The present invention relates to the field of well drilling.
It relates more particularly to an isolation device of part of a wellbore.
This invention applies especially but not exclusively to the casing of a horizontal well. This casing is called “pipe” in the remainder of the document.
This well configuration has become widespread over recent years due to novel extraction techniques.
A horizontal well, inter alia, considerably increases the productive length and therefore the contact surface with the geological formation in which gas and/or oil is present in source rock.
In such a horizontal configuration, it is technically difficult to case and cement the annular space between the pipe and the inner wall of the well in a horizontal position. This cementing technique, used in the majority of vertical or slightly deviated wells, provides a seal between different geological zones.
The exploitation of horizontal wells, whether for stimulation or flow control, requires some zones to be isolated in the rock formation itself.
A pipe is run into the well with isolation devices at its periphery, spaced out in predetermined fashion.
The term “zonal isolation packers” is used for these devices. Between these isolation devices the pipe often has ports open or closed on demand, which enable communication between the pipe and the isolated zone of the well.
In this horizontal completion environment, hydraulic fracturing (also called “fracking”) is a technique for cracking of the rock in which the pipe is set horizontally.
Cracking is carried out by injection of a liquid under pressure. This technique enables extraction of oil or gas contained in highly compact and impermeable rocks.
The injected liquid generally comprises 99% water mixed especially with sand or ceramic microballs. The rock fractures under the effect of pressure and solid elements penetrate inside fissures and keep them open when the pressure drops so that gas or oil can flow through the resulting breaches.
These days fracking is mostly carried out by using an assembly of pipes such as described above. The zones are fractured one by one so that the quantity of fluid injected can be controlled. The fluid is indeed injected in limited volumes that are spread along the well. Pressures up to 1000 bar (15 000 psi) can be reached.
A key element of these fracking completions is located in the isolation and sealing device. It has to ensure perfect sealing between the zones to guarantee the quality and safety of fracking.
Indeed, if sealing not ensured, a zone could be fractured several times, creating an excessively large fracture and reaching unplanned geological zones.
During these fracking operations, isolation devices are subjected to high internal, external and differential pressures. Also, the injected fluids often have a lower temperature than that of the well, subjecting isolation devices to variations in temperature.
Several types of isolation devices are currently being used.
Hydraulic-set isolation devices “Hydraulic Packers” which utilise hydraulic pressure to compress a rubber ring via one or more pistons are being used.
This rubber ring expands radially and comes into contact with the borehole.
The patent U.S. Pat. No. 7,571,765 is a typical example of this type of hydraulic-set isolation device.
It is clear that when used this type of device does not properly seal a well having an ovalised cross-section.
Also, a fracture of the rock can be initiated at the packer level due to high contact pressure. Hydraulic isolation devices are also sensitive to temperature variations.
Other types of devices can be used.
In this way, mechanical isolation devices “mechanical packers” have a working principle close to that of hydraulic isolation devices, the only difference is that the compression of the rubber ring is carried out by an external tool.
Also, inflatable isolation devices (in English “inflatable packers”) comprise an elastic membrane inflated by injection of liquid under pressure. After activation, the pressure is maintained in the sealing device by check valve systems.
Isolation devices based on swellable elastomer (in English “swellable packers”) are composed of an elastomer which swells when placed in contact with a type of fluid (oil, water, etc.) according to formulations.
Activation of these devices is initiated by contact with fluid. It is therefore understood that diameter increase must be relatively slow so as to avoid blockage of the completion during the run in hole. As a consequence, it sometimes takes several weeks to achieve the isolation of the zone.
Other types of isolation devices are those known as “expandable” (in English “expandable packers” or “metal packers”) and comprise an expandable metallic sleeve which is deformed by application of liquid under pressure (see the article SPE 22 858 “Analytical and Experimental Evaluation of Expanded Metal Packers For Well Completion Services (D. S. Dreesen et al—1991), U.S. Pat. No. 6,640,893 and U.S. Pat. No. 7,306,033).
Expandable isolation devices made of metal usually comprise a ductile metallic sleeve attached and sealed at its ends to the surface of a pipe. The interior of the pipe, on the one hand, and the ring defined by the external surface of the pipe and the inner surface of the expandable sleeve, on the other hand, communicate with each other. The metallic sleeve is expanded radially towards the exterior until it makes contact with the borehole, by increasing the pressure in the pipe to create an annular barrier.
Contrary to other isolation devices, sealing is not based on elastomer means only, whereof the efficiency over time and under severe conditions is uncertain. Also, fracking often makes use of fluids at external ambient temperature whereas isolation devices are brought to the temperature of the well.
Expandable metal sleeves are less sensitive to temperature variations and more particularly to thermal contraction. The value of the coefficient of thermal expansion of the metal is lower than that of elastomer.
These expandable metal isolation devices therefore combine the advantages of devices explained earlier. First, as isolation devices based on inflatable elastomer, their design is simple and inexpensive and also they can be activated on demand as hydraulic isolation devices, soon after the completion has been run in the well.
Purely by way of illustration
This pipe 1 is illustrated again in the bottom part of the figure, the isolation devices 2 set in an expanded position.
The arrow v represents the circulation of fluid inside the pipe for fracking, that is, from upstream to downstream.
The aim of the description of this figure is simply to explain how pipes provided with such zonal isolation devices has been used to date.
A well A whereof the wall is referenced A1 has previously been drilled in the ground S.
Pipe 1 which is illustrated partially here has been set in place inside this well.
Along its wall, this pipe has, at regular intervals, isolation devices 2. In this case, just two devices 2 designated N and N−1 are illustrated by way of simplification.
In practice, there is a larger and substantial number of such devices along the pipe. As is known, each device is constituted by a tubular metallic sleeve 20 whereof the opposite ends are connected directly or indirectly to the external face of the pipe by reinforcing rings or skirts 21.
Pressure P0 prevails in the well.
Initially, the metallic sleeves 20, not deformed, extend substantially in the extension of the rings 21.
The distal end of the pipe preferably comprises a port, not illustrated here, which is initially open during the descent of the pipe into the well so as to allow circulation of fluid from upstream to downstream at pressure P0. This port is preferably closed by means of a ball which is placed in and blocks this port, increasing the pressure in the pipe is then possible.
A first fluid under pressure P1 greater than P0 is then sent inside the pipe. The fluid circulates through openings 10 arranged in front of the sleeves 20 along the entire pipe so as to expand the metallic sleeves and take the position of
Of course, the material of the sleeve and the pressure are selected so that the metal deforms beyond its elastic limit.
A device, not illustrated, frees up an opening located at the distal end of the pipe when the pressure P1 is slightly raised. The pressure at the level of the opening goes from P1 to P0 and circulation is then possible in the pipe from upstream to downstream of the well.
Next, another ball 5 is launched inside the pipe and lands in a sliding seat 4 located substantially mid-distance between the two isolation devices N and N−1.
Originally, the seat 4 is located just opposite the abovementioned openings 3 and seals them. Under the effect of displacement of the ball, the seat 4 is closed and shifts, freeing up the openings 3. A fracking fluid under very high pressure is then injected inside the pipe 1.
This fluid, under pressure P2, is introduced in the device N as well as in the annular space B which separates the devices N and N−1.
However, the prevailing pressure inside the device N−1 returns to the initial pressure of the well, that is, to the pressure P0.
In these conditions, the difference in pressure which exists between the annular space B and the device N−1 exposes the sleeve 2 of the device N to high stresses which in some places leads it to partially collapse. It is understood that this constitutes a source of leaks, meaning that the zone B to be fracked is no longer fluid or gas tight.
Systems have been added to this kind of devices to withstand collapse. An example is given in document WO 2011/042 492. Another option is to use this pressure difference by way of valves to maintain internal pressure in the device after expansion or to “capture” this pressure difference (see U.S. Pat. No. 7,591,321, US 2006/004 801 and US 2011/02 66 004). Yet, all these solutions mean greater complexity of the materiel and risk of malfunctioning.
From EP-A-1 624 152 is known a device in which each sleeve of the pipe is equipped with a “skin” which extends only along a part of said sleeve. Between the sleeve and the skin is present a sealant material.
The aim of the present invention is to cope with these difficulties.
More specifically, it relates to an isolation device of part of the well which is capable of resisting high differential pressures while having considerable sealing capacity.
Also, the system according to the invention has expansion pressure less than the fracking pressure and is not sensitive to changes in temperature.
As a result, this isolation device of part of a well which comprises a pipe provided along its external face with at least one metallic tubular sleeve—called “first external sleeve”—whereof the opposite ends are connected directly or indirectly to said external face of the pipe. This pipe, the first external sleeve and its ends together delimiting an annular space, the wall of said pipe exhibiting at least one opening which allows it to communicate with said space, this sleeve being likely to expand and to be applied tightly against the wellbore over an intermediate part of its length is
characterised in that it comprises:
The solution according to the invention succeeds in establishing pressure inside isolation devices, substantially equal to that which allows fracking of the rock, without the concern of collapsing and sealing leaks. Also, the solution according to the invention does not affect the general structure of pipe equipped with known isolation devices.
According to other advantageous non-limiting characteristics:
Other characteristics and advantages of the present invention will emerge from the following detailed description of some preferred embodiments. This description will be given in reference to the attached drawings, in which:
In reference to
It is illustrated expanded in
As illustrated in
More particularly in reference to
More precisely, these ends are enclosed inside reinforced annular rings referenced 21 in
In referring more particularly to
It is evident more particularly from
According to a particular characteristic of the invention, this is about a second sleeve 22, also expandable, whereof the ends X22 are sandwiched between those of the first sleeve 20 and the external face of the pipe 1, as shown in
In the case illustrated here, the two sleeves are made of ductile metallic material. However, the second internal sleeve 22 could be made of another expandable material such as an elastically deformable material based on rubber.
These sleeves are fixed to the wall of the pipe 1 by welds.
The same applies to the two parts 210 and 212 which constitute respectively the body and the end of the skirt or reinforcing ring 21.
Fixing means other than welds can be used, of course.
More particularly in reference to
In the process, the fluid enters the space E which is delimited by the wall of the pipe 1, the first external sleeve 20 and its ends X20.
This space E is divided into two parts, in this case a space E1 delimited by the pipe 1 and the second sleeve 22, and a space E2 delimited by the two sleeves.
In any case, according to the invention, the space E (i.e spaces E1 and E2) is not intended to be filled with a solid material or a liquid or paste material which becomes solid thereafter, or with a sealant material.
The second sleeve 22 has expansion pressure which is less than or equal to P1, that is, it is capable of expanding under the effect of pressure less than or equal to P1.
Because the second internal sleeve 22 is sandwiched in between the first sleeve 20 and the pipe 1, the second sleeve 22 deforms and is pressed against the inner face of the first sleeve 20.
Under the effect of the pressure P1, the sleeves 20 and 22 deform therefore simultaneously radially towards the exterior, as shown in
After expansion of the sleeves, the pressure drops and returns to P0. This pressure P0 is applied therefore in the space E1 located between the pipe 1 and the second inner sleeve 22. At this instant E1 is substantially equal to E, approximately the thickness of the second sleeve 22.
This is the situation of
In a later step, the openings 3 are cleared and a fluid under fracking pressure P2, above P0 (and P1), is circulated in the pipe 1.
This fluid therefore occupies the annular space B which separates both adjacent isolation devices and, as shown in
In this way, the space E1 which is located between the pipe 1 and the second sleeve 22 sees its volume reduce gradually since said pressure is sufficient to deform this second sleeve and press it progressively against the pipe 1. There is progressive transition from the situation of
In the process, on either side of the first external sleeve 20, the same equalised pressure P2 is obtained. In these conditions, sealing is retained and the risk of collapse of the sleeve is no longer there.
This solution is particularly advantageous since no mobile mechanical member is necessary. The only necessary step is to provide a second sleeve 22 and orifices 200 in the first sleeve 20.
The embodiment illustrated highly schematically in
However, the operation described hereinabove applies also for this embodiment, if the only difference is the pressure P2 being initiated between the two sleeves via the abovementioned orifice(s) located between the ends of the two sleeves.
The embodiment illustrated in
However, the external sleeve 20 is devoid of orifices 200.
However, the openings 10 which connect the pipe 1 with the abovementioned space E communicate with the latter via an annular gap j1 which extends between the first end of the first sleeve 20 and the first end of the second sleeve 22. This is particularly evident in
To do this, the sleeve 20 has been previously deformed locally to release such a gap.
Under the effect of the introduction of initial pressurised fluid P1 to the pipe, the openings 3 being closed, the fluid infiltrates via the openings 10 and travels in the annular gap j1 to occupy the space E2 located between the two sleeves 20 and 22, as in the configuration of
In reference to
In these conditions, the fluid of pressure less than or equal to P2 can travel in the gap j2 and deform the second sleeve 22 which is applied tightly against the first sleeve 20.
This gives the configuration of
In this way, any risk of even partial collapsing of the device 2 is guaranteed.
As is shown more particularly by the sectional view of
According to an advantageous characteristic of the present invention, the external face of the pipe 1 comprises a deformable elastic cover 7, for example made of rubber which covers the openings 10.
This can be a single and same tubular piece which covers all the openings 10 or several different pieces each covering an opening.
This cover is attached only at some points to the sleeve, for example by adhesion. So when this relates to a pressure flow directing openings 10 in the direction of the cover 7, the latter releases the pressure in the regions where it is not attached to the pipe 1.
The external sleeve 20 presented here is of the same type as that of
As is evident earlier, when the pressure P2 enters the space E2 collapsing of the sleeve 22 occurs.
During this collapsing, folds generated in the material of the sleeve can constitute mechanical weak zones and sources of leaks.
But if the device according to the invention is reused several times, the expansion and collapsing phases of the sleeve 22 risk making it defective.
In the embodiment of
The pressure P2 is applied in the space E1 which further still limits the risk of collapsing.
Although the invention herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and applications of the present invention. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present invention as defined by the appended claims.
Number | Date | Country | Kind |
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1252384 | Mar 2012 | FR | national |
Number | Date | Country | |
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61614225 | Mar 2012 | US |