The present invention relates to a downhole tool for removing a restriction in a well tubular metal structure having a wall, a tool axis and an inner diameter, the restriction partly blocking the inner diameter, creating an opening defined at least partly by a rim section of the restriction.
Downhole intervention tools are used in an existing well for drilling out a restriction in the casing, e.g. reboring a stuck valve.
Occasionally, a downhole valve which has been closed for some time gets stuck, due to corrosion or the like, and thus cannot be reopened with the usual equipment. In such situations, drilling out part of the stuck valve is the only solution in order to gain full access therethrough and thus regain a full-bore casing. When reboring the stuck valve, the drill bit tends to slide on the abutting surface, especially if the valve is a ball valve, and thus the drill bit has a pilot bit in the centre, and the cut-out part of the stuck valve is also retrieved with the drill bit by means of the pilot bit, such as known from EP2314825. However, sometimes the valve gets stuck when being half-closed/opened, resulting in an opening across the centre, and then a pilot bit can no longer be used for avoiding sliding and for retrieving the cut-out part of the valve after the drilling operation has been completed. Furthermore, the cut-out part of the valve can also not be retrieved from the well.
It is an object of the present invention to wholly or partly overcome the above disadvantages and drawbacks of the prior art. More specifically, it is an object to provide an improved downhole tool which is able to retrieve a restricting part of a half-closed valve or other damaged component from the well to regain access to the well below the valve.
The above objects, together with numerous other objects, advantages and features, which will become evident from the below description, are accomplished by a solution in accordance with the present invention by a downhole tool for removing a restriction in a well tubular metal structure having a wall, a tool axis and an inner diameter, the restriction partly blocking the inner diameter, creating an opening defined at least partly by a rim section of the restriction, comprising:
wherein the second part of the downhole tool further comprises:
the locator and the collecting means are rotating with the core bit until the locator locates the rim section and a threshold value is reached.
By having the locator and the collecting means rotating with the core bit until the locator locates the rim section of the restriction and a threshold value is reached, the locator can enter the opening of e.g. a half-closed valve, and the collecting means also entering the opening can fasten the cut-out part of the restriction so that the cut-out part is brought to surface along with the tool after the operation has ended. The cut-out part may obstruct the well tubular metal structure, and it is therefore important that it is removed along with the tool and does not remain in the well. Thus, the downhole tool is able to cut out the part of the valve restricting access to the well and retrieve this part of the half-closed valve from the well to regain access to the well below the valve.
The core bit rotates during the cutting operation and creates a cut along its circumference, and the locator and the collecting means stop rotating when the locator is prevented from rotation by the restriction.
By “cutting” is also meant milling out part of a restriction, e.g. a valve or similar damaged component in the well. The milling process is an abrasive process.
The core bit may have a centre axis coincident with the tool axis.
Moreover, the locator and the collecting means may be rotating with the core bit in a first condition, and in a second condition the locator and the collecting means may stop rotating with the core bit.
Also, the locator and the collecting means may be rotating with the core bit in a first condition, and in a second condition the locator and the collecting means may be prevented from rotating with the core bit by the rim section of the restriction.
In addition, the locator and the collecting means may be rotating with the core bit in a first condition, and in a second condition where the locator contacts the rim section the locator and the collecting means may stop rotating with the core bit.
Furthermore, the locator and the collecting means may be connected with the core bit until a predetermined force is reached, i.e. a threshold value is reached, between the locator and the core bit.
Also, the locator and the collecting means may be releasably connected with the core bit.
Additionally, the locator and the collecting means may be connected with the core bit by a frictional force, and the locator and the collecting means may be disconnected from the core bit when the locator is prevented from rotating with the core bit, overcoming the frictional force. The locator is prevented from rotating when the locator hits against the rim section of the opening.
Moreover, in a first condition the core bit may be configured to rotate mutually with the locator and the collecting means, and in a second condition the core bit may be configured to rotate relatively to the locator and the collecting means.
Further, the second condition may be activated when the locator contacts the rim section of the restriction.
Also, the core bit may have a centre axis, and the locator is arranged radially offset from the centre axis.
Furthermore, the core bit may have a centre axis, and the locator may be arranged off-centre from the centre axis.
In addition, the core bit may have a centre axis, and the locator may have a locator axis, which locator axis may be arranged off-centre from the centre axis.
Also, the core bit may have a centre axis, and the locator may have a locator axis which is arranged at a distance in a radial direction away from the centre axis.
By having the locator arranged radially offset from the centre axis, the locator is able to locate the opening of e.g. the half-closed valve and thus guide the collection means into the opening in order to be able to retrieve the cut-out part of the restriction. The opening of a partly closed valve often does not overlap the centre of the core bit, and by arranging the locator off-centre from the centre of the core bit, the locator is thus able to locate the rim section of the opening even if the opening does not overlap the centre of the tool and the centre of the core bit. The same applies when the locator is arranged off-centre from the centre axis, or when the locator has a locator axis which is arranged at a distance in a radial direction away from the centre axis.
In addition, the locator and the collecting means may be arranged within the core bit.
Furthermore, the second part may comprise a base part and a spring arranged between the locator and the base part so that the locator compresses the spring when moving along the tool axis towards the first end of the core bit.
Moreover, the locator may be moved along the tool axis by the restriction when the core bit moves along the tool axis and cuts into the restriction.
The locator has a first condition in which the locator is in its extended position and a second condition in which the locator has moved in relation to the core bit by an external force such as from contacting the restriction. Hereby, the locator compresses the spring as the locator is forced by the external force to move towards the first end of the core bit along the tool axis.
Also, the spring may have an extension along the tool axis.
Additionally, the locator and the collecting means may be fixedly connected.
Furthermore, the locator and the collecting means may be fixedly connected for guiding the collection means in through the opening arranged off-centre from the tool axis.
Moreover, the locator and the base part may be fixedly connected.
In addition, the core bit may comprise a ball bearing arranged between the core bit and the base part.
Further, the core bit may be connected with the locator by means of a fastening means, such as a coupling, a shear part or a spring-loaded pin, until the threshold value is reached.
Also, the coupling may be a friction coupling or a torque coupling.
Moreover, the coupling may be arranged between the base part and the core bit.
Additionally, the fastening means may be arranged between the base part and the core bit.
Furthermore, the core bit may have an indentation for receiving the spring-loaded pin.
In addition, the core bit may have a centre axis, the collecting means being arranged radially offset from the centre axis.
Also, the collecting means may comprise at least one bendable part for engaging the cut-out part of the restriction.
Moreover, the collecting means may comprise at least one expandable/projectable part for being expanded/projected when passing the opening for supporting the cut-out part of the restriction so that it is held in place between the core bit and the expandable/projectable part.
Additionally, the collecting means may have a radial extension being larger than that of the opening.
Further, the locator may project from the cutting edge along the tool axis. In that way, it is easier to apply a force on the locator and reach the threshold value to release the locator from the core bit.
In addition, the locator may have a first locator end connected with the core bit and a second locator end having a tapering shape.
Furthermore, the collecting means may extend radially from the locator.
The downhole tool may further comprise a gearing section connected between the electrical motor and the rotatable shaft for reducing the rotation of the core bit in relation to the rotational output of the motor.
Also, the downhole tool may further comprise an axial force generator providing an axial force along the tool axis.
Moreover, the axial force generator may be arranged in the first part for moving the second part along the tool axis.
The downhole tool may further comprise an anchoring tool section for preventing the tool from rotating within the casing.
Further, the anchoring tool section may comprise projectable anchoring elements.
In addition, the downhole tool may further comprise a driving unit, such as a downhole tractor, for preventing the tool from rotating within the casing and for providing an axial force along the tool axis.
Furthermore, the downhole tool may be a wireline tool, i.e. a downhole wireline tool.
Additionally, the driving unit may comprise a second motor driving a second pump for rotating wheels and projecting arms onto which the wheels are arranged.
Finally, the downhole tool may comprise a compensator for providing a surplus pressure inside the downhole line separation tool.
The invention and its many advantages will be described in more detail below with reference to the accompanying schematic drawings, which for the purpose of illustration show some non-limiting embodiments and in which:
All the figures are highly schematic and not necessarily to scale, and they show only those parts which are necessary in order to elucidate the invention, other parts being omitted or merely suggested.
The downhole tool 1 shown in
By having the locator and the collecting means rotating with the core bit until the locator locates the rim section and a threshold value is reached, the locator can enter the opening, and the collecting means can fasten the cut-out part of the restriction so that the cut-out part is brought to surface along with the tool after the operation has ended. The cut-out part may obstruct the well tubular metal structure, and it is therefore important that it is removed along with the tool and does not remain in the well. Thus, the downhole tool is able to cut out the part of the valve restricting access and retrieve part of the half-closed valve from the well to regain access to the well below the valve.
As shown in
By having the locator arranged radially offset from the centre axis, the locator is able to locate the opening of the half-closed valve and thus guide the collection means into the opening in order to be able to retrieve the cut-out part of the restriction. The opening of a partly closed valve often does not overlap the centre of the core bit, and by arranging the locator off-centre from the centre of the core bit, the locator is thus able to locate the rim section of the opening. The same applies when the locator is arranged off-centre from the centre axis, or when the locator has a locator axis which is arranged at a distance in a radial direction away from the centre axis.
The locator has a first locator end 28 connected with the core bit and a second locator end 29 having a tapering shape. When the second locator end 29 of the locator 15 hits against the rim section 6 (shown in
Thus, by having the locator arranged radially offset from the centre axis, the downhole tool is able to cut out part of the restriction and bring the cut-out part to surface along with the tool, even though the valve is only half-closed.
The locator 15 and the collecting means 16 arranged within the core bit 10 are fixedly connected in
In
The indentation 39 engages with the spring-loaded pin 25 in
The core bit 10 has a centre axis L2 coincident with the tool axis L, as shown in
In
The collecting means 16 extends radially from the locator 15 as shown in
The collecting means 16 may extend radially all the way around the locator 15 as shown in
In
As shown in
In another embodiment, the second locator end 29 of the locator has a tapering shape so as to guide the locator into the opening. The collecting means 16 could thus also be this tapering-shaped end as this end could be squeezed in between the rim section and the core bit as the core bit moves and cuts further into the restriction. The spring between the base part and the locator is thus designed to be able to be compressed accordingly so that the core bit is able to keep moving and rotating until the restriction is fully cut, separating the cut-out part 36.
When rotating, the core bit 10 cuts out a part of the restriction which occupies the space within the core bit, and the cut-out part prevents fluid within the core bit from escaping from the second end 12 of the core bit 10, and as the cut-out part moves towards the first end 11, it may displace the fluid within the space and out through apertures 45 in the first end 11, as shown in
In
The downhole tool 1 further comprises an axial force generator 33 providing an axial force along the tool axis while rotating the core bit 10. The axial force generator is arranged in the first part 17 for moving the second part 18 in relation to the first part along the tool axis L. In order to transfer all the rotation of the motor to the core bit, the downhole tool 1 further comprises an anchoring tool section 32 for preventing the tool from rotating within the casing. The anchoring tool section comprises projectable anchoring elements.
In
As can be seen in
In another embodiment, the downhole tool may also comprise a second pump and an accumulating section for suction of shavings from the cutting process and into the accumulating section through the apertures 45 (shown in
An axial force generator may be a stroking tool and is a tool providing an axial force. The stroking tool comprises an electrical motor for driving a pump. The pump pumps fluid into a piston housing to move a piston acting therein. The piston is arranged on the stroker shaft. The pump may pump fluid into the piston housing on one side and simultaneously suck fluid out on the other side of the piston.
By “fluid” or “well fluid” is meant any kind of fluid that may be present in oil or gas wells downhole, such as natural gas, oil, oil mud, crude oil, water, etc. By “gas” is meant any kind of gas composition present in a well, completion or open hole, and by “oil” is meant any kind of oil composition, such as crude oil, an oil-containing fluid, etc. Gas, oil and water fluids may thus all comprise other elements or substances than gas, oil and/or water, respectively.
By “casing” or “well tubular metal structure” is meant any kind of pipe, tubing, tubular, liner, string, etc., used downhole in relation to oil or natural gas production.
In the event that the tool is not submergible all the way into the casing (by gravity), a driving unit such as a downhole tractor can be used to push the tool all the way into position in the well. The downhole tractor may have projectable arms having wheels, wherein the wheels contact the inner surface of the casing for propelling the tractor and the tool forward in the casing. A downhole tractor is any kind of driving tool capable of pushing or pulling tools in a well downhole, such as a Well Tractor®.
Although the invention has been described above in connection with preferred embodiments of the invention, it will be evident to a person skilled in the art that several modifications are conceivable without departing from the invention as defined by the following claims.
Number | Date | Country | Kind |
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20165642.8 | Mar 2020 | EP | regional |