NO20100228A1 - Side pocket valve assembly in a well - Google Patents

Abstract

The present invention relates to a valve device for use in a side pocket and or sub in a well, comprising a housing (1) with a first opening (2) and a second opening (3), a first valve body (11) arranged movable internally in the housing (1), a second valve body (20) arranged internally in the housing (1) and movable with respect to both the housing (1) and the first valve body (11), wherein a first locking device (A) is configured between the first valve body (11). ) and the second valve body (20) to lock the movement of the first valve body (11) relative to the second valve body (20) in one direction and so that when the first locking device (A) is actuated, the first valve body (11) is held in position. an open position as long as the second valve body (20) is in an open position, so as to have flow through the valve means, and a third locking device (C) configured between the second valve body (20) and the housing (1), so that a release of the third lock the device (C) will allow movement of the second valve body (20) relative to the housing (1) and thus to a closed position of the valve device and thus also allow the first valve body (11) to move into a closed position. The invention also relates to a method.

Description

According to the invention, the valve device further comprises a second valve body arranged inside the housing and movable in relation to both the housing and the first valve body, a first locking device configured between the first valve body and the second valve body, to lock the movement of the first valve body in relation to the second valve body in one direction and so that when the first locking device is activated the first valve body is kept in an open position as long as the second valve body is in an open position, so that one has flow through the valve device and a third locking device configured between the second valve body and the housing, so that a release of the third locking device will allow movement of the second valve body relative to the housing and thus to a closed position of the valve device and thus also allow the first valve body to move to a closed position.

In one embodiment, the first valve body can be shaped so that, together with a valve seat formed by a surface in the housing, it closes off the second opening in the housing and forms a barrier for the flow of fluid from the production pipe into the valve device and thus also out into the annulus. In one embodiment, the second valve body can be shaped so that, together with a valve seat formed in the housing, it closes off the first opening in the housing and forms a barrier for the flow of fluid from the annulus into the valve device and thus also into the production pipe. The housing of the valve device is shaped with external devices so that it can be placed in the sub and or side pocket and form seals between the two openings in the sub or side pocket, so that all flow through the sub or side pocket proceeds through the valve device.

When using the valve, it will normally be configured with the first valve body in a closed position and the second valve body in an open position. From this, when one has a pressure-activated first valve body, pressure is applied in the annulus to move the first valve body from a closed position to an open position and thus by this movement, lock the first valve body relative to the second valve body in the first locking device . In such an open position of the valve device, it will be possible to circulate fluids from the production pipe to the annulus and the opposite way, depending on the need for use. When you have circulated out/in the desired fluid, you either close the annulus or the production pipe and press up the fluid in the well, until the third locking device is released. When this is released, the second valve body will move from an open position to a closed position and thus the first valve body will also be moved to a closed position and the valve device will be closed. After this, there is no fluid communication between the annulus and the production pipe through the valve device.

According to one embodiment, the first locking device may comprise a ratchet locking, where the first valve body has a ratchet device facing one way and the second valve body has a ratchet device facing in the opposite direction. When these two ratchet devices engage each other they allow further movement in one direction but prevent movement in the opposite direction. Alternatively, the first valve body may comprise a locking ring which, when the valve body has moved to an open position, engages with a groove in the second valve body and locks them relative to each other.

According to one embodiment, the valve device may also comprise a second locking device configured between the second valve body, the housing and the first valve body, so that the second valve body is firmly locked relative to the housing in an open position, until the first valve body is locked in the first locking device and thus in the open position of the valve device. Such a locking device can also prevent the third locking device from being released before the first valve body is locked by the first locking device of the second valve body. The introduction of this second locking device thus provides greater certainty that the operation of the valve device follows the desired procedure.

According to a further embodiment, the valve device can also comprise a fourth locking device configured between the housing and the first valve body, so that it locks the first valve body to the housing in a closed position and further arranged so that this must be released before the first valve body can be moved and locked with the first locking device. Such a locking device can be set to break at a higher pressure difference between the annulus and the production pipe than the pressure difference which, without this fourth locking device, would move the first valve body from a closed position to an open position in the event that the valve body is pressure activated. This fourth locking device can be a shear pin arranged between the first valve body and the housing, alternatively a rupture disk that opens for fluid to affect the first valve body or another type of rupture element which, after rupture, means that the first valve body can be moved to an open position. As an alternative to a fourth locking device, one can instead use a throttle in the fluid supply which influences the first valve body to move to an open position due to the pressure difference across the valve body. This ensures that the valve body does not open due to sudden and short pressure variations in the fluids around the valve device. In a further alternative embodiment, this throttling can further be arranged with a ball, which allows you to regulate/throttle the flow rate through the valve to open the first valve body in relation to the housing, but also arrange the ball and the flow path so that you can have a larger flow diameter in opposite direction, for example reduced flow rate in the direction from the annulus to the production pipe and greater flow rate in the direction from the production pipe to the annulus.

According to one embodiment, the first locking device can be activated from a free position to a locked position, by moving the first valve body relative to the housing from a closed position to a locked open position at a given pressure difference between a pressure in the annulus and a pressure in the production pipe. This is achieved by having pressure surfaces on the first valve body which, under the influence of fluids in the annulus and in the production pipe, will exert forces on the first valve body which cause it to move between the closed and open position. The valve body can also be biased in a closed position by means of an elastic element arranged between the housing and the valve body.

According to an embodiment of the invention, a chamber set with a given pressure can be arranged between the second valve body and the housing before installation of the valve device in the well. This pressure can be vacuum or another pressure set before installation of the valve device in the well. Furthermore, an embodiment of the housing and the second valve body can be such that this chamber is opened and or punctured and thus no longer forms a closed chamber upon movement of the second valve body, so that no "fluid cushion" is formed for movement of the second valve body which a consequence of this chamber.

According to one embodiment, the third locking device can be configured so that when the valve device is in an open position, the third locking device can be released by a given pressure difference between the chamber and a pressure applied in the well, so that the second valve body goes to a closed position. In an embodiment where there is also a second locking device in the valve arrangement, a release of the third locking device requires that the second locking device has already been released. The third locking device can be a shear pin, or also a breaking disc, locking ring or other device.

According to one embodiment, a second locking device can be configured with at least one recess inside the housing, a through groove in the second valve body and a recess in the first valve body, with a locking ring or dog/claw arranged in the groove in the second valve body . This locking ring, when aligned with the recess in the housing, will engage with this and only allow relative movement between these parts when a force is overcome and the recess of the first valve body is aligned with the slot and the recess in the housing, so that the locking ring has room to be moved out of the recess in the house. When the recess of the first valve body is not aligned with the groove in the second valve body and the recess in the housing, the locking ring will not have any room to move out of the recess in the housing, so that the second valve body is firmly locked to the housing.

According to a further embodiment, the valve device according to the invention may comprise a fifth locking device which locks the second valve body firmly in relation to the housing in a closed position. This fifth locking device can in one embodiment be formed by locking hooks arranged on the second valve body and in the housing, which when they engage do not allow movement in the opposite direction.

According to a possible embodiment of the invention, the first valve body can be arranged relatively within the second valve body and where the first valve body in a closed position closes the opening towards the production pipe and the second valve body in a closed position closes the opening towards the annulus. In one possible embodiment, the second valve body can be mainly sleeve-shaped and comprise an inflow opening through the sleeve wall for fluid flow. The first valve body may comprise is mainly cylindrical main part with a central flow passage with an opening at one end of the cylinder facing the first opening of the valve arrangement and a closed opposite end of the cylinder with openings arranged in a side wall of the cylinder facing the second opening of the valve arrangement . The closed end of the cylinder provides an area that allows you to control the opening/closing of the valve so that it is pressure regulated. According to another embodiment, the first valve body can have a shape other than cylindrical, for example polygonal, such as octagonal, hexagonal, triangular, etc. The second valve body will then have a complementary shape to the shape of the first valve body. Also these alternative embodiments may have a central flow passage through the first valve body which is open at one end and which is closed at the opposite end with openings in the side wall near this closed end. Also in these cases, this inner end surface can be used for pressure regulation of the movement of the first valve body between an open and a closed position. Such a device also provides a large flow area and only a small number of deflections on the flow path through the valve.

The present invention also relates to a method for operating a valve device between the production pipe and annulus in a well, where the valve device comprises a first opening and a second opening. According to the method, fluid is pressurized in the annulus which is allowed to flow into the valve device until a pressure difference is achieved between annulus pressure and production pipe pressure, so that the second opening of the valve is opened and the valve is locked in this position and fluid is allowed to flow through the valve, after which the fluid in the well is pressurized so that a locking device inside the valve is broken and both the second and first opening are closed.

The invention will now be explained with a non-limiting embodiment example with reference to the attached figures, where;

Fig. 1 showing a sectional view of the valve in a first closed position,

Fig. 2 shows the valve in fig. 1 in a second open position,

Fig. 3 shows the valve in fig. 1 in a third closed position,

Fig. 4 shows a detail of fig. 3, and

Fig. 5 shows a valve according to the invention placed in a sub in a production pipe.

In fig. 1 shows a valve according to the invention. It comprises a housing 1 which is elongated so that it fits into a side pocket or sub (see fig. 5) and has a first opening 2 in the side wall and a second opening 3. Furthermore, the housing 1 has a first sealing surface 4 and a second sealing surface 5, arranged on either side of the first opening 2 and one of the sealing surfaces 4 arranged between the first opening 2 and the second opening 3. The housing has an internal space and in this a first valve body 11 and a second valve body 20 are arranged, movable in relation to the house and movable in relation to each other. Both valve bodies 11, 20 can be moved in the longitudinal direction of the housing. The first valve body 11 is a substantially cylindrical body with an internal flow passage 14. This flow passage 14 extends in the direction of movement of the first valve body 11. The cylindrical element forming the flow passage 14 has an open end 15 and is closed at the opposite end, but has wall openings 13. The wall openings 13 are in an open position of the first valve body aligned with the second opening 3 of the housing. The second valve body 20 is mainly sleeve-shaped and is arranged located partly outside and surrounding the first valve body. The open end 15 of the first valve body 11 ends inside the second valve body 20. The second valve body has opening 21 in its side wall, which when the second valve body is in an open position is aligned with the first opening 2 in the housing. With such a configuration of the two valve bodies, a relatively large flow passage is obtained through the valve device. This flow passage is also shaped with a minimum of directional changes to the flow through the passage. The flow passage flows in radially and then flows axially through the valve to a more radial outlet. There are only two deflections of the flow path through the valve.

The first valve body 11 is in one embodiment attached to the housing 1 with a fourth locking device D. The first valve body 11 is then in a closed position so that sealing surfaces 12 on the first valve body 11 are in contact with a valve surface 6 in the housing 1, as shown on fig. 1. In the embodiment shown, this fourth locking device D comprises a shear pin opening 18 in the first valve body 11, a shear pin 26 and a shear pin opening 27 in the housing. When pressure is applied through the first opening 2 which is open since the second valve body 20 is in an open position, the pressure will affect the first valve body 11, for example at the inner end surface of the flow passage and when the pressure difference between the first 2 and second 3 opening in the housing becomes of a given size, the fourth locking device will be broken and the first valve body will move to an open position, as shown in fig. 2. Instead of shear pin openings and shear pins, one can alternatively have a rupture disc which prevents movement of the first valve body before a given pressure difference is reached. As indicated above, one must also not have the fourth locking device, as the first valve body can be opened on the pressure difference without a locking device as such.

When the first valve body 11 has moved to an open position, see fig. 2, by moving the first valve body 11 in the longitudinal direction of the housing 1, the first locking device A engages and locks the first valve body 11 in relation to the second valve body 20, so that they can only move in one direction relative to each other. The first locking device A comprises locking hooks 17 arranged on the outside of the first valve body 11 and oppositely arranged locking hooks 22 arranged inside the second valve body 20. These locking hooks 17, 22 engage and lock. The locking hooks 17 on the outside of the first valve body are also arranged with some flexibility in the radial direction so that an easier joining is achieved. This flexibility can be achieved by the latches around the perimeter being shaped with at least one split. Alternatively, the first locking device may comprise a locking ring arranged on the first valve body and a slot in the second valve body.

In this position as indicated in fig. 2, a second locking device B which locks the second valve body 20 firmly in relation to the housing 1 is also released. The second locking device B comprises a recess 8 in the housing, a continuous groove 23 in the second valve body 20 and a recess 16 in the first valve body 11, and a locking segment 28, best seen in fig. 4. The locked position of the second locking device is formed by the fact that the locking segment 28 which is arranged in the continuous groove 23 will be pressed into the recess 8 in the housing, since a wall of the first valve body 11 prevents the locking segment 28 from exiting the recess 8 in the house, see fig. 1. The second valve body 20 will then be firmly locked to the housing 1 and cannot be moved relative to this. When the first valve body 11 has been moved to an open position, see fig. 2, a recess 16 in the outer wall of the first valve body will be aligned with the groove 23 in the second valve body 20, and the locking segment 28 can thus be moved out of the recess 8 in the housing, and the second valve body 20 is no longer locked to the housing 1. The locking segment 28 can be a locking ring, or one or more dogs, claws or slopes, arranged in the groove 23 in the second valve body 20.

In this position as shown in fig. 2, there is full flow through the valve, and the valve remains in this open position until a third locking device C is activated. The third locking device C can be activated by putting a pressure in the well which thus breaks the third locking device comprising a locking pin 30 which is arranged in a locking pin slot 25 in the second valve body 20 and a locking pin slot 29 in the housing 1. One can here imagine other solutions where an element breaks and thus frees up movement. This could be, for example, a pin arranged on one element which lies in a groove in the other, a rupture disc, a friction coupling, etc.

The pressure required to release the third locking device is a pressure difference between the fluid in the well and a pressure in a chamber 31 formed between the second valve body 20 and the housing 1. This chamber 31 is delimited by a sealing surface 7 around the first opening 2 and a further gasket 32 between the second valve body 20 and the housing 1. This chamber 31 is set with a given pressure when assembling the valve. When the third locking device is broken, due to pressure on the second valve body 20, a movement of this second valve body will occur so that it moves in the longitudinal direction of the housing 1. With this movement, the chamber 31 will also be opened, since the second valve body 20 moves away from the sealing surface 7, as shown in fig. 3. This results in no "fluid cushion" for the movement of the second valve body 20 relative to the housing 1 due to the chamber 31. This movement of the second valve body 20 will also allow the first valve body 11, which is biased by an elastic element 19 between the housing 1 and the first valve body 11, to move to a closed position. The valve device is thus completely closed in that both the first and second valve bodies are in a closed position and there is thus again a barrier between the production pipe and the annulus in the well.

Furthermore, when the second valve body 20 has moved relative to the housing to a closed position, as shown in fig. 3 a fifth locking device E which locks the second valve body 20 relative to the housing 1 in this position. This fifth locking device E comprises locking hooks 9 arranged inside the housing 1, and oppositely directed locking hooks 24 arranged externally on the second valve body 20. The locking hooks 9 in the housing are arranged with some radial flexibility. This can be achieved by designing them with a split. Furthermore, they can be biased to a position by a centralizing ring that supports the ratchets.

The locking segment 28, which can be one or more segments arranged around a circumference, will in a first locked position of the second locking device cooperate with a first groove 8a formed in the housing 1. When the third locking device is released and the fifth locking device is moved in engagement, the locking segment 28 will be in connection with a second slot 8b formed in the housing 1. Also a seal in connection with the chamber 31 is in this position in connection with the slot 8b, so that the chamber in this position is also opened on this side of the chamber 31. In a variant, the valve can be shaped so that the locking segment 28 in this position is not in connection with any groove in the housing.

In fig. 5 shows a valve device according to the invention placed in a sub 40 in a production pipe with a main pipe 41. The valve device is placed in a side chamber with an opening 43 to the annulus and opening 42 to the production pipe. In the embodiment shown, an internal sleeve 44 is also arranged in the production pipe. The sleeve 44 has a plurality of openings 45. When the valve device is to be used, the sleeve 44 is moved so that these are aligned with the opening 42 and flow can be obtained. The invention is now explained with reference to an exemplary embodiment. A person skilled in the art will understand that it will be possible to make several modifications and changes to this embodiment which are within the scope of the invention as stated in the following claims. For example, it will be possible to omit both the second, fourth and fifth locking device and still have a valve that fulfills the purpose. It will also be possible to make the valve with other types of locking devices than those shown.

Claims (11)

1. Valve device for use in a side pocket and or sub in a well, comprising a housing (1) with a first opening (2) and a second opening (3), where the first opening (2) in use leads to the annulus and the second opening (3) leads to the production pipe, and a first valve body (11) arranged movably inside the housing (1), characterized in that it comprises - a second valve body (20) arranged inside the housing (1) and movable in relation to both the housing (1) and the first valve body (11), - a first locking device (A) configured between the first valve body (11) and the second valve body (20) to lock the movement of the first valve body (11) relative to the second valve body (20) in one direction and so that when the first locking device (A) is activated, the first valve body (11) is held in an open position as long as the second valve body (20) is in an open position, so that there is flow through the valve device, and - a third locking device (C) configured between it the second valve body (20) and the housing (1), so that a release of the third locking device (C) will allow movement of the second valve body (20) relative to the housing (1) and thus to a closed position of the valve device and thus also allow that the first valve body (11) moves to a closed position. 2. Valve device according to claim 1, characterized in that it comprises a second locking device (B) configured between the second valve body (20), the housing (1) and the first valve body (11), so that the second valve body (20) is fixed locked relative to the housing (1) in an open position, until the first valve body (11) is locked in the first locking device (A) and thus in the open position of the valve device. 3. Valve device according to claim 1 or 2, characterized in that it comprises a fourth locking device (D) configured between the housing (1) and the first valve body (11), so that it locks the first valve body (11) to the housing (1) in a closed position and further arranged so that this (D) must be released before the first valve body (11) can be moved and locked with the first locking device (D). 4. Valve device according to one of the above-mentioned claims, characterized in that the first locking device (A) is activated from a free position to a locked position, by the first valve body (11) being moved relative to the housing (1) from a closed position to a locked open position at a given pressure difference between a pressure at the first opening (2) and a pressure at the second opening (3). 5. Valve device according to one of the above-mentioned claims, characterized in that between the second valve body (20) and the housing (1) there is arranged a chamber (31) set at a given pressure before installation of the valve device in the well. 6. Valve device according to one of the above-mentioned claims, characterized in that the third locking device (C) is configured so that when the valve device is in an open position, the third locking device (C) can be released by a given pressure difference between the chamber (31) and a pressure at the first or second opening (2,3), so that the second valve body (20) goes to a closed position. 7. Valve device according to one of the above-mentioned claims, characterized in that it comprises a fifth locking device (E) which locks the second valve body (20) permanently in relation to the housing (1) in a closed position. 8. Valve arrangement according to one of the above-mentioned claims, characterized in that the first valve body (11) is arranged relatively within the second valve body (20) and where the first valve body (11) in a closed position closes the second opening (3) and the second valve body (20) in a closed position closes the first opening (2). 9. Valve device according to one of the above-mentioned claims, characterized in that the second valve body (20) is mainly sleeve-shaped and comprises an inflow opening (21) through the sleeve wall for fluid flow. 10. Valve device according to one of the above-mentioned claims, characterized in that the first valve body (11) comprises is mainly cylindrical with a central flow passage (14) with an opening (15) at one end of the cylinder facing the first opening (2) of the valve arrangement and a closed opposite end of the cylinder with openings (13) arranged in a side wall of the cylinder facing the other opening (3) of the valve arrangement. 11. Method for operating a valve between the production pipe and annulus in a well, where the valve comprises a first opening and a second opening characterized in that it comprises the steps of pressurizing fluid in the annulus which is allowed to flow into the valve device until a pressure difference is achieved between annulus pressure and production pipe pressure, so that the second opening of the valve is opened and the valve is locked in this position and fluid is allowed to flow through the valve, after which the fluid in the well is pressurized so that a locking device inside the valve is broken and both the second and first opening are closed.