NO329509B1 - Hydraulic brush for use in downhole operations - Google Patents

Abstract

BACKGROUND OF THE INVENTION The present invention relates to a well tool (1) for cleaning the interior of casings and valves, in particular for shell removal, wherein the tool (1) comprises main body (9) comprising a drive means (11), a power supply (5), a hydraulic pump ( 13) and a gripping mechanism (8). The invention is characterized in that the tool (1) further comprises a brush head (10) comprising radially expanding brush members (16), the tool (1) being arranged by means of the driving means (11) to firmly lock the main body (9) to the inside of a liner (2) by means of the gripping mechanism (8), rotating the brush head (19) and expanding the brush members (16) to the desired outer diameter.

Description

The present invention relates to a well tool for cleaning the inside of casing pipes and valves.

In the case of oil and gas production, wells are drilled which are fully or partially supplied with casing. In addition, as a rule, one or more valves are arranged, for example a well safety valve or so-called DSV valve (Downhole Safety Valve), to ensure well control in the event of unexpected events occurring in the well. A DSV valve is usually "fail-safe", that is, it closes automatically if certain parameter values rise or fall out of predetermined intervals. However, over some time, a coating called scale will always form on the inside of the casing and the DSV valve. Casing may contain remnants of cement used when a casing is set into a borehole. Water carried with the production stream can also contain barium and calcium ions, which can be combined with minerals and deposited in a coating or shell of, for example, barium sulphate and calcium carbonate. In addition, the production stream can contain significant amounts of wax, which, possibly together with e.g. barium sulphate and calcium carbonate, can form layered shells, i.e. a coating of deposits which can be very difficult to remove.

This coating of deposits could affect the function of the DSV valve, which is considered unacceptable. If the DSV valve cannot be operated safely, the well must either be closed/abandoned or it must be re-completed (the completion must be pulled, and a new well with a new DSV valve must be installed). In both cases, there are very large financial losses.

Known methods for removing shells include the use of solvents and/or mechanical scraping. The use of solvents causes cleaning problems and costs for both solvents and cleaning. Milling and/or honing are often used to remove cement scale in casing and harder deposits of minerals such as barium sulphate and calcium carbonate. Mechanical scraping using brushes is also common.

From Norwegian patent NO 320906 B1, an apparatus is known for cleaning the inside of a casing for shells. Rotating cleaning elements are inclined in relation to their axis of rotation, and thereby oscillate axially against the inner wall of the pipe when they are rotated. This avoids slow back and forth movement from prior art. This device is attached to a pipe, e.g. a drill string, which both supplies fluid to drive rotation and oscillation and provides the necessary mechanical reaction force required when shells are to be scraped off.

Other cleaning tools for connection in a pipe string are described in NO 316915 B1, NO 172427 C, US 4,501,322, US 5,947,203 and US 7,255,164 B2. These patents also describe the use of liquid supplied through the pipe string in combination with the brush/scraper function.

Using a pipe string when removing shells can be complicated, and thus time- and cost-consuming.

It is an aim of the present invention to provide a tool which can clean the inside of casing pipes and valves in a simple and cost-effective way.

It is also an object of the present invention to provide a tool that can clean the inside of casings and valves with the help of a wire (so-called "slickline", which is a wire of typically approx. 3mm (0.125") that is used to winch equipment and tools down a well) or e-line (wires comprising electric cable).

These and other purposes are achieved by a device which is characterized by the features specified in the characterizing part of the attached independent claims. Further advantageous features and embodiments are specified in the independent claims.

In the following, a detailed description of a preferred embodiment of the present invention is given with reference to the attached drawings, where: Fig. 1 shows a well tool for cleaning the inside of casing pipes and valves according to one embodiment of the present invention, the gripping mechanism and the brush members being located in a retracted state, Fig. 2 shows the well tool according to fig. 1, the gripping mechanism and the brush members being in an activated, protruding state, and Fig. 3 shows a well tool according to Fig. 1 and 2 while in a casing, the gripping mechanism and brush members being in an activated, protruding state and respectively engaging with a nipple profile and the DSV valve.

According to the present invention, a well tool 1 is provided for cleaning the inside of casing 2 and valves 3 which can be driven on a cable 4 or e-line. If it is driven on a cable 4, it must be supplied with a battery pack 5 which can supply it with power during the operation. Driving using wireline 4 is considered to be the least expensive well intervention method that exists today. If the tool 1 is run on an e-line, power can be supplied from the surface and the battery pack can be bypassed.

According to one embodiment of the present invention, the tool 1 is run on a standard 3mm (0.125") wire 4, being attached to the wire by means of a wire holder 6 (so-called "rope socket") 6 and then placed in the sluice pipe. The sluice pipe is pressure tested, after which the Christmas tree is opened and the tool can be lowered into the well until it reaches the DSV valve 3. The DSV valve 3 is normally arranged approximately 50 meters below the seabed, as in the open state it forms a continuous passage that does not obstruct access further down the well. of the DSV valve 3 there is a recess which is often called a "nipple profile". The nipple profile forms an engagement point in the casing 2 which the tool 1 according to the present invention can grasp. The tool 1 is lowered through the DSV valve 3, whereupon the is pulled slowly upwards until a radially acting gripping mechanism 8 arranged on the tool slips into the nipple profile . v for example claw organs 8 which are activated by, for example, a jerking movement. One can also find and activate the claw organs 8 by using optical, magnetic, profile detecting, radioactive or similar sensing organs. When the tool 1 is positioned and has clamped correctly in relation to the DSV valve 3, the tool is ready to start and perform the cleaning operation.

The tool according to the present invention comprises, according to one embodiment, a main body 9 and a brush head 10. According to one embodiment, the main body 9 comprises the battery pack 5, a drive member 11 and an activation member 12. The drive member 11 comprises an electric motor 17 which is arranged to turn the brush head 10 via a hydraulic pump 13 and a gear system 18. The drive 11 is powered by the battery pack 5 or alternatively from the surface via an electric cable. The hydraulic pump 13 is in communication with a hydraulic system 14 comprising, among other things, a hydraulic chamber/reservoir 15, as the hydraulic system 14 is used to clamp the tool firmly in the wellbore and further causes brush members 16 on the brush head 10 to expand against the inside of the wellbore/DSV valve 3, so that the brush members 16 come into contact with the inside of the wellbore/DSV valve 3. When the drive member 11 rotates the brush head 10 and the brush members 16 on the brush head 10 rest against the inside of the wellbore/DSV valve 3, the deposits will be removed quickly and efficiently.

It is understood that the brush members 16 can comprise brushes of different types and designs. Instead of brushes, a honing tool can possibly be used

milling tool. The honing tool can, for example, be used to ensure that a wellbore is sufficiently cleaned for setting plugs or for honing nipples. Similarly, a milling tool can be used to ensure that the wellbore is sufficiently circular, for milling out a window, or for milling out obstructions in the wellbore that you want removed.

The tool 1 according to the present invention can, for example, be activated by performing an "overpull" on the wire. A sensor or valve will register the extra load that the overpull force constitutes, as the electric motor 17 is thus caused to start. As mentioned, the electric motor 17 drives a hydraulic pump 13, the hydraulic pump 13 ensuring that the pressure in the hydraulic system 14 increases to the desired hydraulic system pressure. When the desired hydraulic system pressure has been achieved, pressure can be opened against the claw members 8 for further clamping of the tool's main body 9 to the nipple profile in the wellbore 2, as this will further contribute to the tool 1 being firmly seated and able to withstand the reactive torsional forces that arise when the brush head 10 rotates. At the same time, the brush head 10 can be caused to rotate by means of the system pressure at the same time as the brush members 16 which are placed on the brush head 10 are caused to expand towards the inside of the wellbore. The brush members 16 are arranged on piston members which cause the brush members 16 to expand radially outwards towards the inside of the wellbore. In one embodiment, the system pressure will determine how far the brush members 16 are allowed to expand, so that these expand in a controlled manner to a predefined outer diameter (OD), i.e. adapted to the wellbore's inner diameter (ID). Alternatively, the outer diameter of the brush members 16 can be set in advance by means of mechanical setting/stop means.

According to one embodiment of the present invention, one can provide the present well tool with devices that make it possible to reduce the expansion force on the brush members 16 when the rotation resistance becomes too great, for example when the rotation speed becomes too low or when the power consumption becomes too high. One possible way to achieve this is to use an electrohydraulic logic module 19 which registers motor data and which, on the basis of these registrations, regulates the hydraulic pressure of the brush members 16 to a level which is necessary to maintain the desired rotation speed. The electrohydraulic module can, for example, be arranged so that it dumps pump flow back to chamber/reservoir 15 by means of a varying and adapted restriction in order to thereby regulate the differential pressure of the brush members 16.

The tool 1 can be arranged so that it operates sequentially, for example in that the system pressure first causes the claw members 8 to tighten firmly, then the brush head 10 is caused to rotate and finally the brush members 16 are expanded radially outwards to the desired outer diameter. It is understood that other sequential orders may also be selected.

According to another embodiment, the brush head 10 can be telescopically arranged so that the cleaning function of the tool 1 can be carried out over a greater length of the inside of the wellbore.

According to a further other embodiment, the tool's 1 can be arranged so that the electric motor 17 directly rotates the brush head 10, that is to say that the electric motor 17 causes the brush head 10 to rotate without detouring through a hydraulic pump 13. The electric motor 17 will also drive a hydraulic pump 13 which generates a system pressure sufficient to cause the claw members 8 to fasten firmly in the nipple profile and expand the brush members 16 radially outwards to the desired outer diameter.

Fig. 1 shows the tool 1 according to one embodiment, in that the claw members 8 and the brush members 16 have a common pressure line from the electrohydraulic logic module 19, in that a stretch in the tool 1 gives an impulse to the electrohydraulic logic module 19 from the activation member 12, whereupon the brush head 10 is activated and the brush members 16 expands. The brush head 10 rotates as long as the electric motor 17 is in operation. The expansion of the brush members 16 is then controlled by the electro-hydraulic logic module 19 as described above.

Claims (7)

1. Well tool (1) for cleaning the inside of casing and valves, in particular for removing mineral deposits, the tool (1) comprising a main body (9) comprising a drive member (11), a power supply (5), a hydraulic pump (13 ) as well as a gripping mechanism (8), characterized in that the tool (1) further comprises a brush head (10) comprising radially expanding brush members (16), the tool (1) being arranged by means of the drive member (11) to clamp the main body (9) firmly to the inside of a casing ( 2) using the gripping mechanism (8), rotate the brush head (19) and expand the brush members (16) to the desired outer diameter. 2. Well tool (1) according to claim 1, where the drive member (11) drives a hydraulic pump (13) which generates a system pressure, where the system pressure is used to activate the gripping mechanism (8), rotate the brush head (19) and expand the brush members (16) to desired outer diameter. 3. Well tool (1) according to claim 1, where the drive member (11) is arranged to directly rotate the brush head (10) which comprises the radially expanding brush members (16), the drive member (11) further drives a hydraulic pump (13) which generates a system pressure, where the system pressure is used to activate the gripping mechanism (8) and expand the brush members (16) to the desired outer diameter. 4. Well tool (1) according to any one of the preceding claims, wherein the drive member (11) comprises an electric motor. 5. Well tool (1) according to any one of the preceding claims, wherein the power supply (5) comprises a battery pack. 6. Well tool (1) according to any one of the preceding claims, wherein the power supply (5) comprises a power cable (4) from the surface. 7. Well tool (1) according to any one of the preceding claims, wherein the gripping mechanism (8) comprises radially expanding claw members, the gripping mechanism (8) being arranged to expand radially by means of a hydraulic pressure generated by a hydraulic pump.