NO20093308A1 - Method and apparatus for closing a well in the ground - Google Patents

Abstract

A method and apparatus for closing a well (1) in a formation (2) in the ground where feeding tubes (4, 6, 8) are provided, the method comprising: - inserting a cutting tool (20) into the well (1) ; removing a longitudinal portion (46) of the casing (4, 6, 8) by cutting the longitudinal portion (46) into pipe wall pieces (44); - removing the cutting tool (20); and - inserting a plug (48) against the formation (2) in the longitudinal portion (46) where the casing (4, 6, 8) is removed.

Description

METHOD AND DEVICE FOR CLOSING A WELL IN THE GROUND

This invention relates to a method for closing a well in the ground. More specifically, it concerns a method for closing a well in the ground where the well is provided with casing. The invention also includes a device to be able to carry out the method

When production from a well in the ground, typically a petroleum well, has ended, it is necessary to close the well in a way that, among other things, ensures against future outflow of well fluid from the well.

Above each pressure-bearing zone, it is common to place at least two independent barriers comprising an appropriate plug material which is designed to be able to seal the well. In some cases, it is necessary to remove a longitudinal section of a casing in order to place a barrier or a plug against the formation wall.

According to known technology, the casing material is machined away by means of carbide cutters which are arranged on a pipe string.

The pipe string is connected to a drilling vessel or an installation with the necessary drilling equipment. Chips from the machining must be transported up to the surface because the chips, which can be magnetic and include relatively long chip bends, prevent tools from passing the part if it has not been removed. Machining away the longitudinal section from the casing using known techniques can take several days and is a very expensive operation.

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.

A method has been provided for closing a well in a formation in the ground where casing is arranged and where the method comprises: - passing a cutting tool down into the well; - to remove a longitudinal section of the casing by cutting the longitudinal section into pipe wall pieces;

- to remove the cutting tool; and

- to put a plug against the formation in the longitudinal section where the casing has been removed.

In this context, a cutting tool means a tool that is designed to be able to make cuts through the pipe wall, as opposed to a machining tool that is designed to be able to remove pipe material by chipping.

By cutting the longitudinal section into pipe wall pieces, the production of voluminous chips is avoided at the same time that the pipe wall pieces are relatively easy to handle.

The method can further comprise cutting open the longitudinal section using a fluid jet. By using a fluid jet, further induction of magnetic forces in the pipe wall pieces is avoided and the pipe wall pieces can be allowed to fall down and remain in the well. If desired, the pipe wall pieces can be brought to the surface, for example with the help of a magnet.

The procedure can further include the preparatory actions: - filling the lower part of the well with filling material; - cutting an inner casing in a lower position in the well than the position where the longitudinal section is located; and - to remove the upper part of the inner casing.

The method may further comprise connecting the cutting tool to the surface by means of a coiled pipe. The method thereby enables shut-in of the well without the use of a drilling rig.

The method can be carried out with the help of a cutting tool for cutting the longitudinal part of a casing, where the cutting tool comprises a nozzle head rotatable about its longitudinal axis with at least one nozzle, and where the nozzle head is connected to a coiled tube, the coiled tube extending to the surface, and where the cutting tool is connected to the casing using an anchor.

The anchor can be a fixed anchor or a roller anchor and the cutting tool can be equipped with an actuator for axial displacement of the nozzle head.

In an embodiment where the armature is fixed, the actuator can be used for axial displacement of the nozzle head during the cutting operation. If a rolling anchor is used, the coil pipe can be moved axially in the well without the use of a separate actuator.

In a further embodiment, the cutting head can be provided with a pendulum nozzle. The pendulum nozzle, which is of a known design in and of itself, is designed to be able to rotate the fluid jet while the nozzle head is kept stationary.

The cutting tool can be provided with a switching valve which is arranged to optionally be able to connect a fluid stream to a desired nozzle. For example, the fluid flow can be directed to a cutting nozzle during the cutting operation and then directed to a cleaning nozzle during a subsequent cleaning operation.

The method and device according to the invention enables a significant reduction of the time required to shut down petroleum wells while at the same time significantly simpler equipment can be used compared to known technology. The invention thereby facilitates a significant reduction in costs associated with shutting down and completing wells.

In what follows, an example of a preferred embodiment is described which is visualized in the accompanying drawings, where: Fig. 1 schematically shows a well which has been prepared for a

cutting operation according to the invention;

Fig. 2 schematically shows a section on a larger scale of a

cutting head;

Fig. 3 shows a cutting pattern in the wall of the casing; and

Fig. 4 schematically on a smaller scale shows a well after that

a plug is set.

In the drawings, the reference number 1 denotes a petroleum well in a formation 2. An inner casing 4, a second inner casing 6 and other casings 8 are embedded in a borehole 10 using casting compound 12.

A gasket 14 seals between the inner casing 4 and the second inner casing 6.

In fig. 1, the well 1 is shown after preparatory work has been carried out such as filling the lower part of the inner casing 4 with filling material 16, cutting the inner casing 4 and removing the upper part of the inner casing 4 not shown from

well 1.

A coiled pipe 18 with an attached cutting tool 20 is located in the well 1, the cutting tool 20 being positioned and held in the second inner casing 6 by means of an anchor 22.

The cutting tool 20 comprises a tool housing 24 with components necessary in and of themselves, not shown, for controlling the cutting operation. An actuator 26 is designed to be able to displace a rotatable nozzle head 2 8 in the longitudinal direction of the well 1.

In this preferred embodiment, the nozzle head 2 8 comprises a switch valve 30 to be able to selectively control pressurized fluid which is supplied via an actuator channel 32 from the coil pipe 18 to a cutting nozzle 34 or a cleaning nozzle 36, see fig. 2.

The switching valve 30 can be a so-called sequence valve which changes position every time the fluid pressure is relieved.

When the cutting tool 20 is positioned in the well 1, the cutting can be initiated by fluid containing abrasive material flowing to the cutting nozzle 34 under relatively high pressure via the coil pipe 18 and the switching valve 30.

The nozzle head 2 8 is caused to displace the cutting nozzle 34 along a predetermined path which, for example, provides the cutting path 3 8 in the tube wall 40 of the second inner casing 6 as shown in fig. 3.

By then cutting along the paths 42, pipe wall pieces 44 of the second inner casing pipe 6 longitudinal section 46 are formed.

By switching on the switching valve 30, pressurized fluid is fed to the cleaning nozzle 36, whereby the pipe wall pieces 44 can be flushed down or into the well 1.

The part of the molding compound 12 which can be behind the longitudinal part 46 of the second inner casing 6 is also removed by means of a fluid jet from the nozzles 34, 3 6 in the nozzle head 28.

After the well 1 has been prepared, the coiled pipe 18 and the cutting tool 20 are pulled out from the well 1, after which a plug 48 is set against the formation 2 in the longitudinal section 46 in a manner known per se, see fig. 4.

In an alternative method not shown, the longitudinal part 44 can be selected at a place where two or more casing pipes 6, 8 located outside of each other must be cut away to expose the formation 2.

Claims (10)

1. Method for closing a well (1) in a formation (2) in the ground where casing (4, 6, 8) is arranged, characterized in that the method includes: - passing a cutting tool (20) down into the well (1 ) ; - removing a longitudinal section (46) of the casing (4, 6, 8) by cutting the longitudinal section (46) into pipe wall pieces (44); - to remove the cutting tool (20); and - placing a plug (48) against the formation (2) in the longitudinal section (46) where the casing (4, 6, 8) has been removed. 2. Method according to claim 1, characterized in that the method further comprises cutting the longitudinal section (46) using a fluid jet. 3. Method according to claim 1, characterized in that the method further comprises allowing the pipe wall pieces (44) to remain in the well (1). 4. Method according to claim 1, characterized in that the method further comprises the preparatory actions: - filling the lower part of the well (1) with filling material (16); - cutting an inner casing (4) in a lower position in the well (1) than the position where the longitudinal part (46) is located; and - to remove the inner casing (4) upper part. 5. Method according to claim 1, characterized in that the method further comprises connecting the cutting tool (20) to the surface by means of a coiled pipe (18). 6. Device with cutting tool (20) for cutting the longitudinal section (46) of a casing pipe (4, 6, 8) according to the method in claim 1, characterized in that the cutting tool (20) comprises a nozzle head (2 8) rotatable about its longitudinal axis with at least one nozzle (34, 36) where the nozzle head (28) is connected to a coil pipe (18), the coil pipe (18) extending to the surface, and where the cutting tool (20) is connected to the casing pipe (4, 6, 8) using an anchor (22). 7. Device according to claim 6, characterized in that the anchor (22) is a roller anchor. 8. Device according to claim 6, characterized in that the cutting tool (20) is provided with an actuator (26) for axial displacement of the nozzle head (28). 9. Device according to claim 6, characterized in that the nozzle head (28) is provided with a pendulum nozzle. 10. Device according to claim 6, characterized in that the cutting tool (20) is provided with a switching valve (30) which is arranged to optionally be able to connect a fluid stream to a desired nozzle (34, 36).