RU54618U1 - VALVE DEVICE - Google Patents

Abstract

The proposal relates to oil production and can be used to bleed gas from the annulus of a well into a flow line. The valve device includes a hollow body with inlet and outlet nozzles, as well as radial and axial channels. In the axial channel there is a valve consisting of a hermetically movable sleeve, a spring supported on an adjustable leaky cup installed in the axial channel of the hollow body. The inlet pipe is coaxially and rigidly connected to the hollow body in the opposite direction to the glass. The outlet pipe is in communication with the radial channel, which is hermetically sealed in the initial position by a sleeve provided with radial channels for the balls. In the inner cavity of the sleeve with the possibility of tight axial movement, there is a finger equipped with a front ring on the inlet pipe side and a rear ring stop on the opposite side. The hollow body is equipped with a partition that limits the axial movement of the finger from the side of the glass. The finger is the rear annular emphasis, spring-loaded by means of a spring, from the glass to the partition of the hollow body. In the axial channel of the hollow body, next to its radial channel from the side of the glass, an annular selection is made for balls supported from the inside of the sleeve by a finger. An annular groove is made on the outer surface of the finger, which has the ability to interact with the balls. The finger between the annular groove and the rear annular stop is equipped with a cylindrical selection that can interact with a ball spring-loaded by means of an adjusting screw. The ball, spring and adjusting screw are placed in the technological hole made in the partition of the hollow body. A through channel is made in the hollow body in front of the partition from the inlet side to eliminate the effect of “pistoning” in the process of moving the sleeve relative to the hollow body. An additional radial channel is made in the hollow body, which is not covered by a sleeve and equipped with a pressure gauge with which the valve device is set up and monitored during operation. The proposed valve device allows, within the required limits, to regulate the opening and closing pressure of the valve directly during operation with constant pressure control, and the exception of the drive of the shut-off element, made in the form of a rotary valve, allows to increase the tightness of the device and extend its service life.

Description

The proposal relates to oil production and can be used to bleed gas from the annulus of a well into a flow line.

Known check valve (Handbook of oil production / V.V.Andreev, K.R. Urazakov, V.U.Dalimov and others; Edited by K.R. Urazakov. - 2000, pp. 94-96 - analogue ) for transferring gas from the annulus to the flow line, which is part of the equipment of the wellhead OU140-146 / 168-65A and OU140-146 / 168-65B, consisting of a saddle and a spring ball.

The disadvantage of this device is that the check valve, which is part of the equipment of the wellhead only bypasses gas through itself, but does not allow to block the channel from the annulus to the flow line, which is necessary when carrying out technological operations in the process of underground and workover, such as jamming, flushing and the like, in connection with which a check valve or valve is required before the check valve, and this leads to an increase in the metal consumption of the structure.

The closest in technical essence is the valve device (Certificate of the Russian Federation for utility model No. 20536, IPC 7 E 21 V 34/02, publ. BI No. 31 dated 10.11.2001), including a hollow body with an axial channel, a valve placed in it consisting of a saddle and a locking member, a movable spring-loaded sleeve and a fitting, as well as an inlet pipe and an outlet pipe made at the end of the housing, and a glass is installed at the end of the housing opposite the outlet pipe, while the receiving and placed on both sides are made in the housing intermediate from her cavities hydraulically connected to each other by an axial channel, the movable sleeve with one end is rigidly connected to the valve shut-off element, and a spring is installed from its other end connected with the rod of the adjusting device installed at the end of the glass, while the valve shut-off is made with an axial passage channel, the fitting is placed in the intermediate cavity from the side of the outlet pipe, sealing elements are fixed on the outer surface of the sleeve, and the inlet pipe is in communication with the receiving cavity by means of a radially channel.

The disadvantages of this device are:

firstly, the pressure at which the valve opens is not controlled directly on the device itself (lack of a pressure gauge), and therefore it is not possible to track at what pressure the valve opens during operation;

secondly, often during operation there is a need to change the opening and closing pressure of the valve within certain limits, which this device design does not allow to do;

thirdly, the stuffing box packing of the shut-off valve actuator, made in the form of a rotary valve, is not durable, and in the process of frequent openings and closures, its wear occurs and, as a result, loss of tightness, and therefore constant monitoring and maintenance of the device is required.

The objective of the utility model is to create a valve device design that allows, within the required limits, to control the opening and closing pressure of the valve directly in the process of working with pressure control, as well as increasing the tightness of the device.

The problem is solved by the proposed valve device, comprising a hollow body with inlet and outlet nozzles, as well as with radial and axial channels, in which a valve is located, consisting of a hermetically movable sleeve, a spring supported by an adjustable leaky cup installed in the axial channel.

What is new is that the inlet pipe is coaxially and rigidly connected to the hollow body in the opposite direction to the cup, and the outlet pipe is in communication with the radial channel, which is hermetically sealed in its initial position by a sleeve provided with radial channels for the balls, while in the inner cavity of the sleeve it can be sealed axial movement of the finger is located, provided on the inlet pipe side with a front and rear ring stops on the opposite side, and the hollow body is provided with a partition, limiting axial movement of a finger from the side of the cup, which is spring loaded with a rear ring stop from the cup to the partition of the hollow body, moreover, in the axial channel of the hollow body, next to its radial channel, an annular selection is made for balls, supported from the inside of the sleeve by a finger, an annular is made on the outer surface of the finger a groove having the ability to interact with the balls, while the finger between the annular groove and the rear annular stop is equipped with a cylindrical selection having the ability to interact with the ball a person placed in the technological hole made in the partition of the hollow body, the ball being spring-loaded to the finger with the adjusting screw, while the through channel is made in the hollow body in front of the partition from the inlet side, and an additional radial channel is made in the hollow body, which is not covered by a sleeve and provided pressure gauge.

The figure shows the proposed valve device in longitudinal section.

The valve device includes a hollow body 1 with input 2 and output 3 nozzles, as well as radial 4 and axial 5 channels. In the axial channel 5 there is a valve consisting of a hermetically movable sleeve 6, a spring 7, supported by an adjustable leak-tight cup 8, mounted in the axial channel 5 of the hollow body 1.

The inlet pipe 2 is coaxially and rigidly connected to the hollow body 1 in the opposite direction to the glass 8. The output pipe 3 is in communication with the radial channel 4, which is hermetically sealed in its initial position by a sleeve 6 provided with radial channels 9 for the balls 10.

In the inner cavity of the sleeve 6 with the possibility of tight axial movement is a finger 11, provided on the inlet pipe 2 side with a front 12, and on the opposite side with a rear 13 ring stops.

The hollow body 1 is provided with a partition 14 restricting the axial movement of the finger 11 from the side of the glass 8. The finger 11 is provided with a rear ring stop 13, spring-loaded by means of a spring 7, from the glass 8 to the partition 14 of the hollow body 1.

In the axial channel 5 of the hollow body 1, next to its radial channel 4 from the side of the cup 8, an annular sample 15 is made for the balls 10, supported from the inside of the sleeve 6 by the finger 11. On the outer surface of the finger 11, an annular groove 16 is made, which has the ability to interact with the balls 10.

The finger 11 between the annular groove 16 and the rear annular stop 13 is equipped with a cylindrical selection 17, which can interact with the ball 18, spring-loaded by means of the spring 19 of the adjusting screw 20. The ball 18, the spring 19 and the adjusting screw 20 are placed in the technological hole made in the partition 14 of the hollow casing 1. In the hollow casing 1 in front of the partition 14 from the side of the inlet pipe 2, a through channel 21 is made to eliminate the effect of "pistoning" in the process of moving the sleeve 6 relative to the hollow casing 1.

An additional radial channel 22 is made in the hollow body 1, which is not blocked by the sleeve 6 and equipped with a pressure gauge 23 with which the valve device is set up and monitored during operation.

Unauthorized fluid flows during operation are eliminated by sealing elements 24, 25.

The valve device operates as follows.

The valve assembly is installed in the wellhead equipment (for example, as part of OU140-146 / 168-65A or OU 140-146 / 168-65B) for bleeding gas from the annular space of the well into the flow line by turning the valve

device inlet pipe 2 into the production casing, and the output pipe 3 is connected to the flow line (not shown in the figure).

Next, the valve device is adjusted according to the manometer 23.

To do this, by turning or turning the cup 8 into the hollow body 1, adjust the spring 7 to a certain pressure (for example, 5.0 MPa), at which the valve should open, that is, the sleeve 6 should move relative to the hollow body 1, and open the radial channel 4 hollow body 1.

By twisting or turning the adjusting screw 20 into the technological hole made in the partition 14 of the hollow body 1, the spring 19 is adjusted to a certain pressure (for example, 1.0 MPa) at which the valve should close, that is, the sleeve 6 should move back relative to the hollow body 1, and close the radial channel 4 of the hollow body 1.

During the operation of the well, gas rises upward through the annulus of the production casing and enters the axial channel 5 of the hollow body 1 through the inlet pipe 2, exerting an impact on the front annular stop 12 of the finger 11. When the valve opens in the axial channel 5 of the hollow body 1, noted above - 5.0 MPa, the finger 11 moves toward the cup 8, compressing the spring 7 until the balls 10 get into the annular groove 16 made on the outer surface of the finger 11, while the balls 10 fall out of the ring selection 15 of the housing 1 and the front annular abutment 12, finger 11 acts on the sleeve 6.

At this moment, the movement of the finger 11 relative to the sleeve 6 is stopped and the sleeve 6 together with the finger 11 are displaced towards the glass 8 relative to the hollow body 1, compressing the spring 7. The movement of the sleeve 6 occurs until the ball 18 is pressed against the finger 11 by the spring 19 will fall into the cylindrical selection 17 of the finger 11. After the ball 19 enters the cylindrical selection 17 of the finger 11, the spring 19 is unclenched (due to the return force) and the finger 11, and therefore the sleeve 6 are fixed relative to the hollow body 1, and the valve opens, then e The radial channel 4 and the axial channel 5 of the hollow body 1 are hydraulically connected, passing gas into the flow line (not shown in the figure).

As the gas is bleed into the flow line, the pressure in the axial channel 5 of the hollow body 1 drops and when the valve closes to 1.0 MPa, the return force of the spring 7 transfers the ball 18, which fixes the pin 11 and the sleeve 6 relative to the hollow body 1 in a cylindrical sample 17, causing compression of the spring 19.

As a result, the spring 19 is compressed, and the ball 18 is buried in the technological hole of the partition 14 of the hollow body 1.

The sleeve 6 together with the finger 11 are moved towards the inlet pipe 2 relative to the hollow body 1 due to the return force of the spring 7 until the balls 10 fall into the annular selection 15 of the hollow body 1, while the balls 10 fall out of the annular groove 16 of the finger 11.

The movement of the sleeve 6 relative to the hollow body 1 is stopped, and the valve closes (the sleeve 6 hermetically cuts off the radial channel 4 from the axial channel 5 of the hollow body 1). Further, the finger 11, freed from interaction with the balls 10, due to the return force of the spring 7 moves relative to the sleeve 6 until its back ring 13 rests against the partition 14 of the hollow body 1 from the side of the glass 8.

The opening and closing pressure of the valve during operation is controlled by a manometer 23 connected to the axial channel 5 of the hollow body 1 by means of an additional radial channel 22 and can be adjusted starting from zero or higher directly during operation of the valve device by opening or wrapping the cup 8 and / or adjusting screw 20.

The proposed valve device allows, within the required limits, to control the opening and closing pressure of the valve directly during operation with constant pressure control, and the exception of the drive of the shut-off element, made in the form of a rotary valve, can increase the tightness of the device and extend its service life.

Claims (1)

Valve device, comprising a hollow body with inlet and outlet nozzles, as well as with radial and axial channels, in which a valve is placed, consisting of a hermetically movable sleeve, a spring supported on an adjustable leaky cup installed in the axial channel, characterized in that the inlet pipe coaxially and rigidly connected to the hollow body in the opposite direction to the cup, and the outlet pipe is in communication with the radial channel, which is hermetically sealed in its initial position by a sleeve provided with radial channels under ariki, while in the inner cavity of the sleeve with the possibility of tight axial movement there is a finger equipped with a front ring support on the inlet pipe side and rear ring stops on the opposite side, the hollow body having a partition restricting axial movement of the finger from the glass side, which is the rear ring stop spring-loaded from the cup to the partition of the hollow body, and in the axial channel of the hollow body next to its radial channel from the side made an annular selection of balls supported and inside the sleeve with a finger, an annular groove is made on the outer surface of the finger that can interact with the balls, while the finger between the annular groove and the rear annular stop is equipped with a cylindrical selection that can interact with the ball located in the technological hole made in the partition of the hollow body, the ball is spring-loaded to the finger with an adjusting screw, while a through channel is made in the hollow body in front of the partition from the inlet pipe side, and in the hollow body Execute additional radial passage, do not overlap the sleeve and provided with a pressure gauge.