NO339590B1 - Valve and method for opening and closing a valve - Google Patents

Description

VALVE AND PROCEDURE FOR OPENING AND CLOSING A VALVE

This invention relates to a valve. More specifically, it concerns a valve for use in a sealing device, where the valve comprises a valve housing and an axially displaceable valve slide in the valve housing which is designed to be able to open for pressure equalization or to be closed, with at least one valve opening in the valve slide being designed to be able to be brought between a closed position and an open position where in said open position it communicates with at least one valve opening in the valve housing. The invention also includes a method for opening and closing a valve.

Valves in equipment that are fed into a well pipe are sometimes exposed to unintended stresses from adjacent components. It happens, for example, that valves of this type are damaged by falling objects in the well pipe. It may also happen that, due to particle accumulation, you do not get to the valve mechanism. It also happens that the mechanism gets stuck, for example due to corrosion or accidental foreign objects entering the mechanism. A third case that often occurs in a well pipe where it is expected that there will be large accumulations of foreign particles, often called debris, is that the foreign particles will pack in the valve mechanism during pressure testing. This will often make the valve mechanism become slower or completely locked. In all cases, one is then prevented from being able to operate the valve in the preferred way.

It is known to activate valves using various actuators. When mechanical activation devices are used, it is common to run them in reverse when deactivating valves. For example, an electric actuator during deactivation must be driven with the opposite direction of rotation to that which was used during the activation operation. For various reasons, it may be impossible to maneuver the valve in the intended manner.

From the publication US 2012/0119125, a valve with a valve housing and an axially displaceable valve slide in the housing is known which is designed to be able to open for pressure equalization or closing. The nut/screw connection can be released from the valve housing in connection with assembly or modifications.

From the publication WO 2012/088008, an assembly for operating a valve for controlling flow through a passage is known. The valve comprises a closing element which is movable between a closed position in which the body essentially prevents passage, and an open position. The assembly comprises a movable stem with opposite ends, a first end which can be connected to the closing element, so that displacement of the spindle moves the closing element between open and closed positions.

From the publication US 5046376, a manual operating device is known for use together with a valve or other type of device, to either effect manual regulation of the valve in one direction or to form a barrier against movement of the valve away from one of its end positions.

A valve for use in connection with well plugs where the valve is of the type that is operated with the help of a cable, is usually closed when driving into the well. The valve remains closed until the well plug is pulled, as it is important to equalize the pressure above, for example, the well plug first. Normal operation is then either to apply a force downwards or upwards to compensate for any difference in pressure across the valve. This is often the only way to ensure that the pressure is equalized before the well plug can be pulled. Problems with such a mechanism can lead to greater challenges and further unintended and costly operations.

Valves that cannot be opened in an intentional way, for example due to damage, can cause significant and costly operational disruptions. This is particularly related to valves that are mounted in well plugs where you have to apply mechanical blows upwards to open the valve and pull the plug in the same movement. In wireline operations, especially where mechanical forces are used, it is difficult to say anything about the magnitude of axial forces that are actually applied to the equipment. This is because cable tension and a combination of weights and a mechanical hammer are used. There will then be a potential danger of opening the valve and pulling the plug in one go. If there is then a higher pressure on one of the sides, this could cause operational disturbances as mentioned above.

The purpose of the invention is to remedy or reduce at least one of the disadvantages of known technology.

The purpose is achieved according to the invention by the features indicated in the description below and in the subsequent patent claims.

The invention is defined by the independent patent claims. The independent claims define advantageous embodiments of the invention.

According to a first aspect of the invention, a valve is provided for use in a sealing device where the valve comprises a valve housing and an axially displaceable valve slide in the valve housing which is arranged to be able to open or close for pressure equalization, at least one valve opening in the valve slide being arranged to could be brought between a closed position and an open position where in said open position it communicates with at least one valve opening in the valve housing, and where the valve is characterized by the valve slide being connected to a nut/screw connection which in the use position is axially releasably connected to the valve housing by means of a radially displaceable engagement means located in an opening in a portion of the nut/screw connection and held in an active position in rotatable engagement with a groove in the valve housing by a portion of a valve actuator, the engagement means by means of an axial force applied to the valve actuator, is designed to be able to be operated from the active position where the screw/nut connection is engaged with the valve body, and to an inactive position where the engagement means is out of engagement with the valve body.

When using several valve openings, these can be arranged at a distance from each other in the axial direction and/or in a peripheral direction of the valve.

In this connection, the term "well pipe" covers any pipe or tubular part located in a well, typically a petroleum well, in any phase of the well's life, and where the setting of a sealing device may be appropriate.

Said opening or closing for pressure equalization can be provided by rotating a valve activator which is in rotational engagement with a locking nut which forms part of said nut/screw connection relative to a plug activator, as will be explained in detail in the special part of the application. Depending on the direction of rotation of the valve activator, the valve will be able to be opened and closed repeatedly.

If opening the valve by means of the nut/screw connection, which is usually used for repeated opening and closing of the valve, in a given situation turns out to be not possible or for other reasons is inappropriate, the valve slide can be displaced axially for opening, by the nut/screw connection is released axially in relation to the valve body, by means of displacement produced by applying an axial force to the valve slide via the rotatable valve activator.

The valve activator has a first end part which is enclosed by the plug activator, and a second end part which projects axially from the plug activator.

The first end part of the valve activator is referred to below as the axially inwardly projecting part of the valve activator, or only the inwardly projecting part.

The nut in the screw/nut connection can be a locking nut. As mentioned, the locking nut is held in an axial position relative to the valve body by means of an engagement means which

may include at least one valve block block. Said track can be a brick track. The opening can be arranged in the locking nut. In its active state, the valve blocking block can be held in a radial position by an axially inwardly projecting part (see below) of the valve activator.

The valve activator can be stored in a bearing sleeve and held in axial position in the valve housing by at least one shear pin via the bearing sleeve, where the bearing sleeve and thus the shear pin are not affected by differential pressure which, when the valve is closed, will apply axial forces.

In one embodiment, the locking nut is externally designed with a number of encircling locking grooves, as a locking ring encircling the locking nut in such an embodiment is arranged to be displaceable in one direction along the locking nut. The locking ring is axially locked in the valve housing.

The one-way displaceable locking ring can be arranged to be unable to be displaced back along the lock nut, so that the locking ring prevents the locking nut and thereby the valve slide from being able to be displaced towards the closed position while the valve is displaced towards the open position, even if there should be a differential pressure across the valve which would attempt to close the valve again during opening.

The axially inward projecting part of the valve actuator is designed to lose its engagement with the at least one valve locking block when the valve activator is moved further into the locking nut.

The locking nut and thereby the valve slide can be axially displaceable towards an open position in the valve housing when at least one valve locking block is no longer in radial engagement with the block groove.

According to a second aspect of the invention, there is provided a method for opening and closing a valve according to the first aspect of the invention, where the method comprises displacing the valve slide from a closed position to an open position by displacing a rotatable valve activator axially in the valve housing by means of an applied axial force.

Procedure may further include:

- first displacing the valve activator axially sufficiently so that valve locking blocks arranged in the valve lose their radial engagement with a block groove; and then - to move the valve activator axially together with the valve slide further to the open position of the valve slide.

It is thus possible to open the valve by simply applying to the valve activator an axial force in the direction of the opening direction of the valve, which is sufficiently large to break shear pins arranged in the valve, said shear pins holding the valve activator in position axially, and then a force large enough to displace the valve slide in the valve housing against any differential pressure across the valve that acts against the direction of push.

From the description above, it will be understood that a valve and a method according to the invention enable the release of the valve in a simple way even if the nut/screw connection should be damaged or in some other way could not be used as intended.

In what follows, an example of a preferred method and embodiment is described which is visualized in the accompanying drawings, where: Fig. 1 shows a sealing device during displacement in a well pipe, where the sealing device comprises a valve according to the present invention; Fig. 2 shows the sealing device after it has been activated in the well pipe; Fig. 3 shows a longitudinal section of a gripping device which forms part of the sealing device, where the gripping device is in a passive position; Fig. 4 shows the same as in fig. 3, but in activated position; Fig. 5 shows details from the gripping device; Fig. 6 shows a perspective view of a section III-III in fig. 3; Fig. 7 shows a longitudinal section of a sealing element which forms part of the sealing apparatus; Fig. 8 shows a longitudinal section of the sealing device's centering device in passive position; Fig. 9 shows the same as in fig. 8, but where the centering device is being activated; Fig. 10 shows the same as in fig. 8, but where the centering device is activated; Fig. 11 shows a longitudinal section of the sealing device's activation device and a release device in its initial position; Fig. 12 shows the same as in fig. 11, but after the activation device has been pulled, and where the release device has also been activated; Fig. 13 shows in perspective a section XI-XI in fig. 11; Fig. 14 shows in perspective a section XV-XV in fig. 15; Fig. 15 shows a longitudinal section of the valve of the sealing device according to the present invention, where the valve is in the closed position; Fig. 16 shows the same as in fig. 15, but where the valve is in an intermediate position;

Fig. 17 shows the same as in fig. 15, but where the valve is open; and

Fig. 18 shows the valve in fig. 15, but where it is opened in an alternative way.

In the drawings, reference number 1 denotes a sealing device placed in a well pipe 2.

Apparatus 1 comprises a radially movable gripping device 4, a radially movable sealing element 6, a radially movable centering device 8, an axially movable activation device 10, a release device 12 and a valve 14 according to the present invention. The activation device 10, the release device 12 and the valve 14 are located in the housing 16 of the device 1 and are therefore not shown in fig. 1 or 2. The design and operation of these will be explained below. Each of the gripping device 4, the sealing element 6 and the centering device 8 is radially movable between a passive, retracted position and an active, extended position relative to a central axis 22 of the apparatus 1.

The housing 16 is composed of several components which are described in detail in the following. The housing 16 is provided with a counterhold 18, i.e. a force counteracting anchoring device, which is arranged to be able to accommodate both torsional and axial forces. The abutment 18 is designed with a fish neck 20 of a design known per se. An activator 24 which is rotatable about the central axis 22 of the device 1 projects axially and centrically from the abutment 18, while a valve activator which is rotatable about the central axis 22 projects axially and centrically from the activator 24.

In fig. 1 is a setting device 28 connected to the stop 18. The setting device 28 comprises an actuator 30 which is designed to be able to turn the activator 24 in any direction of rotation about the central axis 22, whereby the activator 24 can be moved in an axial direction along the central axis 22.

During axial displacement of the device 1 into the well pipe 2 by means of the setting device 28, the device 1 can be in an off-centered position in the well pipe 2, such as

indicated in fig. 1.

When the device 1 is to be set, the gripping device 4 and the centering device 8 are activated towards their active, extended positions before the sealing element 6 is brought out into its active,

extended position. This is achieved by turning the activator 24 in a corresponding direction of rotation. In their active, extended positions, the gripping device 4, the sealing element 6 and the centering device 8 are in contact with an inside of the well pipe 2. Thereby, the device 1 is centered in the well pipe 2, whereby it is ensured that the sealing element 6 comes into the correct position in the well pipe 2 when the activator 24 is turned further in the same plug set-end direction, see fig. 2.

It is advantageous if the centering device 8 is activated at least partially before the gripping device 4 is activated. The reason for this is that the gripping device 4, when activated and attached to the inside of the well pipe 2, will be able to prevent the centering device 8 from moving the plug 1 to a centered position in the well pipe 2.

In one embodiment (not shown), the centering device 8 is activated at least partially before or while the apparatus 1 is introduced into the well pipe 2.

Grip device 4, see fig. 3 to 6, comprises a number of radially movable and wedge-shaped

gripping bodies 36, five gripping bodies 36 shown in fig. 6, which is distributed around the central axis 22. In the embodiment shown, part of the outer surface of the gripping bodies 36 is designed with teeth 38 which are arranged to be able to engage with the well pipe 2 when the gripping bodies are pressed against the inside of the well pipe 2. The well pipe 2 is only shown in fig. 1 and 2. On their radial inside, the gripping bodies 36 abut against a device 40, 42, here shown as two wedge cones 40, 42. In what follows, the wedge cone 40 will be referred to as the first wedge cone 40 and the wedge cone 42 as the second wedge cone 42.

The first wedge cone 40 is attached by means of a guide nut 46 to a leading end part of a (in the apparatus 1) centrally located spindle 44. The gripping bodies 36 are biased towards their passive position by means of springs 48, here in the form of spiral springs, see fig . 3 and 6. The spindle 44 and the guide nut 46 transmit the axial displacement of the activation device 10, among other things, to the gripping device 4. The spindle 44 and the guide nut 46 can therefore, in this design example, be considered to be part of the activation device 10.

The second wedge cone 42, which is displaceably arranged along the spindle 44, is limited axially displaceable in relation to a first housing part 50, which forms part of the housing 16. An intermediate ring 52 divided into segments is attached to the first housing part 50 and is provided with internal annular grooves 54 in which a flange-shaped ridge 56 to the second wedge-

cone 42 is displaceably arranged.

The intermediate ring 52 has several inclined surfaces 58, each of which rests against a ball 60. Each ball 60 spans by means of a spring 62 against a radially displaceable gripper stop 64 which thereby rests against the spindle 44. The gripper stop 64 is provided with sawtooth-shaped detent teeth 66 which complementarily fit in sawtooth-shaped detents 68 on the spindle 44. The gripper detent 64 engages with the spindle 44 when the spindle 44 is shifted to a position where the detent teeth 66 on the detent 64 correspond to the detent teeth 68 on the spindle 44.

The gripper 64 is provided on two opposite sides with inclined grooves 70 which fit into guides 72 in the intermediate ring 52, see fig. 5.

Each gripping body 36 is assigned four return arms 74 which are rotatably attached to the first wedge cone 40 and the second wedge cone 42, respectively, and which extend into gripping grooves 76 in the gripping body 36. The return arms 74 are designed to be able to pull the gripping body 36 out of engagement with the well pipe 2 .

Between each gripping body 36 is arranged an elongated segment 78 which is attached to the first wedge cone 40 by means of the guide nut 46, and which is displaceably arranged in relation to the first housing part 50. The elongated segment 78 can for example be a leaf spring. At the first housing part 50, the elongated segment 78 is held in position by means of a segment sleeve 80 which also holds the segmented intermediate ring 52 in position. The segment sleeve 80 is arranged to be able to hold the divided intermediate ring 52 in position on the first housing part 50.

When the spindle 44 is displaced in the direction of the first housing portion 50, the intermediate ring 52 is first displaced closer to the second wedge cone 42. The ball 60 is displaced radially inward by the inclined surface 58, whereby the bias against the gripper 64 is increased.

When the spindle 44 is displaced further in the direction of the first housing portion 50, the first wedge cone 40 and the second wedge cone 42 are displaced in opposite directions, whereby the gripping bodies 36 are displaced radially outwards and into engagement with the well pipe 2. At the same time, the locking teeth 66 of the gripping device 64 engage with the spindle 44 ratchet teeth 68.

The gripping device 4 is thereby prevented from detaching from the well pipe 2 even if the axial force in the spindle 44 should be reduced or disappear. The reason was that the sawtooth-shaped locking teeth 64, 66 must be pulled apart in order to release.

It is nevertheless possible to release the gripping device 4 from the well pipe 2 by pulling on the housing 16. Typically, a pulling or fishing tool, not shown, is attached to the fish neck 20, after which a tensile force is applied to the housing 16 and thereby also to the first housing part 50.

There is thereby a limited displacement of the intermediate ring 52 in the direction away from the second wedge cone 42. The guides 72 of the intermediate ring 52, which rest against the groove 70 of the gripper 64, thereby pull the gripper 64 out of its engagement with the spindle 44. Further displacement of the housing 16 in direction away from the gripping device 4 causes the return arms 74 and the springs 48 to pull the gripping bodies 36 out of their engagement with the well pipe 2 and further into their passive positions.

In fig. 7 shows a longitudinal section of the sealing device 6. An elastic sealing element 86 is arranged on a sealing boss 88 belonging to the first housing part 50. The sealing boss 88 protrudes displaceably into a bore 90 in a second housing part 92 and is prevented from slipping out of the second housing part 92 of a nut 94 which abuts against a parapet 96 in the bore 90.

The sealing element 86 is activated in a manner known per se by displacing the first housing part 50 and the second housing part 92 towards each other, here by means of the spindle 44 which is provided with an axial, through bore 98.

The centering device 8 comprises a number of double, articulately connected joint arms 100, here five joint arms 100, each of which is arranged to be able to be moved from its passive position as shown in fig. 8, and to its active, extended position as shown in fig. 10.

Each of the joint arms 100 comprises a first joint arm 102 which is attached to a joint locking sleeve 104 by means of a joint connection, and a second joint arm 106 which is attached to a sliding sleeve 108 by means of a joint connection.

The joint lock housing 104 is firmly connected to the second housing part 92 by means of fastening elements, not shown, which in one embodiment can be screws. The sliding sleeve 108 is limited displaceable in a bore 110 in a third housing part 112.

Springs 114, here in the form of disc springs, tension the slide sleeve 108 in the direction of the joint lock sleeve 104, but are prevented from being able to slide out of the bore 110 by a nut 116.

Joint lock cover Isen 104 is designed with external lugs 118. The sliding sleeve 108, which is limited in displacement relative to the joint lock sleeve 104, is provided with internal lugs 120. The outer lugs 118 and the internal lugs 120 are designed to be able to abut against each other. Both the joint lock sleeve 104 and the sliding sleeve 108 are displaceably arranged on the spindle 44.

A joint lock body 122, which is radially displaceable in a guide opening 124 in the joint lock sleeve 104, is in its initial position in engagement with an annular groove 126 in the spindle 44, as shown in fig. 8. Together with other joint lock bodies not shown which are arranged about a central axis 22, the joint lock body 122 is prevented from coming out of engagement with the spindle 44 before the joint lock body 122 corresponds with an annular, internal release groove 128 in the third housing portion 112.

In fig. 9, the spindle 44 is pulled to an axial stop against the joint locking body 122. The second housing part 92, and thereby the joint locking sleeve 104, is displaced somewhat in the direction of the sliding sleeve 108, but not sufficiently so that the joint locking body 122 can be displaced out into the release groove 128. This displacement between the other housing part 92 and the third housing part 112, cause the articulated arms 100 to be displaced somewhat towards their active positions.

The spindle 44 is prevented from being able to move further relative to the joint lock sleeve 104, and thereby relative to the second housing part 92. In this embodiment, this means that the centering device 8 must be activated towards its active position before the gripping device 4 (see fig. 3 and 4) and the sealing device 6 (see fig. 7) can be activated towards their respective active positions.

When the spindle 44 is displaced sufficiently far relative to the third housing part 112, as shown in fig. 10, the joint locking body 122 is displaced radially out into the release groove 128. The spindle 44 is thereby freed from the joint locking body 122 and can thereby be displaced further in the direction of the third housing part 112.

In this position, the joint locking body 122 is prevented from being displaced from the release groove 128. The centering device 8 is thereby held in its active, extended position. The centering device 8 cannot be released until the ring groove 126 in the spindle 44 has been moved back to the joint locking bodies 122, that is when the ring groove 126 corresponds axially with the joint locking body 122.

If the joint arms 100 are prevented from being able to be fully displaced to their activated and extended positions, the springs 114 are tensioned while the sliding sleeve 108 is displaced somewhat in the bore 110.

From the description above, it will therefore be understood that the centering device 8 is provided with a joint locking body 122 which is directly or indirectly in conditional, blocking engagement with the activation device 10; when the joint lock body 122 is in conditional engagement with the spindle 44, it is dependent on it not being engaged with the housing with which it may be engaged in another state.

The activation device 10 and trigger device 12 of the device 1 are shown in fig. 11-13.

A spline nut 136 is displaceably arranged in the third housing part 112 and is provided with external splines 138 which complementarily fit into internal splines 140 in the third housing part 112. The spline nut 136 is firmly connected to the spindle 44.

The activator 24, which projects into the third housing part 112, is provided with an external thread 142 which fits with an internal thread 144 in the spline nut 136. A cylindrical part 146 of the activator 24 protrudes displaceably and sealingly into the through bore 98 of the spindle 44 .The activator 24 is also designed with a through centric bore 148.

The activator 24 is, by means of a number of protruding bearing flanges 150, stored in a bearing sleeve 152. The bearing sleeve 152, which forms a suspension part 153, is internally provided with annular bearing surfaces 154 which rest against the bearing flanges 150.

The bearing sleeve 152 is held in axial position in the third housing part 112 by means of a number of release blocks 156, here eight release blocks 156. Each release block 156 has a toothed surface 158 which faces the bearing sleeve 152, and which fits against teeth 160 on the bearing sleeve 152.

A fourth housing part 162, which is attached to the abutment 18, surrounds the release device 12. The housing 16 and the activator 24 constitute equipment components 163.

The eight trigger blocks 156 are arranged around the central axis 22, as shown in fig. 13, where the fourth house lot 162 is not shown.

When the device 1 is to be activated, the activator 24 is rotated about the central axis 22. The activator 24 is supported in the bearing sleeve 152 and thereby pulls the spline nut 136, which is prevented from turning in the third housing part 112, and the spindle 44 in the axial direction towards the activator 24. If the activator 24 is turned in the opposite direction, the spline nut 136 and the spindle 44 are displaced in the axial direction away from the activator.

During displacement of the activator 24 relative to the spindle 44, the cylindrical part 146 is displaced axially in the bore 98.

The third housing part 112 and the fourth housing part 162 are secured to each other by means of breaking bolts, which are referred to below as release bolts 164. Release bolts 164 are shown in fig. 13, while their axial positions in the third housing portion 112 are indicated by bolt center lines 166 in FIG. 11 and 12.

The third housing part 112 and the fourth housing part 162 are prevented from being completely separated by a ring nut 168 which is threaded to the fourth housing part 162, and which is arranged to be able to abut against a parapet 170 which encircles the third housing part 112, see fig. 11 and 12.

If the third housing part 112 and the fourth housing part 162 are displaced in the axial direction from each other, the release blocks 156, which normally support the inside against the fourth housing part 162, will be able to be displaced radially outwards and into the release groove 172 in the fourth housing part 162. The release blocks 156 then lose the engagement in the bearing sleeve 152, whereby the bearing sleeve 152 with the activator 24 and the spline nut 136 can be displaced axially in the third housing part 112 without having to turn the activator 24.

If it becomes necessary to release the device 1 in a different way than by turning the activator 24, a pulling tool (not shown) can be connected to the fish neck 20, which is fixed in the fourth housing part 162, and then pull the fourth housing part 162 up to the release bolts 164 is broken. The aforementioned axial displacement between the third housing part 112 and the fourth housing part 162 can then take place.

The house 16 also consists of the first, second, third and fourth house lot 50, 92, 112, 162.

The valve 14, see fig. 14-18, is arranged inside the activator 24, which then forms a valve housing 173.

A valve slide 180 is externally provided with two outer seals 182 which are arranged to be able to provide a seal between the valve slide 180 and the activator 24. An intermediate seal 184 is designed to be able to regulate a flow rate through the valve 14.

Valve openings 186 in the valve slide 180 are closed in relation to valve openings 188 in the activator 24 and in the fourth housing part 162 when the valve 14 is in the closed position, as shown in fig. 15.

The valve slide 180 is designed with an axially extending screw spindle 190 which extends centrically in the direction from a valve bore 178. The screw spindle 190 is also provided with longitudinal grooves 192 which fit inside an externally splined counter retaining plate 194. The counter retaining plate 194, which is arranged to be able to prevent the screw spindle 190 can be rotated relative to the activator 24, fits axially displaceably in internal complementary splines 196 in the activator 24.

A locking nut 198 is screwed onto the screw spindle 190. The screw spindle 190 and the locking nut 198 make up the screw/nut connection 199. The locking nut 198 is externally provided with a series of encircling locking grooves 200. A locking ring 202 is arranged to be able to engage with the locking grooves 200 to thereby prevent or to prevent the locking nut 198 from being displaced axially in the direction away from the counter retaining plate 194.

The valve activator 26 is stored in a bearing sleeve 204 in the activator 24. The valve activator 26 is held axially in position via the bearing sleeve 204, which is connected to the activator 24 by means of a number of shear pins 206 in the form of breaking screws 206, see fig. 14.

In its radially outer end part, in the subsequently also called inward projecting part 208, the valve activator 26 is in an axially displaceable rotational engagement with the lock nut 198. A number of valve lock blocks 210 are arranged in corresponding radial openings 212 in the lock nut 198. By means of the valve activator 26's inward projecting part 208, the valve locking blocks 210 are held in position in a block groove 214 in the activator 24.

By rotating the valve activator 26 relative to the activator 24, the valve can be opened and closed repeatedly. The valve stop colossus 210 remains in and rotates in the block groove 214 at the same time as the valve slide 180 is displaced axially back and forth in the activator 24 depending on the direction of rotation of the valve activator 26 relative to the activator 24.

In fig. 16, the valve 14 is shown in an intermediate position where the relative position of the intermediate seal 184 in the valve housing 180 determines the flow rate through the valve 14.

In fig. 17, the valve 14 is shown in the open position where the opening 186 of the valve slide 180 is aligned with the opening 188 of the valve housing 173 so that fluid communication is provided between the valve bore 178 and the surroundings of the device 1.

Should it be necessary to bring the valve 14 from the closed to the open position without turning the valve activator 26, a pressure force can be assigned to the valve activator 26 in the axial direction towards the valve 14, so that the shear pins or breaking screws 206 are broken. The valve activator 26, with the associated inwardly projecting part 208, can thereby be displaced somewhat into the locking nut 198. The inwardly projecting part 208 thereby no longer blocks the valve blocking blocks 210. The valve blocking blocks 210 are displaced axially out of the block groove 214 and into the recess 209 in the valve activator 26 outer surface, after which the valve slide 180 can be moved axially to its open position, see fig. 18.

The engagement of the locking ring 202 against the locking nut 198 prevents the valve slide 180 from being displaced axially towards the closed position even if there is an overpressure inside the valve slide 180.

If the pressure is greatest above the valve 14 relative to the orientation of the well, the pressure helps to push the valve slide 180 towards the open position. By above here is meant up towards the surface as well as towards the top of the device or the plug 1. If the pressure is greatest below the valve 14, the pressure seeks to displace the valve slide towards the closed position. The locking ring 202 prevents the valve slide 180, even if it is in an intermediate position, from being able to move towards the closed position. The retaining ring 202 also prevents nearby components such as the valve retainer blocks 210 from being able to fall out.

It should be noted that all of the above embodiments illustrate the invention, but do not limit it, and those skilled in the art will be able to devise many alternative embodiments without departing from the scope of the dependent claims. In the requirements, reference numbers in parentheses should not be seen as limiting. The use of the verb "to comprise" and its various forms does not exclude the presence of elements or steps not mentioned in the claims. The indefinite articles "an", "ei" or "et" before an element do not exclude the presence of several such elements.

Claims (9)

1. Valve (14) for use in a sealing device (1) where the valve comprises a valve housing (173) and an axially displaceable valve slide (180) in the valve housing (173) which is designed to be able to open for pressure equalization or closing, with at least one valve opening (186) in the valve slide (180) is arranged to be able to be brought between a closed position and an open position where in said open position it communicates with at least one valve opening (188) in the valve housing (173), characterized in that the valve slide (180) is connected to a nut/screw connection (199) which in the use position is axially releasably connected to the valve housing (173) by means of a radially displaceable engagement means (210) located in an opening (212) in a part of the nut/screw connection (199) and which in an active position is held in rotatable engagement with a slot (214) in the valve housing (173) by a portion of a valve activator (26), the engagement means (210) being aligned by means of an axial force applied to the valve activator (26) to to know is driven from the active position where the screw/nut connection (199) is in engagement with the valve body (173), and to an inactive position where the engagement means (210) is out of engagement with the valve body (173). 2. Valve according to claim 1, where the nut in the screw/nut connection (199) consists of a locking nut (198). 3. Valve according to claim 2, where the engagement means comprises at least one valve blocking block (210), where the slot is a block slot (214), where the opening (212) is arranged in the locking nut (198), and where the valve blocking block (210) in its active state is held in radial position by an axially inward projecting portion (208) of the valve actuator (26). 4. Valve according to claim 3, where the valve activator (26) is stored in a bearing sleeve (204) and is held in axial position in the valve housing (173) by at least one shear pin (206) via the bearing sleeve (204). 5. Valve according to claim 2, where the locking nut (198) is externally designed with a number of encircling locking grooves (200), with a locking ring (202) encircling the locking nut (198) being displaceable in one direction along the locking nut (198). 6. Valve according to claim 3, where the inward projecting part (208) of the valve activator (26) is designed to come out of its blocking position with the at least one valve locking block (210) when the valve activator (26) is moved further into the locking nut (198) ). 7. Valve according to claim 3, where the locking nut (198), and thereby the valve slide (180), is displaceable towards the open position in the valve housing (173) when at least one valve locking block (210) is no longer in engagement with the block groove (214) . 8. Method for opening a valve (14) according to claim 1, characterized in that the method comprises displacing the valve slide (180) from a closed position to an open position by displacing a rotatable valve activator (26) axially in the valve housing (173) by means of an applied axial force. 9. Method according to claim 8, where the method comprises: - first displacing the valve activator (26) sufficiently so that valve locking blocks (210) can lose their engagement in a block groove (214); and then - to move the valve activator (26) together with the valve slide (180) further to the open position of the valve slide (180).