The present invention relates to an expandable downhole tool apparatus for incorporation into a drill string used in the oil and gas industry to drill boreholes, and relates particularly, but not exclusively to a drill string incorporating such an expandable downhole tool apparatus.
Drill strings are used in the oil and gas industry to cut boreholes to reach pockets of oil and gas. A drill string comprises lengths of drill elements which are interconnected to lengthen the drill string as the drill string advances down a borehole.
To meet demand for energy, the drilling of oil and gas wells is becoming more and more complex in order to open up new reserves. Wells are drilled from land directionally and wells are also drilled in deeper and deeper formations. This means that drill strings can stretch up to several kilometers in length and may be curved to facilitate directional drilling. However, longer, directional drill strings are susceptible to becoming stuck which can cause a catastrophic failure of the drill string. It is therefore desirable to provide drill string elements having expandable parts that are less susceptible to becoming jammed in outward positions.
U.S. Pat. No. 4,693,328 describes an expandable roller reamer in which rollers are pivotally mounted to the body of the apparatus by two levers. A piston is longitudinally moveable along the axis of the body and comprises a cam surface. When fluid pressure in the drill string is increased, the piston moves upwardly along the body and the cam surface pushes the rollers outwardly. This apparatus suffers from the drawback that there are a large number of components that are moveable relative to one another to enable the rollers to be expanded outwardly. Consequently, there is a greater likelihood that one of these moveable parts could malfunction and prevent the tool from operating correctly, particularly if debris from the drilled borehole becomes lodged in the moving parts of the tool. This therefore leads to a risk that the rollers could be jammed in the outward position which could prevent the drill string from being retrieved from the borehole and cause a catastrophic failure.
GB2445862 describes a downhole stabiliser having stabilisers that deploy along a direction which is offset from the radius of the body. This apparatus suffers from the drawback that debris from the drilled borehole could become lodged between the tool and the stabilisers preventing retraction of the stabilisers and causing the drill string to become stuck.
Preferred embodiments of the present invention seek to overcome the above disadvantages of the prior art.
According to the present invention, there is provided an expandable downhole tool apparatus for incorporation into a drill string, the apparatus comprising:
This provides the advantage of providing a means for preventing accumulation of debris underneath and in the moving parts of a working member of a drill string element. If the working members are prevented from retraction, this can increase the difficulty of withdrawing the drill string from a bore hole and in some circumstances, cause the drill string to become jammed in the bore hole which leads to a catastrophic drill string failure.
The passages enable debris accumulating under the working member to fall out or to be pushed through the passage so that the working members can fully retract.
In a preferred embodiment, the body defines a longitudinal axis and at least one said working member is moveable relative to the body in a radial direction, and wherein at least one said passage extends non-radially away from the respective working member to a point on the surface of the body.
It has been found that this configuration of passage leading from the working member, through the tool body, and exiting at a point on the surface of the body is particularly effective at preventing accumulation of debris under the working members. In this configuration, the centrifugal force of the rotating drill string assists in moving debris along the passages to exit the body.
The apparatus may further comprise first and second pistons mounted in the body and moveable relative to the body between an inward retracted position and outwardly deployed activated position in response to fluid pressure in the body acting on respective surfaces of the first and second pistons disposed internally in the body, wherein at least one said working member is mounted between said first and second pistons and wherein at least one said passage extends from a location underneath the respective working member.
This provides the advantage of a working member configuration that enables the passage to extend from directly below the working member to assist removal of debris, for example when the working member moves to the inward retracted position it can push debris down the passage. Furthermore, this configuration also enables the size of the passage to be maximised.
Passages enable use of a closer tolerance between the diameters of the piston and pocket in the body in which the piston sits because debris can move from under the piston along passage rather than back out past the piston.
The apparatus may further comprise a cutter element disposed on an end of said first and/or second piston, the cutter element arranged to cut into the side of the borehole when the respective piston is in the outwardly deployed activated position.
The apparatus may further comprise:
This provides the advantage that the passages formed in the body do not form a concentrated weak point on the body. Staggering the working members and passages along the axial length of the body does not detrimentally affect the working ability of the apparatus while minimising the weakness and likelihood of breakage due to the body having passages formed therein.
At least one said working member may be a roller arranged to roll against the side of a borehole when in the outwardly deployed activated position to provide stabilisation to and reduce vibration and torque in a drill string in which the apparatus is incorporated.
It has been found that using the passage configuration in an expandable roller bearing provides a highly effective expandable roller bearing for stabilising long drill strings. The passages facilitate cycling of the tool and repeated expansion and retraction of the working members.
The apparatus may further comprise crushing means disposed on an outer surface of at least one said roller and being arranged to crush rock when the respective roller rolls against the side of a borehole.
In very hard formations, polycrystalline diamond (PDC) cutter bits or diamond drag bits are not so effective to cut the formation and can quickly become damaged which causes drilling to stop. For these hard formations, it is generally necessary to employ insert roller cone rock bits that roll on the formation crushing the rock and not cutting the rock. Consequently, the apparatus can be used in combination with crushing means dispersed on the stabilising rollers to crush rock and enlarge the hole in a ream while drilling operation. The passages increase the efficiency of the crushing rollers because debris moves quickly away from the crushed part of the wall of the bore hole.
Said crushing means may comprise a plurality of hardened inserts disposed in the outer surface of at least one said roller.
Each said hardened insert may comprise a substantially dome shaped portion arranged to contact and crush rock.
The apparatus may further comprise a thread disposed on the outer surface of at least one said roller, the thread arranged to engage the sides of a borehole and push the apparatus down the borehole.
This provides the advantage of a stabiliser that also helps a drill string advance down a hole.
According to a further aspect of the present invention, there is provided a drill string comprising a plurality of drill string elements and at least one expandable downhole tool apparatus as defined above.
Preferred embodiments of the present invention will now be described, by way of example only, and not in any limitative sense with reference to the accompanying drawings in which:
a is a cross-sectional view showing a roller assembly in the outwardly deployed activated position as shown in
b is a cross-sectional view corresponding to
a is a cross-sectional view of a piston in the inwardly retracted position showing the retaining member and shearable plate in the unsheared condition;
b is a view corresponding to
a is a longitudinal cross section of a downhole expandable roller bearing apparatus embodying the present invention showing the pistons in the outwardly deployed activated position;
b is a longitudinal cross section of the downhole expandable roller bearing apparatus of
c is an end view of the apparatus of
d is an end view of the apparatus of
Referring to
Expandable downhole tool apparatus 2 is mounted between a top sub 6 and a bottom sub 8. The apparatus 2 is adapted to be incorporated into a drill string comprising a drill bit (not shown) for use drilling well bores in the oil and gas industry as will be familiar to persons skilled in the art.
Referring to
Roller 12 is rotatably mounted between pistons 14a and 14b. Alternatively, roller 12 could be mounted to a single larger piston having two bushings between which the roller is mounted. Pistons 14a, 14b are arranged to be moveable relative to the body 4 between an inwardly retracted position (
Roller 12 comprises crushing means such as a plurality of hardened inserts 16. As shown in
Referring to
The pistons 14a and 14b move inwardly and outwardly in a radial direction relative to longitudinal axis X (
As a consequence of fluid pressure acting directly on internal surfaces 15a and 15b of the first and second pistons 14a and 14b, the pistons have a greater range of travel than prior art expandable downhole tools. This is because longitudinally moveable cam arrangements (such as in U.S. Pat. No. 4,693,328) are not required to force the rollers out by frictional contact. The space taken up by these components in the tool is therefore saved and can be used to accommodate longer piston stroke.
Each piston 14 comprises an aperture 30 formed through the body of the piston. This is best shown in
A retaining member 26 is removably mountable in the body to project into the respective aperture 30 in both the inwardly retracted and outwardly deployed activated positions of the pistons. Retaining member 26 therefore prevents removal of the corresponding piston 14 from the body and resists rotation of the piston 14 relative to the body. The retaining member 26 defines a retaining member axis that is parallel to the longitudinal axis of the body when mounted in the body. Also, as shown in
Use of retaining member 26 rather than a pin to hold the piston 14 in body 4 significantly increases the strength of the assembly. This helps to prevent removal of the piston 14 from body 4 and prevents rotation of the piston 14.
Referring to
Referring to
Alternatively, the plate 34 may mountable to the spline bar 26 by at least one shearable pin (not shown). The shearable pin may be adapted to break in response to an increase in fluid pressure in the body in order to enable the piston 14 to move to the outwardly deployed activated position.
Roller 12 is mounted on an axle 13. Once pressure is removed from piston chamber 24, the rollers 12 are pushed inwardly by reaction with the formation through which the drill string is moving. This enables easy retraction of rollers 12.
An expandable downhole tool apparatus embodying the present invention is shown in
Expandable downhole tool apparatus 202 comprises a body 204 adapted to be incorporated into a drill string and at least one working member 210 moveable relative to the body between an inward deactivated position and an outwardly deployed activated position in order to engage the wall of a borehole. Activation means adapted to move at least one said working member between the inward deactivated position and outwardly deployed activated position is provided. The activation means is the same as that described above in connection with the apparatus of
The apparatus 202 comprises three working members 210 in the form of rollers 212 rotatably mounted between respective pistons 214a and 214b. Alternatively, working members 210 can be under reamer bits for enlarging a borehole. Each piston 214a, 214b is disposed at a different location along the longitudinal axis of the body. This provides the advantage of increasing piston travel length. Since all of the pistons are located at different positions along the body, the internal ends of the pistons will not contact each other when retracted into the body. This is best shown in
Pistons 214a, 214b are deployed by an increase in fluid pressure in piston chamber 224 acting on internal piston surfaces 215a and 215b of the pistons. Pistons are held in the body by retaining member 226 projecting through piston aperture 230. It can be seen from
Also, since the rollers 212 only project out to half diameter, if the rollers encounter obstacles or impacts from large rocks they will tend to be pushed back into body 204 against the pressure of fluid in piston chamber 224. The extent to which the rollers 212 project outwardly from body 204 can be changed merely by altering the width of retaining member 226.
Each roller 212 comprises an associated passage 250 which as can been seen from
Since the passages 250, which are milled in the body 204 form weak points, the rollers 212 and passages 250 are formed at different locations along the longitudinal axis of the body to prevent a concentrated weak point as best shown in
Referring to
Referring to
Alternatively, the pistons and axle may be case hardened by nitriding or carburization or a combination of both. A hardened bushing 254 is disposed on piston 214a to receive end 213a of the axle 213. The hardened bushing 254 may be formed from a hardened material such as tungsten carbide or D2. By using these hardened materials, the lifespan of the roller bearing apparatus can be lengthened.
An expandable downhole tool of a second embodiment of the invention is shown in
Expandable downhole tool apparatus 302 comprises rollers 312 and passages 350 in common with the embodiment of
An expandable downhole tool of a third embodiment of the invention is shown in
Expandable downhole tool apparatus 402 comprises rollers 412 disposed between pistons 414a and 414b. Passages 450 are formed in the body 404. A cutter element 444 is disposed on the end of each piston 414. The cutter elements 444 may be formed from polycrystalline diamond (PDC) or may comprise tungsten carbide inserts. Consequently, this embodiment can be used as a combined stabiliser and under-reamer.
An expandable downhole tool of a fourth embodiment of the invention is shown in
This embodiment is a combination of rollers having crushing means and also windows formed underneath the rollers to prevent accumulation of debris under the rollers. Apparatus 502 comprises rollers 512 on which crushing means are disposed. The crushing means may for example comprise a plurality of hardened inserts or buttons 516. Hardened inserts may be formed from tungsten carbide. Windows 550 are formed through the body 504. When the drill string is advancing downhole in a particularly hard formation, the rollers can be used to crush rock. For example, with PDC or tungsten carbide inserts 516 having a domed shaped configuration being inserted in the rollers, the formation can be enlarged.
For example, if the internal surfaces 515a, 515b of pistons 514a and 514b have an area of 10 square inches each, and the pressure differential between piston chamber 524 and the outside of the apparatus is 1000 psi, 20,000 pounds of force will be applied to each of the three rollers around the apparatus. This is sufficient force to crush hard rock formations with hardened roller inserts. In this embodiment, hardened bushings axles and pistons would be used as shown in
It will be appreciated by person skilled in the art that the above embodiments have been described by way of example only and not in any limitative sense, and that various alterations and modifications are possible without departure from the scope of the invention as defined by the appended claims. In particular, features of the embodiments described above can be interchanged, such as different combinations of cutters, rollers, passages, hardened roller inserts and hardened components. Also, the rollers could be solid in construction and rotatably mounted to the pistons directly rather than being mounted on a non-rotatable axle. Furthermore, a roller could be rotatably mounted to a single piston, rather than being rotatably mounted between two pistons, such that only a single piston having two bushings for example is provided for each roller assembly.
Number | Date | Country | Kind |
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0914629.1 | Aug 2009 | GB | national |
0919787.2 | Nov 2009 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/GB2010/051380 | 8/20/2010 | WO | 00 | 3/21/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2011/021048 | 2/24/2011 | WO | A |
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