraulic communication of the annulus with the annulus while sealing elements are located inside the housing, the movable element is located inside the housing with the possibility of overlapping bypass openings d and with the possibility of interacting with the chamber, the high-pressure hydraulic channel is hermetically fixed in the inlet, characterized in that the chamber is at least one buffer chamber, the device is additionally equipped with external chambers with spring functions located in the housing with the possibility of charging it a working agent and with the possibility of compression or decompression, while the external chambers with spring functions are at least one in the form of an enclosed space and at least one in the form of e open space with the possibility of hydraulic communication with the well fluid, the buffer chamber is located in the housing with the possibility of hydraulic isolation from the bypass holes and from the external chambers, sealing elements are located between the buffer and external chambers and between the buffer chamber and the bypass hole or holes, several movable elements, arranged with the possibility of tight reciprocating movement, while each movable element is made with different sizes

Description

The utility model relates to the field of hydrocarbon production, namely, oil, gas, condensate, etc. and can be used in the operation of well installations with packers, namely, during the injection of a working agent or production of formation fluid, in oil, gas condensate and gas wells, including those with low well pressure, in wells with small diameters and with simultaneous and separate operation several layers.

Known Regulator containing a hydraulic channel, one or more moving elements, sealing elements, a housing made with one or more chambers, at least one bypass hole and with an inlet opening, while one or more bypass holes are made with the possibility of hydraulic communication annular space with annular, movable element is configured to overlap one or more bypass holes and interacting with the camera, the hydraulic channel hydraulically connected to the inlet (RF Patent No. 2415255, E21B 43/14, 34/06, op. March 27, 2011).

The disadvantage of the above regulator is the restriction in use in wells with reduced pressure, due to the inability to control the pressure of the working agent in the hydraulic channel below the hydrostatic, including when the pressure of the working agent in the inlet is greater than the pressure of the well fluid.

Known hydraulic regulator containing a hydraulic channel, a movable element, sealing elements, a housing made with a camera, at least one bypass hole and an inlet, the sealing elements are located inside the housing, the movable element is located inside the housing with the possibility of overlapping bypass holes and with the possibility of interaction with the camera, the bypass holes are made with the possibility of hydraulic communication of the in-pipe space with the annular, hydraulic the channel is hermetically fixed in the inlet, made with the possibility of hydraulic communication with the camera (RF Patent No. 2474673, E21B 34/10, op. 02/10/2013, prototype)

The disadvantage of the above hydraulic regulator is the restriction of use in wells with small diameters, due to the large overall dimensions of the hydraulic regulator with a two-pipe body, in particular this concerns production casing with 139, 114 and 100 mm dimeters and others. In addition, the movement of the movable element inside the housing is associated with increased wear of the sealing elements due to the large area of interaction of the rubbing surfaces. Premature loss of tightness in deviated and horizontal wells when the hydraulic regulator is located on one side, which contributes to the maximum wear of the sealing elements from the bottom and the misalignment of the movable element.

The proposed technical solution eliminates the above disadvantages, increases the reliability of the device in wells with small diameters, with variable or low pressure of the wellbore fluid, including by changing the pressure in the buffer and external chambers, hydraulically isolated from each other and from the overflow holes, This hydraulic device contains a hydraulic channel of high pressure, a movable element, sealing elements and a housing made with a chamber, with an inlet made with the possibility of hydraulic communication with the camera, and with bypass holes made with the possibility of hydraulic communication of the in-pipe space with the annulus, while the sealing elements are located inside the housing, the movable element is located inside the housing with the possibility of overlapping the bypass holes and with the possibility of interaction with the camera, the hydraulic channel is high the pressure is hermetically fixed in the inlet, the chamber is at least one buffer chamber, the construction is additionally equipped with external chambers with spring functions located in the housing with the possibility of charging it with a working agent and with the possibility of compression or decompression, while the buffer chamber is located in the housing with the possibility of hydraulic isolation from bypass holes and from external chambers, the sealing elements are located between the buffer and external cameras and between the buffer chamber and the bypass hole or holes, there are several movable elements and they are located with the possibility of a tight return staged movement, wherein each movable element is made with different cross-sectional sizes, the smaller cross-sectional dimension of the movable element is located on the side of the bypass holes or openings, and the larger cross-sectional size of the movable element is located on the side of the external chamber, the housing is made monolithic or prefabricated, it is equipped additional spring element located in the outer chamber and fixed in it with the possibility of interaction with the movable element, sealing element NT is a sealing surface, a sealing seal in the form of a ring or a sleeve, the bypass holes are made with different sizes of the flow cross-sections, the movable element is prefabricated or monolithic, in the form of a rod of variable cross-section or a rod of variable cross-section, in the form of a cylinder of variable cross-section or a piston of variable cross-section, it is further provided with a bypass chamber hydraulically connected to the bypass holes, at least one connecting element, an overlapping element, located on a movable element in the area of the bypass holes and made in the form of a ball or sphere, cone, cylinder, rubber-metal nozzle, one or more additional hydraulic channels hermetically connected to an external chamber or cameras, a fitting located in the bypass hole, one or more instrumentation downhole tools.

In FIG. shows a hydraulic device comprising a housing with a bypass chamber, with two buffer chambers and with two external chambers, while one external chamber is equipped with a plug and an additional spring element in the form of a charged bellows, the second external chamber is made open for hydraulic communication with the downhole fluid, the housing and external chambers are made in the form of a threaded monolithic coupling.

The hydraulic device consists of a housing 1 with external chambers 2 and with one or more buffer chambers 3, of one or more movable elements 4, of a hydraulic channel of high pressure 5 and sealing elements 6.

External chambers 2 are located in the housing 1 with the possibility of charging a predetermined pressure at the wellhead or in the well and with the possibility of providing a spring function.

The housing 1 is made with an inlet 7 and with bypass holes 8.

The housing 1 and the outer chambers 2 are made integral or composite, in the case of a composite execution of the part: the housing 1 and the outer chambers 2 are hermetically connected to each other by means of a detachable or one-piece connection. The detachable connection is, for example, a threaded connection, the permanent connection is, for example, a connection by soldering or welding.

The housing 1 is made, for example, in the form of a composite or integral coupling.

The inlet 7 is made in the housing 1 with the possibility of hydraulic communication with one or more buffer chambers 3.

The bypass holes 8 are made in the housing 1 with the possibility of hydraulic communication of the annular space with the in-tube space and are made with specified different or identical sizes of the flow sections. The size of the cross section of the bypass hole 8 is set depending on the conditions for regulating the flow of liquid or gas through the bypass holes 8. For example, the bypass holes 8 are made with fittings.

The external chamber 2 with the spring function is a space pre-charged by the working agent with a given pressure at the wellhead and in the well or in the well with the possibility of compressing or unloading the space of the external chamber, while changing its volume.

External chambers 2 are at least one external chamber 2 in the form of a closed space pre-charged by a working agent with a given pressure at the wellhead or in the well and at least another external chamber 2 in the form of an open space with the possibility of hydraulic communication with borehole fluid, the pressure of which determines the charging pressure of this chamber.

The external chamber 2, which is an unclosed space with hydraulic communication with the downhole fluid, contracts with a decrease in downhole pressure, decreasing its volume, and with an increase in downhole pressure is expanded, increasing its volume.

The buffer chamber or chambers 3 are located in the housing 1 between the sealing elements 6. The buffer chambers 3 are located in the housing 1 with the possibility of hydraulic communication with each other and with the inlet 7, while the buffer chamber 3 represents the space between the sealing elements 6.

The sealing elements 6 and the movable element or elements 4 are located in the housing 1 with the possibility of hydraulic isolation of the isolation of the buffer chamber 3 from the bypass hole or holes 8 and from the external chamber or cameras 2.

For example, the sealing elements 6 are mounted on the movable element 4 in the area of the outer chamber 2 between the buffer 3 and the outer 2 chambers and in the zone of the bypass hole 8 between the buffer chamber 3 and the bypass hole 8, hydraulically isolating the buffer chamber 3 from the bypass hole 8 and from the external chamber 2.

One or more buffer chambers 3 through the inlet 7 are hydraulically connected to the hydraulic channel of high pressure 5 with the possibility of changing the pressure in one or more buffer chambers 3.

The movable elements 4 are located in the housing 1 with the possibility of tight reciprocating movement in the housing 1, closing or opening the bypass holes or hole 8, while the movable element 4 is made composite or monolithic and with different sizes of the cross section, for example, in the form of a rod of variable cross section , a rod of variable cross-section, a cylinder of variable cross-section, a piston of variable cross-section, the cross-sectional dimension of the movable element 4 from the side of the bypass holes or holes 8 is less than the cross-sectional measures of the movable element 4 from the side of the outer chamber 2, which provides reciprocating movement of the movable element 4 towards its larger or smaller cross-sectional dimension when the pressure in the buffer chamber 3 changes, that is, the movement of the movable element 4 towards the outer chamber 2 or towards bypass openings or openings 8.

For example, in the zone of the bypass hole 8, the cross-sectional size of the movable element 4 is smaller than the cross-sectional size of the movable element 4 in the area of the outer chamber.

The hydraulic channel of the high pressure 5 is hermetically fixed in the inlet 7, for example, by means of a threaded connection, and is hydraulically connected to it.

The sealing element 6 is, for example, at least one sealing sleeve, at least one sealing seal in the form of a ring, at least one sealing surface.

For example, a sealing seal 6 in the form of a ring is located on the movable element 4 in the area of the bypass holes 8 and in the area of the outer chamber 2; a sealing surface 6 is fixed to the movable element 4 in the area of the bypass holes 8 and in the area of the outer chamber 2; the sealing surface 6 is fixed on the inner surface of the housing 1 in the area of the bypass holes 8 and in the area of the outer chamber 2.

The hydraulic device is further provided with at least one spring element 9, at least one bypass chamber 10, one or more additional hydraulic channels 11, at least one plug 12, at least one connecting element 13, one or several fittings and one or more overlapping elements 14, one or more control and measuring downhole tools for measuring charging pressures in the external chamber 2, pressures in the buffer 3 and bypass 10 chambers the pressure in the well.

The spring element 9 provides an additional spring function of the outer chamber 2, is located in the outer chamber 2 and is hermetically mounted on the movable element 4 and in the outer chamber 2 by means of a detachable or one-piece connection. The spring element 9 is, for example, a bellows chamber, a spring.

The bypass chamber 10 is hydraulically connected to the bypass holes or hole 8.

The additional hydraulic channel 11 is hermetically connected to the external chamber 2 with the possibility of charging it at a given pressure in the well.

The plug 12 is hermetically located in the outer chamber 2.

The connecting element 13 hermetically connects to each other, for example, the hydraulic channel of the high pressure 5 and the inlet 7, the hydraulic channel 11 and the outer chamber 2.

The connecting element 13 is, for example, a sleeve with a sealing element, a sleeve with a sealing element.

The fitting is located in the bypass hole 8.

The overlapping element 14 is mounted on the movable element 4 in the zone of the bypass holes - from the side of the bypass hole 8 and is made, for example, in the form of a ball or sphere, or cone, or cylinder, or in the form of a rubber-metal nozzle.

The control and measuring downhole tool is used to measure charging pressures in the external chamber 2, pressures in the buffer 3 and bypass 10 chambers and pressures in the well.

The device operates as follows.

A string of tubing pipes with a hydraulic device consisting of movable elements 4, a high pressure hydraulic channel 5, sealing elements 6, from a housing 1, with one or more buffer chambers 3, with external chambers 2 with spring functions, with an inlet 7 is lowered into the pipe and with overflow holes 8.

External chambers 2 with spring functions at the time the hydraulic device starts operating are charged with a working agent with a given pressure once before installation and lowering into the well at the wellhead and in the well or in the well, while the charging pressure in the static state in each external chamber 2 is always greater than the static pressure in the hydraulic channel of high pressure 5 and, accordingly, is always greater than the static pressure in the buffer chamber 3.

The working agent is a liquid or gas, for example, nitrogen, well fluid.

The buffer chamber or chambers 3 are hydraulically isolated from the bypass holes 8 and from the outer chambers 2 by means of sealing elements 6 and movable elements 4. In this case, the movable elements 4 are located in the buffer chamber or chambers 3 and in the outer chambers 2 with the possibility of hermetic reciprocating movement in the housing 1 in the sealing elements 6 and / or with sealing elements 6, providing hydraulic isolation disconnection of the buffer chamber or chambers 3 from the bypass holes 8 and from the outer chambers 2.

For example, if there is a bypass chamber 10, one movable element 4 is located in the bypass chamber 10, in the buffer chamber 3, in the outer chamber 2 and in the sealing elements 6 or with sealing elements 6, or in a sealing element or elements 6 and with a sealing element or elements 6 with the possibility of hermetic movement and providing hydraulic isolation of the buffer chamber 3 from the bypass hole or holes 8 and from the outer chamber 2.

Then, from the wellhead, a high-pressure hydraulic channel 5 is supplied with a working agent with a given pressure, which enters the inlet 7, and then into the buffer chamber or chambers 3, charging them with a working agent, changing the pressure in the buffer chamber or chambers 3 from static to predetermined pressure dynamic pressure. Then they move the movable elements 4. Each time, changing the pressure in the hydraulic channel of the high pressure 5 and, accordingly, changing the pressure in the buffer chamber or chambers 3, above or below the charging pressure by the working agent in the corresponding external chamber 2, they perform a reciprocating movement movable element to close or open the bypass holes 8.

The excess pressure in the buffer chamber or chambers 3 over the pressure in the outer chambers 2 entails the movement of the movable elements 4 towards the outer chambers 2 by compressing their space.

Due to the supply of a working agent to the buffer chamber or chambers 3 with a pressure higher than the charging pressure of the working agent in the outer chambers 2, and when pressure is pressed inside the outer chambers 2, the reciprocating movement of the movable elements 4 is carried out.

The movement of the movable elements 4 is carried out reciprocating and hermetically.

The reciprocating movement of the movable elements 4 is carried out by changing the pressure in the buffer chamber 3 above or below the charging pressure in the outer chamber or chambers 2, compressing or expanding the space of the outer chamber 2.

The tight movement of each movable element 4 is carried out in the sealing element 6 and with the sealing element 6, in the sealing elements 6 or with sealing elements 6.

In the process of hermetic reciprocating movement of the movable elements 4 open and / or close one or more bypass holes 8.

After opening or closing the bypass holes 8, the movable elements 4 hold in a predetermined position for a predetermined period of time, for example, by holding a predetermined pressure in the high pressure hydraulic channel 5 or inside the buffer chamber 3.

With open bypass openings 8, the bypass fluid is transferred from the annulus of the well to the in-annulus or vice versa, thereby regulating the flow of the borehole fluid.

Regulation of the charging pressure of the working agent in each external chamber 2 allows you to select the pressure necessary to determine a given initial transport position of each movable element 4 corresponding, for example, to the state of the hydraulic regulator in the open or closed position, including when lowering it into the well or when it is in the well.

The regulation of the pressure in the buffer chamber 3, changing the pressure relative to the pressure in each external chamber 2, allows you to move the corresponding movable element 4 from the initial state to a predetermined position and keep it in this state.

Pressure control in the buffer chamber or chambers 3 is carried out remotely at the wellhead manually, for example, using a manual hydraulic pump, compressor or automatically using hydraulic pumping stations programmed for a specific mode of operation.

Depending on the task, the hydraulic device is tuned to a specific predetermined mode of operation in the well, for example, the mode of balancing the pressure of the annular space of the well with the pressure in-pipe.

The movement of the movable elements 4 is carried out simultaneously or alternately.

For example, when installing two movable elements 4 in antiphase in the hydraulic device, the first movable element 4 opens the bypass holes 8 with the size of the cross-section corresponding to the first movable element 4, and the second movable element 4 closes the bypass holes 8 with the size of the cross-section corresponding to the second movable element 4 while both movable elements 4, moving simultaneously, open and close each of its bypass holes 8, bypassing and closing the bypass of the squat liquid from the annulus of the well into the annulus, depending on the specified pressure of the working agent corresponding to the charging pressure of the external chamber 2, the size of the cross section of the movable element 4 and the size of the cross-section of the bypass holes 8.

Thus, the simultaneous or alternate overlapping of the bypass holes 8 provided by different charging pressures of the external chambers 2 and / or by the different size of the cross-sectional area of the bypass holes 8, and / or by the execution of movable elements 4 with different cross-sectional sizes in the area of the bypass holes 8 and in the outer zone cameras 2.

The charging pressure of the working agent, for example, nitrogen, in the outer chamber 2 is set higher than the column pressure of the working agent filling the high pressure hydraulic channel 5, providing the “closed” or “open” mode in the initial transport state.

The pressure of the working agent in the buffer chamber 3 is periodically changed depending on the task, namely, it is created higher or lower than the pressure of the working agent in each external chamber 2, thereby ensuring reciprocating movement of the corresponding movable element 4, i.e., the higher the pressure in the outer chamber 2, the higher the pressure is created in the buffer chamber 3 while ensuring the movement of the movable element 4.

The proposed hydraulic device is used for simultaneous or separate production or injection, for which additional equipment is installed in the well that seals off the formation or layers, for example, a packer or packer, and then the hydraulic device is operated by passing the well fluid through the bypass holes 8 with movable elements 4 , with one or more buffer chambers 3 and external chambers 2. Why change the pressure in the hydraulic channel of high pressure 5 and, accordingly, in movable elements 4. The pressure of the working agent in the buffer chamber 3 is carried out above or below the charging pressure in each external chamber 2. By exceeding the working agent with the preset pressure from the high pressure hydraulic channel 5 through the inlet 7 pressure in the buffer chamber 3 above the pressure in the outer chamber 2 translates the movable element 4 towards the outer chamber 2 and compresses it, and when the pressure in the buffer chamber 3 decreases the expansion of the outer chamber 2 and the return movement of the movable element 4 to its original position, that is, towards the bypass openings or openings 8.

In the process of hermetic reciprocating movement of the movable elements 4 open and / or close the bypass holes 8.

After opening or closing the bypass holes 8, the movable elements 4 hold in a predetermined position for a predetermined period of time, for example, by holding a predetermined pressure in the buffer chamber, bypassing the well fluid from the annulus of the well into the annulus through the bypass holes 8 in the producing well or vice versa from the annulus well space into the annulus in the injection well.

It is possible to regulate the fluid bypass through the bypass holes 8 by setting a certain pressure in the high pressure hydraulic channel 5 and, accordingly, the buffer chamber 3. At the same time, it is also possible to switch to the operation of the movable element 4 only from the external open chamber 2 communicating with the well fluid without involving the second closed external camera 2 is put into operation.

For example, when the downhole pressure, respectively, the pressure in the external open chamber 2 is in communication with the downhole fluid, for example, when injected into the reservoir above the pressure in the buffer chamber 3, the movable element 4 is displaced, blocking the bypass hole or openings 8, and the injection stops. When a reservoir is exploited during production fluid extraction by production wells, the pressure in the reservoir and, accordingly, in the external open chamber 2 will begin to decrease and when lower than the pressure in the buffer chamber 3, then the movable element 4 in our injection well will move to the “open” position and the working agent will begin to be pumped into the formation through the bypass openings 8. With finer tuning based on the data of depth gauges and setting the set pressure in the buffer chamber 3, it is possible to clearly regulate the operation of important. The regulator will be set to a specific injection mode to maintain the planned reservoir pressure in automatic mode, i.e. the mode of opening or closing the bypass holes 8 and, accordingly, the mode of maintaining reservoir pressure at the planned level will be carried out without human intervention. With increasing pressure in the reservoir, the movable element 4 will move to the "closed" or "partially closed" position, while lowering the downhole pressure, the movable element 4 will move to the "open" position.

Example. At the mouth before mounting and lowering the hydraulic device into the well, a bypass chamber 10, two buffer chambers 3, two movable elements 4, two external chambers 2 and hydraulically isolate the buffer chambers 3 from the bypass holes 8 and the outer chambers 2 by means of sealing elements 6 are located in the housing 1 and movable elements 4. A bellows 9 is installed in one external chamber 2 and charged with nitrogen with a pressure exceeding the pressure of the well fluid. The bellows 9 enhances the spring function of the external chamber.

The second external chamber 2 interacts with the borehole fluid, which is a borehole fluid.

The external chamber 2 and the housing 1 are made in the form of a monolithic clutch.

The tubing is lowered into the well with one packer and a hydraulic device consisting of a high pressure hydraulic channel 5, with two movable elements 4 with an expanded part in the form of a cylindrical piston, from the housing 1 with inlet 7 and bypass holes 8, with two buffer chambers 3, hydraulically connected to each other and with the inlet 7, with two external chambers 2, with one external chamber 2 in the open design for communication with the borehole fluid, and the second external chamber 2 with the bellows 9 in the closed design.

The pressure in each buffer chamber 3 is changed from the mouth by supplying a hydraulic fluid with a predetermined pressure through the high pressure hydraulic channel 5 based on the possibility of moving each movable element 4. Setting the pressure in each buffer chamber 3 above the pressure of the corresponding external chamber 2, move the movable element 4 corresponding to its pressure, towards the bypass holes 8, closing the bypass holes 8.

By creating in each buffer chamber 3 a pressure exceeding the nitrogen charging pressure in the outer chamber 2 with a bellows 9 and the charging pressure of the well fluid in the second outer chamber 2, the movable elements 4 are moved based on the pressure of their movement, more precisely, the differential pressure of the movement, towards the outer chamber 2 by opening the bypass openings 8.

Since each movable element 4 in the outer chamber 2 has a cross-sectional size larger than that of the bypass holes 8, the increased pressure in the corresponding buffer chamber 3 acts on the expanded section of the corresponding movable element 4, translationally moving it towards the corresponding outer chamber 2 and c opening the corresponding bypass holes 8.

Compressed nitrogen in the bellows 9 in the first external chamber 2 performs the function of an additional spring, which enhances the return of the movable element 4 to its original transport position “closed” with a decrease in pressure in the high pressure hydraulic channel 5 and, accordingly, with a decrease in pressure in the buffer chamber 3.

The downhole fluid in the second external chamber 2 performs the function of a spring, which ensures the return of the movable element 4 to its original transport position “closed” with a decrease in pressure in the high pressure hydraulic channel 5 and, accordingly, with a decrease in pressure in the buffer chamber 3.

In the process of hermetic reciprocating movement of the movable elements 4 carry out the bypass of the well fluid from the annulus of the well into the in-tube space through the bypass holes 8.

The proposed technical solution allows to increase the reliability of the work and, accordingly, the efficiency of operation, including wells with variable pressures that change during their operation and low borehole pressure, and expands the possibilities of use in wells with small diameters, as well as minimize the number of hydraulic channels of high pressure in wells with simultaneous separate operation of several formations required for remote control of fluid bypass or gas from the annulus of the well into the annulus or vice versa, depending on the purpose of the well. The proposed technical solution also allows you to configure the control device to automatically shut off and partially or completely open the bypass holes, depending on the change in downhole pressure during the development of formations and maintain reservoir pressure, allows for simultaneous or alternate opening of the bypass holes, sequentially and selectively positionally opening them, including remotely by changing the pressure in the high pressure hydraulic channel and, accordingly, changing yes the emergence of a buffer chamber, as well as ensuring economic efficiency both in the production of hydrocarbon fluid and in the maintenance of reservoir pressure in the developed oil and gas deposits.

Claims (18)

1. A hydraulic regulator comprising a hydraulic channel of high pressure, a movable element, sealing elements and a housing made with a chamber, with an inlet made with the possibility of hydraulic communication with the camera, and with overflow openings made with the possibility of hydraulic communication of the annulus with the annulus while sealing elements are located inside the housing, the movable element is located inside the housing with the possibility of overlapping bypass openings d and with the possibility of interacting with the chamber, the high-pressure hydraulic channel is hermetically fixed in the inlet, characterized in that the chamber is at least one buffer chamber, the device is additionally equipped with external chambers with spring functions located in the housing with the possibility of charging it a working agent and with the possibility of compression or decompression, while the external chambers with spring functions are at least one in the form of an enclosed space and at least one in the form of e open space with the possibility of hydraulic communication with the borehole fluid, the buffer chamber is located in the housing with the possibility of hydraulic isolation from the bypass holes and from external chambers, sealing elements are located between the buffer and external chambers and between the buffer chamber and the bypass hole or holes, several movable elements, arranged with the possibility of tight reciprocating movement, while each movable element is made with different sizes cing sections, the smaller cross-sectional dimension of the movable element located on the side of metering orifices or holes, and the larger cross-sectional dimension of the movable member is situated from the outer chamber. 2. The hydraulic regulator according to claim 1, characterized in that the housing is made monolithic or prefabricated. 3. The hydraulic regulator according to claim 1, characterized in that it is equipped with an additional spring element located in the external chamber and fixed in it with the possibility of interaction with the movable element. 4. The hydraulic regulator according to claim 1, characterized in that the sealing element is a sealing surface. 5. The hydraulic regulator according to claim 1, characterized in that the sealing element is a sealing seal in the form of a ring or sleeve. 6. The hydraulic regulator according to claim 1, characterized in that the bypass holes are made with different sizes of the flow cross sections. 7. The hydraulic controller according to claim 1, characterized in that the movable element is prefabricated or monolithic. 8. The hydraulic controller according to claim 1, characterized in that the movable element is made in the form of a rod of variable cross-section or a rod of variable cross-section. 9. The hydraulic regulator according to claim 1, characterized in that the movable element is made in the form of a cylinder of variable cross-section or a piston of variable cross-section. 10. The hydraulic regulator according to claim 1, characterized in that it is additionally equipped with a bypass chamber hydraulically connected to the bypass holes. 11. The hydraulic regulator according to claim 1, characterized in that it is further provided with at least one connecting element. 12. The hydraulic regulator according to claim 1, characterized in that it is additionally equipped with a blocking element in the form of a ball or sphere located on a movable element in the area of the bypass holes. 13. The hydraulic regulator according to claim 1, characterized in that it is additionally equipped with a cone-shaped blocking element located on the movable element in the zone of the bypass openings. 14. The hydraulic regulator according to claim 1, characterized in that it is additionally equipped with a blocking element in the form of a cylinder located on a movable element in the area of the bypass holes. 15. The hydraulic regulator according to claim 1, characterized in that it is additionally equipped with a blocking element in the form of a rubber-metal nozzle. 16. The hydraulic regulator according to claim 1, characterized in that it is additionally equipped with one or more additional hydraulic channels hermetically connected to an external chamber or cameras. 17. The hydraulic regulator according to claim 1, characterized in that it is additionally equipped with a fitting located in the bypass hole. 18. The hydraulic regulator according to claim 1, characterized in that it is additionally equipped with one or more control and measuring downhole tools.

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