The invention relates to the field of drilling.
The invention more particularly relates to the cementing of a casing within a well bore.
The invention can be applied especially to petroleum, gas or geothermal wells.
After the drilling of a well bore, such as a petroleum well, a casing or liner is run down into the unfinished well bore and the annulus between the external wall of the casing. The internal wall of the well is then cemented throughout its height or on a part of its height.
The cementing of the annulus is aimed especially at:
The evolution of cementing quality over time depends on the initial quality of the cementing and especially on the phase of solidification of the cement once this cement has been injected into the annulus.
Once solidified, the cement placed in the annulus is subjected to numerous stresses (temperature, expansion of the casing, pressure in the well etc) throughout the service life of the well.
Over time, defects in the cementing can also arise. Examples of these are the appearance of cracks, the formation of a micro-annulus at the casing/cement interfaces (due to a loss of adhesion of the annulus with the cement) and/or cement/formation interfaces. The deterioration of the cementing over time can lead to leakages of gas towards the surface because the cement is no longer capable of coping with high pressures. This is not desirable.
The present invention is aimed at providing a solution to the shortcomings of prior-art cementing techniques.
Thus, the invention relates to a device for cementing a casing in a well bore.
According to the invention, the cementing device comprises:
on the well head side, shutter means, disposed within the casing, that control the opening and closing of at least one cementing aperture, said at least one cementing aperture making the interior of the casing communicate with the annular space situated between the external face of the casing and the internal wall of the well,
on the well bottom side, a packer mounted along the external face of the casing, comprising:
The cementing device of the invention implements shutter means within the casing which command both the opening and the closing of one or more cementing ports for the annulus and one or more expansion ports of a packer, this packer being situated on the casing downstream (i.e. towards the bottom of the well) from the shutter means and having a structure with two expandable liners.
The shutter means are shifted sequentially so that, in a first phase, they enable the radial expansion of the two expandable liners and the tight-sealed application of the external liner against the wall of the well, and then in a second phase, the cementing of the annulus situated between the external face of the casing and the internal wall of the well.
The implementing of a structure with two expandable liners is advantageous in that it enables optimal tight sealing between the external surface of the casing and the internal surface of the drill-hole so that in particular, the cementing operation in the annulus part situated upstream to the liners is done efficiently.
This structure is furthermore efficient and robust. Even in the event of a collapse of the internal liner, the external liner remains applied in a tightly sealed manner against the internal surface of the drill-hole, ensuring the perennial nature of the isolation and preventing fluids/gases from rising in the cemented annulus towards the surface.
Nor does this structure need to be maintained in an expanded form under pressure, thus eliminating any problem of leakage of pressure.
In short, the application of a structure with two expandable liners in the device of the invention meets several goals:
It protects the cement situated in the annulus during the solidification phase but also in the long term, under harsh conditions.
The cementing device of the invention is particularly well suited but not exclusively suited to the staged cementing (i.e. cementing in several steps) of a well.
According to one particular aspect of the invention, said at least one communication passage consists of a hole placed on the wall of said first external liner and leading into the part of said annular volume that extends between the two liners.
According to one particular aspect of the invention, the shutter means are axially mobile within the casing and can take a first position in which they close, at the same time, said at least one cementing aperture and said at least one expanding aperture, a second position in which they close said at least one cementing aperture and open said at least one expanding aperture and a third position in which they open, at the same time, said at least one cementing aperture and said at least one expansion aperture.
According to one particular aspect of the invention, there is a communication of fluid between the part of said annular volume that extends between the casing and the second internal liner and the annular space situated above the packer, between the external face of the casing and the internal wall of the well, when the mobile shutter means are in said first position in which they close, at the same time, said at least one cementing aperture and said at least one expansion aperture.
According to one particular aspect of the invention, the shutter means comprise at least one rupture disc closing at least one expansion aperture.
According to one particular aspect of the invention, the shutter means are affixed temporarily on the internal wall of the casing in the first position by at least one breakable retaining element.
According to one particular aspect of the invention, the shutter means comprise two shutter sleeves that are axially mobile within the casing.
According to one particular aspect of the invention, one of said two shutter sleeves is temporarily fixed to the internal wall of the casing in the second position by at least one breakable retaining element.
According to one particular aspect of the invention, the shutter means are intended to be shifted by at least one of the following means:
According to one particular aspect of the invention, the cementing device comprises first means for measuring the position of the mobile shutter means within the casing.
According to one particular aspect of the invention, the cementing device comprises second means for measuring the pressure prevailing in the annular spaces situated respectively upstream and downstream to the packer.
According to one particular aspect of the invention, the measuring means are configured so that they can communicate with a measuring tool taken down with a cable inside the casing.
The invention is also adapted to the primary cementing of a well.
The invention also concerns a method for cementing a casing (or a casing column) in a well bore.
According to the invention, such a method comprises:
Other features and advantages of the technique described shall appear more clearly from the following description of several embodiments, given by way of simple illustratory and non-exhaustive examples and from the appended drawings of which:
The appended figures, purely for the sake of simplification, show only one fraction of the vertical part of well bore A. It is naturally possible for this vertical portion to extend over a great length. For all the figures, it will be considered that the well head (which opens out into the open air) is situated towards the top of the figures, and the well bottom is situated towards the bottom.
The cementing device 1 comprises a differential valve 11 (DV) position towards the wellhead A and a packer 12 which is positioned beneath the differential valve 11 (towards the bottom of the well A).
The packer 12 implements a structure with two expandable liners 122, 124.
The packer 12 thus has a tubular metal liner called a “first external liner” 122, the opposite extremities of which are fixedly attached to the external face of the casing 2. More specifically, these extremities are gripped within annular reinforcement rings referenced 123 in
The casing 2, the first external liner 122 and its ends together demarcate an annular volume E which is divided into two parts, in this case volume a E1 demarcated by a casing 2 and a second internal liner 124 and a volume E2 demarcated by the two liners 122, 124.
The wall of the casing 2 has a conduit 115 leading at one extremity into the casing through at least one aperture 112 and leading at the other extremity into the annular volume E so as to make the interior of the casing 2 communicate with the annular volume E.
The packer 12 also has at least one communication passage or hole 125 between the exterior of the first external liner 122 and the part E2 of said volume E which extends between the two liners. This hole 125 passes through the thickness of the wall of the first external liner 122 from one side to the other and is oriented downwards. The function of this hole 125 shall be explained further below.
The liners 122, 124 are liable to expand, the first external liner 122 being designed, on an intermediate part of its length, to get applied in a tightly sealed manner against the wall of the well A, and the second internal liner 124 is intended to be applied against the internal face of the first external liner 122.
In the case represented here, the two liners 122, 124 are made of a ductile metallic material.
However, the second internal liner 124 could be made of another expandable material such as a rubber-based elastically deformable material. The first external liner can be lined on a part of its length with a sealing layer, for example an elastically deformable material (of the elastomer type).
The differential valve 11, in the example illustrated, has a single tubular shutter sleeve 113 that is axially mobile along the internal wall of the casing 2.
This shutter sleeve 113 is intended to selectively open and close the aperture 112 for the expansion of the liners 122, 124 and at least one cementing aperture or port 111 making the interior of the casing 2 communicate with the annular space 3 situated between the external face of the casing 2 and the internal wall of the well. It can be noted that in the embodiments presented here, the expansion aperture 112 for the liners 122, 124 (which is on the well head side) is situated above the cementing aperture 111 (which is on the well bottom side), these two apertures being situated above the packer 12.
In the embodiments of
Here below, the description relates to the case where the cementing of the well A is a staged cementing operation, the casing 2 having been positioned in the well A (step S1) and the primary or initial cementing of the well A having been done in a known manner downstream from the cementing device 1. Once this primary cementing has been done, the casing 2 has been plugged by a plug positioned downstream from the cementing device 1.
In a first position illustrated in
In this first position, the shutter sleeve 113 furthermore covers the expansion (or swelling) aperture 112 for the liners 122, 124 of the packer 12.
More specifically, the shutter sleeve 113 is fixed temporarily to internal wall of the casing 2 in the first position by at least one breakable retaining element, taking the form of a shear pin/slug 114 designed in such a way that a pre-determined force is needed to exceed the shear resistance of the shear pin/slug 114.
The shutter sleeve 113 thus needs a pre-determined force to be actuated so as to pass from the first position to the second position, then to the third position, described in detail here below (as emphasized here above, a tool is used to mechanically shift the shutter sleeve 113).
In a second position illustrated in
With the expansion aperture 112 being open, an expansion fluid for the liners 122, 124 is sent inside the casing 2 and is introduced by the expansion aperture 112 (step S3). The liners 122 and 124 get radially deformed simultaneously towards the exterior and the first external liner 122 gets applied against the wall of the well A. The packer 12, in a tightly sealed manner, isolates an annular part 32 of the well, situated beneath the packer 12, from another annular part 31, situated above the packer 12 and intended to be cemented.
In the third position illustrated in
Cement is then injected into the casing 2 (step S5) and is directed by means of the cementing aperture 111 in the annular space 31 situated above the expanded liners.
After sufficient introduction of cement into the annular space 31, the cementing port 111 is closed to hold back the cement in the annular space 31 and enable it to harden.
In
As illustrated in
As shown in
As shown in
Even if, as illustrated in
In the event of gas rising from the bottom of the well towards the liners 122, 124, the pressure rushes into the space between the two liners 122, 124 through the holes 200 of the first external liner 122, the first external liner 122 remaining applied in a tightly sealed manner against the wall of the well A.
In the case illustrated in
The solution of the invention is therefore efficient and robust. It ensures the perennial character of the isolation between the part of the well situated downstream from the packer and the upstream part which is cemented, and ensures that this cemented part is supported.
Contrary to the above embodiment, when the casing 2 is placed in the well A, the shutter sleeve 113 does not cover the expansion aperture 112 but only the cementing aperture 111 (
In short, the expansion aperture 111 and cementing aperture 112 are open/closed according to the following sequence:
Other Aspects and Variants
In one variant, the wall of the first external liner 122 is devoid of holes 125.
By contrast, the hole (or the holes) 125 are situated between two of the extremities facing the liners 122, 124 and open into the part E2 of the space E between the two liners 122, 124.
The technique of the invention can be implemented in the horizontal part of well bore A.
The shutter sleeves 113 of the differential valve 11 can be moved:
As illustrated, schematically in
Means are also provided to measure the pressure 311, 312 prevailing in the annular spaces 31 and 32 situated respectively upstream and downstream to the packer 12 so as to verify (and validate or not validate) the quality of the tightly sealed barrier formed by the expanded liners 122, 124.
These measuring means can communicate and especially transmit the measured data with a wireline type tool run down with a cable inside the casing 2.
Besides, the shutter sleeve or sleeves can take forms other than those illustrated in the embodiments described here above.
In one particular embodiment, the shutter means comprise:
Sufficient pressure is injected into the casing to break the disc and release the expansion aperture, while the cementing aperture remains shuttered. Once this operation is done, the pressure is increased to expand the liners.
The cementing aperture is then opened by injection of pressure which shifts the first shutter sleeve towards the bottom of the well. Once the cementing is done, the casing is shuttered by a plug positioned upstream to the cementing device and taking support from the second shutter sleeve.
Sufficient pressure is injected into the casing to shift the second shutter sleeve, by means of the plug, towards the bottom of the well so that this well closes the expansion aperture and the cementing aperture.
The plug can then be pierced.
It must be noted that the device of the invention can be implemented to cement a casing within a well bore vessel.
Number | Date | Country | Kind |
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1556609 | Jul 2015 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2016/066059 | 7/7/2016 | WO | 00 |