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EP 1 191 000 B1 |
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EUROPEAN PATENT SPECIFICATION |
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Mention of the grant of the patent: |
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09.06.2004 Bulletin 2004/24 |
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Date of filing: 07.09.2001 |
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Rotary drill bit
Rotationsbohrerspitze
Mèche rotative
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Designated Contracting States: |
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BE DE FR GB IE |
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Priority: |
20.09.2000 US 234075 P 02.04.2001 US 281054 P
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Date of publication of application: |
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27.03.2002 Bulletin 2002/13 |
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Proprietor: Camco International (UK) Limited |
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Stonehouse,
Gloucestershire GL10 3RQ (GB) |
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Inventors: |
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- Hughes, Peter Raymond
Stroud,
Gloucestershire GL5 4SG (GB)
- Griffin, Nigel Dennis
Whitminster,
Gloucester GL2 7PS (GB)
- Matthias, Terry R.
U. St. Leonards,
Gloucestershire GL4 8AH (GB)
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(74) |
Representative: Bailey, Richard Alan |
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A.R. Davies & Co.,
27 Imperial Square Cheltenham, Gloucestershire GL50 1RQ Cheltenham, Gloucestershire GL50 1RQ (GB) |
(56) |
References cited: :
EP-A- 0 546 725
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WO-A-00/28106
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Note: Within nine months from the publication of the mention of the grant of the European
patent, any person may give notice to the European Patent Office of opposition to
the European patent
granted. Notice of opposition shall be filed in a written reasoned statement. It shall
not be deemed to
have been filed until the opposition fee has been paid. (Art. 99(1) European Patent
Convention).
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BACKGROUND OF THE INVENTION
1. Field of the Invention.
[0001] This invention relates to a rotary drill bit for use in the formation of wellbores.
In particular, the invention relates to a rotary drag-type drill bit of improved stability,
particularly when worn. A drill bit of this type typically comprises a bit body having
a shank for connection to a drill string, a plurality of blades formed on the bit
body extending outwardly from a central axis of rotation of the bit, and a plurality
of cutting elements mounted along each blade.
2. Description of the Prior Art.
[0002] The bit body may be machined from solid metal, or may alternatively be molded using
a powder metallurgy process in which a tungsten carbide powder is infiltrated with
a metal alloy binder in a furnace so as to form a hard matrix.
[0003] Typically, the cutters each take the form of a tablet of superhard material bonded
to a substrate, for example of tungsten carbide. Each cutter is typically of circular
or part-circular shape.
In some drill bits, the cutters are arranged upon the blades at different radial distances
to one another so that the cutters sweep over the full area of the bottom of the wellbore.
However, there is a tendency for drill bits of this type to be of relatively low stability.
[0004] In order to improve the stability, it is known to arrange the cutters in a series
of concentric rings at different cutting heights. As a result, the drill bit tends
to form, in the bottom of the wellbore, a series of corrugations or rings. The co-operation
between the drill bit and the pattern formed in the bottom of the wellbore tends to
resist lateral movement of the bit, resulting in the drill bit being of improved stability.
In the past, drill bit designs were compromised because cutters having high abrasion
resistance had low impact toughness and cutters having high impact toughness had low
abrasion resistance. As a result of this trade-off such placement of the cutters may
improve the abrasion resistance of the drill bit, but it is likely that the overall
drilling efficiency is not optimized due to relatively poor impact toughness.
[0005] Drill bits of this type are known as tracking drill bits and are described in, for
example, GB 2294712 and GB 2292163.
[0006] Document EP-A-0 546 725 discloses a drill bit with cutters of different impact toughness.
BRIEF SUMMARY OF THE INVENTION
[0007] It is an object of the invention to provide a drill bit of good stability, particularly
when the drill bit becomes worn.
[0008] According to the present invention there is provided a rotary drill bit comprising
a bit body having an axis of rotation, a plurality of cutters mounted upon the bit
body in a plurality of concentric rings centered upon the axis of rotation, wherein
said plurality of cutters comprises a first type of cutter of relatively low abrasion
resistance and a second type of cutter of relatively high abrasion resistance, at
least one of said concentric rings consisting of cutters of the first type, at least
another of said concentric rings including at least one cutter of said second type.
The impact toughness of all the cutters is substantially the same.
[0009] It will be appreciated, in use, that the cutters of the first type will wear at a
higher rate than those of the second type with the result that a drill bit which initially
has a reasonably uniform cutting profile will, when worn, form grooves in the formation
being drilled. As a result, the stability of the drill bit improves with wear.
[0010] Preferably, the cutters of the second type each include a polycrystalline diamond
table treated so as to render a region thereof close to a cutting edge thereof substantially
free of a material having a catalyzing effect. Cutters of this type have been found
to have an improved wear and abrasion resistance when compared with cutters not so
treated and yet have substantially the same impact toughness as the first type of
cutters.
[0011] According to another aspect of the invention there is provided a rotary drill bit
comprising a bit body having a leading face and an axis of rotation, the leading face
having a plurality of angularly spaced blades, each said blade carrying a plurality
of cutters, wherein said plurality of cutters includes a first type of cutter having
a relatively low abrasion resistance and a second type of cutter having a relatively
high abrasion resistance, and wherein at least one of said blades carries at least
one cutter of the first type and at least one cutter of the second type. The impact
toughness of all the cutters is substantially the same.
[0012] Preferably, the cutters on each blade of the first type are arranged alternately
with cutters from the second type.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] The invention will further be described, by way of example, with reference to the
accompanying drawings.
Figure 1 is a perspective view of a drill bit.
Figure 2 is a diagrammatic view of an end of the drill bit of Figure 1.
Figure 3 is a view of one of the blades of the drill bit of Figure 1, before use.
Figure 4 is a view similar to Figure 3 illustrating the bit when worn.
Figure 5 is a diagrammatic view illustrating the structure of part of one of the cutters.
Figure 6 is a diagrammatic view of one of the cutters.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
[0014] The accompanying drawings illustrate a rotary drill bit of the rotary drag-type comprising
a bit body 10 of machined steel form. The bit body 10 has a leading face 12 provided
with a plurality of upstanding, radially spaced blades 14. Each blade 14 carries a
plurality of cutters 16. Between each pair of adjacent blades 14 is defined a channel
18 which is supplied, in use, with drilling fluid through a series of passages 20
provided internally of the drill bit body 10, each passage 20 terminating at a nozzle
22. The supply of drilling fluid serves to clean and cool the cutters 16, in use.
[0015] The bit body 10 is shaped to include a shank 24 to permit the drill bit to be connected
to the remainder of a drill string and to permit the bit to be driven to rotate about
an axis of rotation 34 thereof.
[0016] As illustrated in Figure 2, the cutters 16 are arranged on the blades 14 in a series
of concentric rings 26, 28, 30, 32. The concentric rings 26, 28, 30, 32 are centered
upon the axis of rotation 34 of the bit body 10.
[0017] The drill bit includes cutters 16 of two different types. A first type of cutters
16a provided on the drill bit have a relatively low abrasion resistance, a second
type of cutters 16b provided on the drill bit having a higher abrasion resistance.
The cutters 16 are arranged such that the first ring 26 of cutters is made up exclusively
of cutters 16a of the first type, the second ring 28 is made up exclusively of cutters
16b of the second type, the third ring 30 is made up exclusively of cutters 16a of
the first type, and the fourth ring 32 is made up exclusively of cutters 16b of the
second type. It will be appreciated, therefore, that the cutters 16 mounted upon each
blade 14 are arranged such that cutters 16a of the first type alternate with cutters
16b of the second type.
[0018] Figure 3 illustrates, diagrammatically, the drill bit of Figures 1 and 2 prior to
use. It will be noted from Figure 3 that all of the cutters 16 are of circular shape.
Figure 4 is a view similar to Figure 3 illustrating the drill bit after use. It will
be noted from Figure 4 that the use of the drill bit has resulted in wear occurring
to the cutters 16. It will further be noted from Figure 4 that the cutters 16a of
the first type have worn to a greater extent than the cutters 16b of the second type.
As a result, the cutting profile of the drill bit has changed from being of relatively
uniform shape as shown by the line 16c in Figure 3 at the commencement of use to being
shaped to form a series of concentric ridges in the formation being drilled as shown
by the line 16d in Figure 4. It will be appreciated that the co-operation between
the drill bit and the pattern of concentric ridges and grooves formed in the wellbore,
in use, results in the worn drill bit being of relatively good stability. The good
stability arises as a result of the resistance to lateral movement of the drill bit
resulting from co-operation between the drill bit and the grooved formation.
[0019] Although the cutters 16 could potentially take a range of different forms, in one
particularly advantageous form, each cutter 16 comprises a table 40 of polycrystalline
diamond bonded to a tungsten carbide substrate 42, as shown in Figure 6. It has been
found that the abrasion resistance of a cutter of this type can be increased by leaching
or otherwise removing from the part of the cutter 16 adjacent a working surface 44
thereof the catalyzing materials used in the formation of the cutter. Thus, in one
embodiment, the cutters 16a may be of the form in which the catalyzing material has
not been leached from the polycrystalline diamond, the cutters 16b being of the type
in which such leaching has occurred. Figure 5 illustrates, diagrammatically, the structure
of a part of one of the cutters 16b. In Figure 5, a matrix of interstices is shown
between the crystals 34 of the polycrystalline diamond table. During the formation
of the polycrystalline diamond table, the interstices house a catalyzing material
36, for example in the form of cobalt. As mentioned above, it has been found that
by removing the catalyzing material from the interstices, the abrasion resistance
of the polycrystalline diamond table can be increased. In Figure 5, the cobalt material
36 has been leached from the polycrystalline diamond table to a depth D, thus leaving
the interstices 38 close to the working surface 44 of the polycrystalline diamond
table 40 substantially free of catalyzing material.
[0020] Although in the description hereinbefore, the interstices 38 close to the working
surface 44 are described as being rendered substantially free of catalyzing material
by leaching the catalyzing material from the polycrystalline diamond. The improvement
in the abrasion resistance of the material may alternatively be achieved by converting
the catalyzing material to a form in which it does not have a catalyzing effect or
by reacting the catalyzing material with another material to form a substance which
does not have a catalyzing effect. Further, if desired, only a proportion of the catalyzing
material may be removed from the interstices 38 close to the working surface 44.
[0021] Although the cutters 16a, 16b described hereinbefore comprise a first set in which
the catalyzing material is present close to the working surface 44 of the cutter 16
and a second set in which the catalyzing material is removed, it will be appreciated
that one or other of these sets of cutters could take the form of cutters in which
only a proportion of the catalyzing material has been removed from the part of the
cutter adjacent the working surface thereof. In the hereinbefore described manufacturing
process for improving wear resistance, as the wear resistance of a cutter improves,
its ability to withstand impact is substantially retained. Therefore, although the
cutters may be made with varying wear resistance, the impact toughness for the cutters
is substantially the same, unlike cutters of the prior art. Further, if desired, the
drill bit could include, in addition to rings of relatively low and relatively high
abrasion resistance cutters, rings of cutters of an intermediate abrasion resistance.
[0022] Although in the arrangement described hereinbefore, at least some of the rings are
formed exclusively of cutters of the second type, it will be appreciated that, if
desired, one or more of the rings of cutters could be made up of a mixture of cutters
of the first and second types.
[0023] Further variations are possible, for example, the first type of cutter and the second
type of cutter may differ from one another in that the cutters of the second type
are treated to remove catalyzing material to a greater depth than those of the first
type. Such treatment will result in the wear and abrasion characteristics of the two
types of cutter differing from one another with the result that the cutting profile
of the worn bit will be grooved. A similar effect may be achieved using cutters of
differing abrasion resistance and differing size.
[0024] The provision of a drill bit which becomes more stable with wear is beneficial as
the tendency for a bit to deviate from a desired path is relatively low when bits
are new, the tendency to deviate increasing with wear.
1. A rotary drill bit comprising a bit body having an axis of rotation, and a plurality
of cutters arranged in concentric rings centered on the axis of rotation, the plurality
of cutters comprising a first type of cutter of a relatively low abrasion resistance
and a second type of cutter of a relatively high abrasion resistance, at least one
of the rings consisting of cutters of the first type, at least another of the rings
including at least one cutter of the second type, wherein the first type of cutter
has substantially the same impact toughness as the second type of cutter.
2. A rotary drill bit according to Claim 1, wherein said at least another of the rings
consists of cutters of the second type.
3. A rotary drill bit according to Claim 1, wherein the bit body is provided with a plurality
of blades each carrying a plurality of cutters, the cutters of the first type and
cutters of the second type being arranged in an alternating pattern along each blade.
4. A rotary drill bit according to Claim 1, wherein each cutter of the second type comprises
a table of polycrystalline diamond which defines a matrix of interstices containing
a catalyzing material, and wherein the interstices close to a working surface of the
table contain less catalyzing material than the interstices spaced from the working
surface.
5. A rotary drill bit according to Claim 4, wherein the interstices close to the working
surface are substantially free of catalyzing material.
6. A rotary drill bit according to Claim 4, wherein each cutter of the first type comprises
a table of polycrystalline diamond which defines a matrix of interstices containing
a catalyzing material, the interstices within a volume close to a working surface
of the table containing more catalyzing material than those of a similar volume of
each cutter of the second type.
7. A rotary drill bit comprising a bit body having an axis of rotation, and a plurality
of blades angularly spaced around the axis of rotation, a plurality of cutters being
mounted upon the blades, the plurality of cutters comprising a plurality of cutters
of a first type having a relatively low abrasion resistance and a plurality of cutters
of the second type having a relatively high abrasion resistance, at least one of the
blades having mounted thereon at least one of the cutters of the first type and at
least one of the cutters of the second type, wherein the first type of cutters has
substantially the same impact toughness as the second type of cutters.
8. A rotary drill bit according to Claim 7, wherein the cutters of the first type are
arranged in an alternating pattern with the cutters of the second type on the said
at least one blade.
9. A rotary drill bit according to Claim 7, wherein the cutters are arranged in a plurality
of concentric rings centered on the axis of rotation.
10. A rotary drill bit according to Claim 9, wherein at least one of said rings consists
of cutters of the first type, and at least another of said rings includes at least
one cutter of the second type.
1. Rotary-Bohrmeißel, der aufweist: einen Meißelkörper mit einer Rotationsachse; und
eine Vielzahl von Schneidelementen, die in konzentrischen Ringen zentriert auf der
Rotationsachse angeordnet sind, wobei die Vielzahl der Schneidelemente einen ersten
Typ von Schneidelement mit einer relativ niedrigen Verschleißfestigkeit und einen
zweiten Typ von Schneidelement mit einer relativ hohen Verschleißfestigkeit aufweist,
wobei mindestens einer der Ringe aus Schneidelementen des ersten Typs besteht, wobei
mindestens ein weiterer der Ringe mindestens ein Schneidelement des zweiten Typs umfaßt,
wobei der erste Typ des Schneidelementes im wesentlichen die gleiche Schlagfestigkeit
wie der zweite Typ des Schneidelementes aufweist.
2. Rotary-Bohrmeißel nach Anspruch 1, bei dem der mindestens ein weiterer der Ringe aus
Schneidelementen des zweiten Typs besteht.
3. Rotary-Bohrmeißel nach Anspruch 1, bei dem der Meißelkörper mit einer Vielzahl von
Flügeln versehen ist, von denen ein jeder eine Vielzahl von Schneidelementen trägt,
wobei die Schneidelemente des ersten Typs und die Schneidelemente des zweiten Typs
in einem abwechselnden Muster längs eines jeden Flügels angeordnet sind.
4. Rotary-Bohrmeißel nach Anspruch 1, bei dem ein jedes Schneidelement des zweiten Typs
eine Platte aus polykristallinem Diamant aufweist, die ein Grundmaterial mit Zwischenräumen
definiert, die ein katalysierendes Material enthalten, und bei dem die Zwischenräume
nahe einer Arbeitsfläche der Platte weniger katalysierendes Material enthalten als
die Zwischenräume, die von der Arbeitsfläche beabstandet sind.
5. Rotary-Bohrmeißel nach Anspruch 4, bei dem die Zwischenräume nahe der Arbeitsfläche
im wesentlichen frei von katalysierendem Material sind.
6. Rotary-Bohrmeißel nach Anspruch 4, bei dem ein jedes Schneidelement des ersten Typs
eine Platte aus polykristallinem Diamant aufweist, die ein Grundmaterial mit Zwischenräumen
definiert, die ein katalysierendes Material enthalten, wobei die Zwischenräume innerhalb
eines Volumens nahe einer Arbeitsfläche der Platte mehr katalysierendes Material enthalten
als jene eines gleichen Volumens eines jeden Schneidelementes des zweiten Typs.
7. Rotary-Bohrmeißel, der aufweist: einen Meißelkörper mit einer Rotationsachse; und
eine Vielzahl von Flügeln, die winkelig um die Rotationsachse beabstandet sind, wobei
eine Vielzahl von Schneidelementen auf den Flügeln montiert ist, wobei die Vielzahl
der Schneidelemente eine Vielzahl von Schneidelementen eines ersten Typs mit einer
relativ niedrigen Verschleißfestigkeit und eine Vielzahl von Schneidelementen des
zweiten Typs mit einer relativ hohen Verschleißfestigkeit aufweist, wobei mindestens
einer der Flügel darauf mindestens eines der Schneidelemente des ersten Typs und mindestens
eines der Schneidelemente des zweiten Typs montiert aufweist, wobei der erste Typ
der Schneidelemente im wesentlichen die gleiche Schlagfestigkeit aufweist wie der
zweite Typ der Schneidelemente.
8. Rotary-Bohrmeißel nach Anspruch 7, bei dem die Schneidelemente des ersten Typs in
einem abwechselnden Muster mit den Schneidelementen des zweiten Typs auf dem mindestens
einen Flügel angeordnet sind.
9. Rotary-Bohrmeißel nach Anspruch 7, bei dem die Schneidelemente in einer Vielzahl von
konzentrischen Ringen zentriert auf der Rotationsachse angeordnet sind.
10. Rotary-Bohrmeißel nach Anspruch 9, bei dem mindestens einer der Ringe aus Schneidelementen
des ersten Typs besteht und mindestens ein weiterer der Ringe mindestens ein Schneidelement
des zweiten Typs umfaßt.
1. Trépan de forage rotatif comprenant un corps de trépan comportant un axe de rotation,
et plusieurs éléments de coupe agencés dans des anneaux concentriques centrés sur
l'axe de rotation, les plusieurs éléments de coupe comprenant un premier type d'éléments
de coupe présentant une résistance à l'abrasion relativement réduite, et un deuxième
type d'éléments de coupe présentant une résistance à l'abrasion relativement élevée,
au moins un des anneaux englobant des éléments de coupe du premier type, au moins
un autre des anneaux englobant au moins un élément de coupe du deuxième type, le premier
type d'éléments de coupe présentant une résistance au choc pratiquement identique
à celle du deuxième type d'éléments de coupe.
2. Trépan de forage rotatif selon la revendication 1, dans lequel ledit au moins un autre
des anneaux englobe des éléments de coupe du deuxième type.
3. Trépan de forage rotatif selon la revendication 1, dans lequel le corps du trépan
comporte plusieurs lames, supportant chacune plusieurs éléments de coupe, les éléments
de coupe du premier type et les éléments de coupe du deuxième type étant agencés dans
une configuration alternée le long de chaque lame.
4. Trépan de forage rotatif selon la revendication 1, dans lequel chaque élément de coupe
du deuxième type comprend une table de diamant polycristallin définissant une matrice
d'interstices contenant un matériau catalyseur, les interstices proches d'une surface
de travail de la table contenant moins de matériau catalyseur que les interstices
espacés de la surface de travail.
5. Trépan de forage rotatif selon la revendication 4, dans lequel les interstices proches
de la surface de travail sont pratiquement exempts de matériau catalyseur.
6. Trépan de forage rotatif selon la revendication 4, dans lequel chaque élément de coupe
du premier type comprend une table de diamant polycristallin définissant une matrice
d'interstices contenant un matériau catalyseur, les interstices agencés dans un volume
proche d'une surface de travail de la table contenant plus de matériau catalyseur
que ceux d'un volume similaire de chaque élément de coupe du deuxième type.
7. Trépan de forage rotatif comprenant un corps de trépan comportant un axe de rotation,
et plusieurs lames espacées angulairement autour de l'axe de rotation, plusieurs éléments
de coupe étant montés sur les lames, les plusieurs éléments de coupe comprenant plusieurs
éléments de coupe d'un premier type, présentant une résistance à l'abrasion relativement
réduite, et plusieurs éléments de coupe d'un deuxième type présentant une résistance
à l'abrasion relativement élevée, au moins une des lames comportant au moins un des
éléments de coupe du premier type et au moins un des éléments de coupe du deuxième
type qui y sont montés, le premier type d'éléments de coupe présentant une résistance
au choc pratiquement identique à celle du deuxième type d'éléments de coupe.
8. Trépan de forage rotatif selon la revendication 7, dans lequel les éléments de coupe
du premier type sont agencés dans une configuration alternée avec les éléments de
coupe du deuxième type sur ladite au moins une lame.
9. Trépan de forage rotatif selon la revendication 7, dans lequel les éléments de coupe
sont agencés dans plusieurs anneaux concentriques centrés sur l'axe de rotation.
10. Trépan de forage rotatif selon la revendication 9, dans lequel au moins un desdits
anneaux englobe des éléments de coupe du premier type, au moins un autre desdits anneaux
englobant au moins un élément de coupe du deuxième type.