The present application claims priority on European Patent Application 03104435.7 filed 28 Nov. 2003.
The present invention relates to a method of removing a body of selected material from the interior of a casing extending into a borehole formed in an earth formation and to a drill bit for use in the method.
When drilling a borehole in an earth formation, for example to create a well for exploration or production of mineral hydrocarbons, a steel casing is commonly set at a certain stage in the drilling operation in order to secure an already drilled section of the bore hole before drilling deeper. After setting the casing, a drill bit is run through the casing in order to reach the bottom of the hole where the drilling operation can be continued. Running the drill bit through the casing involves a risk of damaging the casing wall, in particular since normally a fresh drill bit is selected that has sharp rock cutters, usually in the form of shear cutters which are much harder than the casing steel and are even capable of cutting through the casing. Since a casing is generally intended to remain in the borehole for a long period of time, it is undesirable to cause casing wall damage.
Moreover, a casing is often cemented in the borehole. Commonly applied cementing procedures require that some cement as well as auxiliary equipment such as cementing plugs remain inside the casing shoe. This must be drilled out in order to expose the bottom of the borehole for continued drilling. However, drilling out the remaining cement and auxiliary equipment from the casing involves the risk of damaging the casing with the rock cutters of the drill bit. This is particularly so if it is desired to leave as little as possible remains of cement in the casing, for example if the lower end portion of the casing is to receive the upper end portion of another casing or liner in sealing engagement.
Thus there is a need for an improved method of removing a body of selected material from the interior of a wellbore casing, which method overcomes the aforementioned problems.
The present inventions include a method comprising:
The present inventions also include a drill bit for drilling a borehole into an earth formation, the drill bit being adapted to remove a body of selected material from the interior of a casing extending into the borehole, whereby during operation the drill bit has a longitudinal axis of rotation, the drill bit comprising rock cutting means, at least one protection member for protecting the inner surface of the casing from contact with the rock cutting means, each protection member being adapted to remove said selected material from the interior of the casing and being radially movable towards the inner surface of the casing, and control means for applying a radially outward force of controlled magnitude to the protection member.
Some embodiments of the invention will be described hereinafter in more detail and by way of example with reference to the accompanying drawings in which:
a-5d show various possible arrangements of rock cutters and protection members on the reamer arm;
In the drawings, like reference numerals refer to like parts.
Referring to
The reamer arm 8 is shown in more detail in
Furthermore, the protection member 12 is sufficiently wear-resistant to effectively clean the casing from undesired remains such as cement, but is of a significantly lower hardness than the rock cutters 10. In this manner it is achieved that the protection member 12 quickly wears away during further drilling of the borehole with the drill bit 1 in order that the protection member 12 does not hamper such further drilling. Suitably the protection member 12 may be made of tungsten-carbide or hardened and/or heat-treated steel. These materials are sufficiently wear resistant to provide the desired standoff and protection of the casing, but vanish quickly during drilling into the rock formation. The degree of wear-resistance of tungsten-carbide can be adapted to circumstances by modifying the amount of cobalt in the alloy and/or by modifying the particle size distribution of the alloy material.
Instead of applying a protection member adapted to wear away during drilling into the rock formation, a protection member can be applied which is radially retractable relative to the reamer arm 8 or relative to the rock cutters 10.
The protection member 12 is axially displaced from the rock cutters 10 in upward direction, i.e. in the direction opposite to the drilling direction of the drill bit 1. Thus the protection member 12 trails the rock cutters 10 and protects the casing inner surface until the rock cutters 10 are out of the casing during cleaning a lower end portion of the casing.
The protection member prevents contact between the rock cutting means and the inner surface of the casing, and further that the protection member does not cause any damage to the inner surface of the casing by virtue of the protection member being moved radially outward at a controlled force. Thus the protection member removes the undesired material from the interior of the casing in a safe manner.
Suitably the drill bit comprises a bit body and a reamer arm movable in radial direction relative to the axis of rotation, wherein the rock cutting means and each protection member are provided at the reamer arm, and wherein step c) comprises operating the control means so as to move the reamer arm in radially outward direction relative to the axis of rotation.
By radially extending the reamer arm, the protection member scrapes against the inside wall of the casing thereby cleaning the casing without the risk of the rock cutters damaging the casing.
Preferably the control means includes a pump for pumping drilling fluid to the drill bit, and wherein step c) comprises operating the pump so as to pump drilling fluid at a controlled flow rate to the drill bit.
In order to gradually remove the undesired material from the interior of the casing, suitably the drill bit is axially moved through the casing simultaneously with steps b) and c).
In
In
In
Referring further to
In
In
In
In an another embodiment the drill bit is first operated to drill a longitudinal bore in said body of selected material thereby forming an annular remainder portion of the body of selected material, and subsequently the drill bit is operated to remove the annular remainder portion whereby the drill bit is axially moved through said longitudinal bore.
It is preferred that the protection member suddenly or gradually wears away when the drill bit is operated to further drill the borehole so that the borehole can be drilled with its nominal drilling diameter as dictated by the rock cutting means without being obstructed by the protection member.
In an another embodiment, the protection member is sacrificial when it contacts the subterranean formation. This can be achieved for instance by providing the protection member with a material having a balanced wear resistance that is on one hand sufficiently wear resistant to prevent the rock cutting means to contact the casing inner surface and on the other hand wearable against the subterranean formation once the drill bit is outside the casing and drills the formation.
During normal operation the drill bit 1 is lowered into the casing 16 (
The drill string 15 is then further lowered until the drill bit extends below the bell section 18 of the casing 16 (
In a next step the pump rate is maintained at a level whereby each piston/cylinder assembly exerts a moderate radially outward force to the respective reamer arm 8. The drill string is simultaneously rotated and gradually moved upwardly. As the drill bit 1 moves upwardly through the longitudinal bore 16, the rock cutters 10 enlarge the longitudinal bore 16 and the protection members 12 of the respective reamer arms 8 scrape against the annular cement portion 27 which is thereby gradually removed. Since the force at which the protection members 12 are pushed radially outward is controlled at a moderate magnitude, there is no risk of significant damage to the inner surface of the casing 16 due to the scraping action of the protection members 12. At the same time the protection members 12, by virtue of their radial standoff, prevent the sharp rock cutters 10 to contact the casing 16.
Thus, the drill bit of the invention is particularly advantageous cleaning a casing shoe from cement remnants. The pilot bit section and/or the rock cutters of the reamer arms drill out a major part of the body of cement, and the protection members clean the inner surface of the casing in a safe manner by virtue of the standoff between the rock cutters and the casing wall. The protection member is suitably formed as a blunt cutting element. Also, the protection member can be formed as a scraper.
In an alternative mode of operation, the drill bit is lowered through the casing until the wiper plug (if present) or the cement body is reached. Drilling out is then started with the reamer arms in their retracted position until the bell section of the casing is reached. The drilling fluid pressure is then increased to above the selected pressure so as to break the shear pins and to allow the reamer arms to move radially outward. The protection members thereby engage with the bell section so as to clean the bell section from cement remnants. When the drill bit finally moves to below the casing bell section, the reamer arms can optionally be fully expanded in order to further drill and/or ream the borehole.
During such further drilling the protection members contact the subterranean rock formation and thereby wear at a high wear-rate so that possible negative effects of the purposively poor cutting properties of the protection members on the drilling performance, is mitigated.
During the normal mode of operation, the transition section between the bell section and the remainder casing section converges to a smaller diameter in upward direction. Such damage can be caused by the protection members as these move from the bell section into the remainder casing section if the protection members have somewhat sharp edges due to minor wear of the protection members during cleaning of the bell section.
Number | Date | Country | Kind |
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03104435 | Nov 2003 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2004/053125 | 11/26/2004 | WO | 00 | 5/25/2006 |
Publishing Document | Publishing Date | Country | Kind |
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WO2005/052301 | 6/9/2005 | WO | A |
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