NO302136B1 - Method and apparatus for placing a cement liner in a borehole - Google Patents

Description

The invention relates to a method and a device for placing a cement lining along the wall of a borehole.

In the technique for drilling wells in underground formations, stabilization and reinforcement of the borehole wall with a cement lining is known.

A borehole stabilization technique of this type is known from USSR inventor's certificate 723102. According to the known technique, a formwork in the form of a temporary casing is led down into the well. Later, a cement mixture is pumped into the annular space around the pipes using drilling mud. As soon as the mud has reached the lower end of the casing, the casing is pulled up, and guide plates mounted on the lower end of the casing spread the cement mixture over the borehole wall. The mud is left behind, so that its own weight enables it to act as a barrier while the cement hardens.

A disadvantage of this known technique is, especially in non-vertical wells, that the weight of the casing and guide plates can cause an eccentric placement of the plates inside the borehole, which results in the cement layer having an uneven thickness.

An object of the present invention is to correct this disadvantage of the known process and to produce a method and a device for placing a cement liner in a well so that the cement liner has a constant thickness, even in a non-vertical well.

This is achieved with the method and device according to the invention as it is defined with the features listed in the claims.

Experiments have shown that with correct dimensioning of the centering device, the grooves formed in the cement mixture along the borehole wall of the sliding centering device will disappear before the cement mixture solidifies, so that there are no irregularities in the cement layer.

In the following, the invention will be explained in more detail with reference to the drawings, where Figures 1A-1D show different steps in the well casing method according to the invention, and Figure 2 shows a suitable embodiment of the well casing device according to the invention, Figure 3 shows an embodiment of the device where the centering pipe is connected to the pipe by a telescopic device, and figure 4 shows an embodiment of the apparatus where the centering pipe is connected to the pipe by a flexible hose.

Figure IA shows a borehole 1 in which an upper section is lined with a cement layer 2 while a cement mixture 3 is introduced by injection into a lower section of the borehole.

The cement mixture is injected through a pipe 5 and a centering pipe 6 into an annular space 7 around the pipe 5 and the centering pipe 6. The lower end of the centering pipe 6 is held in a central position in the borehole 1 by an arched centralizing device 8, while the outlet 9 from the centering tube is placed just above the bottom 10 in the hole 1.

Before injecting the cement mixture, the borehole has been cleaned, e.g. to remove any drilling mud from the borehole wall, by circulating a cleaning mud 12 at high speed through the annular space 7. If the annulus has a large diameter, expandable rubber scrapers (not shown) can be attached to the centering tube outer surface to form a flow restriction in the annulus and to scraping off sludge when the centering pipe is passed through a section to be treated.

The cement mixture 3 removes the cleaning mud 12 from the annular space 7, and the cement mixture 3 is displaced from the interior of the centering tube by drilling mud 13 of the same density as the cement mixture. The volume of injected cement mixture 3 is chosen so that the cement mixture fills the annular space 7 above the borehole section to be treated, while the volume of heavy mud injected behind the cement mixture is sufficient to establish the desired mud core over the length of the borehole section to be treated. Later, the upper end of the annular space is closed by means of a collar, known as a hydril or sluice tube, to create a solid column of cement in the annular space 7, after which the tube 5 and the centering tube 6 are pulled upwards as shown in Figure IB . To compensate for the pipe volume being pulled out of the borehole, additional drilling mud is allowed to flow into the pipe.

During the upward movement of the pipe 5 and the centering pipe 6, the centering pipe creates a mud channel 15 in the plug of cement mixture 3. The diameter of the mud channel does not depend on the diameter of the outlet 9 of the centering pipe 6, but on the outer diameter of the pipe 5 which is drawn through the collar. After the outlet 9 from the centering tube 6 is above the zone to be treated as illustrated in Figure 1C, the annular space 7 is opened and excess cement and heavy mud are circulated from the borehole. Later, the cement is allowed to solidify.

As illustrated in figure ID, a drill bit 17 is later used to ream or polish the channel 15 to a bore of the desired diameter. The mud channel 15 acts as a guide for the drill bit 17 to center the bit in the borehole. The crown 17 can be an under-reamer crown or an eccentric crown, and can be equipped with a nose (not shown) which can easily follow the mud channel 15. The same crown 17 can be used to drill a next section of the borehole after the bottom 10 is reached. The mentioned next section can have a smaller diameter than previously treated sections, and can be equipped with a cement lining which is placed using the same method as described above.

Alternatively, the next section may have the same or larger diameter as the previously treated sections, and may be equipped with a normal steel casing, or may be unlined, or lined in the same manner as described above.

As shown in Figure 2, the cement injection apparatus can be equipped with a centering tube 20 which hangs from a coiled tube 21 and is equipped with a mixing sub 22.

The mixing sub 22 comprises a tubular element which is mounted coaxially around the lower end of the centering tube 20, and a conical mixing device 24 which is mounted inside said sub 22 below the said end of the centering tube 20 so that it points towards the centering tube. In use, mud and cement are mixed inside the sub 22 when the pipe 21 and the centering pipe 20 are pulled after injection of cement mixture 25 into the annular space in a well section to be treated.

The cement that enters the top 26 is mixed with mud that flows down through the centering pipe 20 when the pipe is pulled up, so that below the sub 22 a mixture of mud and cement is created in the center 27 of the borehole 28. After solidification of the cement, the mud/cement mixture forms in the center 27 of the drill hole 28 a soft core which can be easily drilled out.

To ensure stable centering of the device in the borehole

28 is a series of rigid ribs 29 and a series of arched centering

blade 30 mounted at equal angular distances on the tubular outer surface and mixing sub 22. The spring-spring centering blades serve to center the apparatus in vertical hole sections, while the rigid ribs 29 serve to center the apparatus in highly divergent hole sections. If desired, the rigid ribs 29 can be replaced with spring stabilization blades of higher stiffness than the other stabilization blades 30. Alternatively, the stabilization device can consist of a steel pin scraper or a series of extendable arms around the circumference, which are held in contact with the borehole wall by a spring action. In the above manner, correct centering of the unit is achieved both in vertical and deviated boreholes or in holes of varying diameter or irregular shape. Correct centering of the unit inside the borehole ensures that the soft core is always placed in the center of the borehole, so that a cement lining of regular thickness is left along the borehole wall 28 after drilling out the soft core. Figure 3 shows an embodiment of the device according to the invention where the centering pipe 33 is mounted telescopically inside a pipe 34. During lowering of the unit through the borehole, the centering pipe 33 is in the illustrated retracted position. However, after injection of cement mixture into the annular space, the pipe 34 is pulled, friction between the borehole wall and the stabilizer blades 35 will cause the centering pipe 33 to be pulled out of the pipe 34 until the centering pipe 33 is in an extended position. Figure 4 shows an embodiment of the device according to the invention where the centering pipe 34 is equipped with two stabilization units 42 and 43. The centering pipe is connected to the pipe 34 by a flexible hose 45. The flexible hose 45 avoids that an eccentric position of the lower end 46 of the tube in an awikswell section 47 would result in an eccentric placement of the centering tube 41.

The cement mixture can contain various additives to adapt its physical properties to the female operations. Latex, polymers and epoxies can be added to the mix to optimize the elastic properties of the cement, and polypropylene or other fibers can be added to the mix to improve the impact resistance of the cement and to plug loose zones. Furthermore, the cement's wear resistance can be improved by adding hard-wearing grains, while the cement's friction factor can be reduced by e.g. to add graphite.

The cement may contain Portland cement, but alternatively it may consist of an epoxy, polymer or other type of resin. The cement composition can also vary over the length of the borehole.

It is further preferred to use bentonite slurry to create the channel in the cement plug, because as soon as it comes into contact with the hydraulic cement, bentonite reacts with cement. The result is that a very viscous, paste-like mud channel remains in the cement plug. The mud may also contain additives which cause the mud to thicken when it comes into contact with hydraulic cement, or which act as an accelerator for solidification of cement.

It is important that good adhesion is achieved between the cement and the borehole wall. Therefore, it is usually necessary to wash away any mud or waste from the borehole wall before injecting cement.

If the centering tube hangs from a pipe with a large diameter, a small annular space is created in which a fluid flow can be created at a high speed. Because of this high fluid velocity, mud can be washed away before placing the cement. However, a disadvantage of hanging the centering pipe from a pipe string is that pulling the centering pipe must be interrupted to break the pipe connections. These breaks can cause air pockets in the sludge channel due to pressure release.

In order to avoid balloons being created in the sludge channel, it is generally preferred to hang the centering pipe from a coiled pipe of small diameter which can be pulled at a constant speed through the interval to be treated.

Because of the large annular space around a small diameter tube, it may be necessary to attach steel-reinforced rubber scrapers to the outer surface of the centering tube and/or tube. These scrapers act as a flow restriction in the annular space and locally result in high fluid velocities. The scrapers also scrape off the filter cake from the borehole wall when the centering pipe is passed through the borehole section to be treated. Sludge can be circulated while the centering pipe is lowered.

It must also be understood that after injection of cement mixture into the annulus around the pipe and centering pipe, and before the cement solidifies, the pipe can be moved up and down through the borehole section to be treated before finally filling the pipe and centering pipe with heavy mud and pulling them through the cement plug to create a mud channel or soft core in this.

Finally, it must be understood that instead of injecting the cement mixture via the centering pipe into the well, you can also introduce the cement mixture into the well before lowering the centering pipe into the well. In this case, the cement mixture will completely fill a lower section of the borehole when the centering pipe is lowered into the hole. When the centering pipe has reached the bottom of the hole, drilling mud is introduced into the interior of the pipe and the centering pipe until these are completely filled with mud, after which the pipe and the centering pipe are pulled up from the borehole in the same way as described with reference to figure lb.

Many other variations and modifications may be made to the apparatus and technique described herein by those skilled in the art. Consequently, it must be clearly understood that the apparatus and method as described in the drawings are only illustrative, and are not intended as any limitation on the scope of the invention.

Claims (8)

1. Method for placing a cement liner (2) along the wall of a borehole (1), comprising lowering a pipe (5, 6) into the borehole (1) until the lower end of the pipe (5, 6) has reached the bottom of a section in the borehole (1) to be lined, to feed a cement mixture (3) into an annulus (7) around the pipe (5, 6) and to pump drilling mud (13) down the pipe (5, 6) until the mud (13 ) has essentially reached the lower end of the pipe (5, 6) and the cement mixture (3) essentially fills the annulus (7) above the section end of the borehole to be lined, to pull the pipe (5, 6) up through the borehole (1) and allowing the cement to solidify, CHARACTERIZED BY, the pipe (5, 6) comprising a centering pipe (6) which is connected to the lower end of the pipe (5), equipping the centering pipe (6) with a mixing sub (22) consisting of a tubular body with the inner diameter of the pipe (5, 6), to arrange a mixing device (24) in the pipe, to mix cement and mud in the mixing sub (22) when the pipe (5) and the centering pipe (6) are pulled up through the borehole ( 1), and to center the centering pipe (6) and the pipe (5) in the borehole (1) by means of a centering device (8) which is held in contact with the wall of the borehole and which is drawn through the cement mixture (3) along the wall of the borehole. 2. Method according to the preceding claim, CHARACTERIZED BY centering the centering pipe (6) in the borehole (1) with a centering device (8) comprising several centering blades (30) designed as arched springs which are mounted near the centering pipe (6) lower end. 3. Method according to claim 2, CHARACTERIZED BY equipping the centering device (8) with rigid ribs (29) mounted at equal angular distances around the centering tube (6). 4. Method according to claim 1, CHARACTERIZED BY pumping bentonite mud (13) with a density essentially equal to the density of the cement mixture (3) into the pipe (5) and the centering pipe (6) behind the cement mixture (3). 5. Method according to claim 1, CHARACTERIZED BY closing the annular space (7) at the wellhead or at the top of the borehole six ion to be lined after mud (13) has been pumped into the pipe (5) and the centering pipe (6). 6. Method according to claim 1, CHARACTERIZED BY introducing a cement mixture (3) into the borehole (1) before the pipe (5) and the centering pipe (6) are lowered into the borehole (1), so that the cement mixture (3) completely fills a lower section of the borehole (1), and injecting drilling mud into the interior of the pipe and the centering pipe until the mud has reached the lower end of the centering pipe, after the pipe (5) and the centering pipe (6) have been lowered to the bottom of the borehole. 7. Method according to the preceding claim, CHARACTERIZED BY lowering a drilling device (17) into the borehole and activating it to drill an open space of the desired size in the center of the cement plug after the cement has solidified. 8. Device for placing a cement lining along the wall of a borehole (1), comprising a centering pipe (6) connected to one end of a pipe (5) and a device for centering the centering pipe (6) in the borehole (1), where the centering device (8) comprises several centering elements which protrude laterally from the centering pipe (6) so that the elements are kept in contact with the borehole wall during use, CHARACTERIZED IN THAT the centering pipe (6) comprises a mixing sub (22) with a tubular element which is mounted coaxially around the centering pipe (6) lower end, and that a conical mixing device (24) is mounted in the mixing sub (22) below and facing the centering pipe (6) end to mix cement and sludge into a soft cement core as a result of the pipe (5) and the centering pipe (6) is pulled up through the drill hole (1).