The present invention is directed to a downhole tool, and more particularly to a flexible casing guide running tool.
In oil and gas exploration and production operations, bores are drilled to gain access to subsurface hydrocarbon-bearing formations. The bores are typically lined with steel tubing, known as tubing, casing or liner, depending upon diameter, location and function. The tubing is run into the drilled bore from the surface and suspended or secured in the bore by appropriate means, such as a casing or liner hanger. For casing, cement may then be introduced into the annulus between the tubing and the bore wall.
As the tubing is run into the bore, the tubing end will encounter irregularities and restrictions in the bore wall, for example ledges formed where the bore passes between different formations and areas where the bore diameter decreases due to swelling of the surrounding formation. Further, debris may collect in the bore, particularly in highly deviated or horizontal bores. Accordingly, the tubing end may be subject to wear and damage as the tubing is lowered into the bore. These difficulties may be alleviated by providing a ‘shoe’ on the tubing end. Examples of casing shoes of various forms are well known in the art.
Another problem that some drilling engineers have described is the difficulty of running casing through build sections. More specifically, there is difficulty in running large diameter casing through the build section of a well in moderate to so ft formations. The stiffness of the casing requires a significant force that must be generated at the casing shoe to cause the casing to bend to follow the curved section of the wellbore.
In one example, it is necessary to run steel casing with a 16.5 inch outside diameter (OD) and 14.8 inch inside diameter (ID) through a planned wellbore curvature of 1 to 2 deg/100 ft to an inclination of 62 degrees. FEA (finite element analysis) studies can be used to determine the force required to deflect the 16.5 inch steel casing described above through various curved wellbores.
Because wells cannot be drilled exactly as planned, and exhibit some deviation from the planned wellpath, a statistical analysis of similar wells indicates that a planned wellbore curvature of 1 to 2 deg/100 ft will likely result in a maximum measured curvature of 3 to 4 deg/100 ft, with an instantaneous maximum curvature of up to 6 to 8 deg/100 ft in some areas.
In the example given above, a force of up to 15,100 lbs could be required to deflect the casing through a maximum curvature condition. This force, when acting through the leading radius of the casing shoe, would generate a large compressive stress on the rock formation, possibly enough to cause the casing to ‘dig in’ to the formation instead to traversing through the curve. Consequently, a need exists to provide a solution against digging into the well formation.
Most casing ‘shoes’ or leading edge surfaces are radiused, but still represent a fairly small contact area. Therefore large deflection forces result in large compressive stress on the downhole rock formation. If the stress is greater than the strength of the rock formation, the casing will not deflect, but will instead attempt to go straight and will dig into the formation, preventing the casing from travelling down the wellbore.
Potential solutions to the problem are either to increase the contact area or reduce the force required to deflect the casing to allow the shoe or nose of the casing to follow the wellbore. The present invention provides a solution to decrease the deflection force required by including a short, 20 to 500 ft, guiding section in front of the normal casing with a lower stiffness than the casing.
Stiffness of the casing is represented by the product of the modulus of elasticity (E) and area moment of inertia (I). Lowering the stiffness can be accomplished by attaching a short (20 to 500 ft) cylindrical or tubular ‘guide’ in front of the casing that has stiffness (EI) that is about 5% to about 80%, and more preferably about 5% to about 25% of the stiffness of the casing to be run. The lower stiffness of the leading cylindrical or tubular guide section would allow it to more easily deflect and travel down the intended wellbore without causing undue stress on the formation. Once this lower stiffness section had entered the curved portion of the wellbore, it would be able to distribute the additional bending force required to deflect the higher stiffness casing behind it and therefore prevent the casing from ‘digging in’ to the wellbore and rock formations.
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One embodiment of this invention would be to produce a section of aluminum tubing as the flexible casing guide 16. Because the modulus “E” of aluminum is approximately 37% of steel, so too would be the stiffness of aluminum tubing with the same geometry as the steel casing to be run.
In other embodiments, fiber reinforced composites such as glass, aramid, or carbon fiber with a thermoplastic or thermoset polymer matrix could be utilized to produce a cylindrical guide with a reduced stiffness compared to steel. As an example, glass reinforced epoxy has a typical modulus that is approximately 9% of steel, but the stiffness of these composites can be adjusted by changing the fiber material, fiber orientation and fiber volume fraction to match any desired modulus or elasticity.
Other potential solutions include reducing the OD or wall thickness of the guide which would further reduce area moment of inertia and therefore the stiffness of the guide. In addition, the guide could be created so that the leading edge stiffness is on the lower end of the range (about 5% to about 15% of casing stiffness) with the guide's stiffness increasing as it approaches the junction with the steel casing to provide support to enable the transfer of the deflection force from the casing to the guide so that the stress on the formation required to deflect the casing down the wellbore does not exceed the strength of the formation. The diameter of the guide will depend on the diameter of the casing, however the guide can range in diameter sizes from about 3 inches to about 30 inches.
Because the guide is positioned at the end of the casing string, it may also have the features of the bottom of most casing strings. It should have a radius or chamfer on the leading edge or ‘shoe’ to provide a ramp to enable the generation of the deflection force, and to spread out the force by increasing the contact area at the leading edge as much as possible. The guide may also have ‘auto fill’ valves 22 or other equipment to enable the casing to fill with fluid as it enters the hole, but also enable cementing after the casing has been run to its final depth. The guide can be connected to the casing by a threaded connection.
Casing to be run:
Flexible Casing Guide:
The flexible casing guide 16 has about 5% to about 80% of the stiffness (EI) of the steel wellbore casing 10 that is to be run and preferably would have about 10% to about 50% of the stiffness of the casing. The guide may have increasing stiffness closer to the casing. The guide may use lower modulus (E) material, or a design with lower area moment of inertia (I), or both.
The guide is constructed out of a material that is lower in modulus (E) compared to steel casing and can include aluminum, fiber reinforced composites such as fiberglass, carbon, or Kevlar, or titanium. The guide utilizes a lower area moment of inertia (I) compared to steel casing, through having a smaller OD, a thinner wall thickness, and/or a narrowed cross section.
The length of guide is determined based on strength of the formation, curvature of the wellbore, and/or the stiffness of casing to be run, etc. The length will be between 20 to 500 ft, preferably between 40 to 200 ft. FEA analysis and calculation of EI (stiffness) is used to determine deflection loads. Evaluation of formation, well shape/wellpath data, and casing will affect length. Lower formation strength equals less length required. Stiff, large diameter, heavy wall casing equals greater length required.
The guide does not need to be pressure tight and auto fill and float equipment could be located between the casing and the guide. In addition the guide could include ports to circulate cement. The guide may include possible steel connections or a cross-over to allow easy makeup of the guide on the rig to reduce risk of cross-threading or galling when making up threaded connections. The flexible casing guide may also have low-friction inserts or materials to decrease running friction.
The flexible casing guide allows large diameter casing to be run and will minimize the risk of the casing getting stuck while running through a dog-leg or curvature in the wellbore. The guide may be used in directional deepwater wells using large, very stiff casing strings, particularly in deepwater wells with a build section or for a need in vertical wells with unplanned dog-leg or wellbore curvature. The guide may also be used in horizontal wells, which have high build rates and dog-leg severity which requires relatively stiff casing to traverse the build section. The flexible casing guide would allow casing to more smoothly run through the 10-15 deg/100 ft build section without getting stuck or digging in to the formation.
As shown if
As seen best in
The steel crossover 38 includes threads to mate with threads 36 to attach to the aluminum connector. The opposite end of the steel crossover can include whatever type of connection is necessary for attachment to the casing or other applications.
The nose assembly 28 includes an aluminum connector 40 having threads to connect to threads 36 for aluminum connector 32. The nose assembly further includes a one piece polyurethane nose section 42 having a conical taper to allow easy passage into cutting beds and through liner tops, etc, while maintaining some flexibility to distribute point loads. The nose section 42 includes an opening 44 positioned in an end surface of the nose section.
The preferable stiffness of the flexible casing guide 16 is about 5% to about 25% of the stiffness of the casing to be run. For an embodiment which uses a low modulus material, such as glass fiber reinforced composite using a thermoset matrix material, if the low modulus material were bonded or joined directly to the high modulus steel material, the stresses would be very high. Consequently, the transition between the very stiff high modulus steel casing and the low modulus composite material, a material with an intermediate modulus or stiffness is used to reduce the stress levels at the interface. By bonding or joining the composite to aluminum, the interface stresses are greatly reduced. Consequently, the composite tube is formed around an aluminum interface or connector, approximately 1 to 4 feet long which is then joined to the steel crossover. As indicated, the aluminum connectors include circumferential protrusions or ribs and the aluminum connectors are placed on a mandrel and the composite material is wound onto the cylindrical mandrel and the aluminum connectors. When the composite material is cured, the ribs serve to lock the composite tube onto the aluminum connector. In this embodiment, the steel crossover has an E=30×106 PSI, the aluminum connector has a E=10×106 PSI and the glass fiber composite tube has a E=1.0×106.
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While the present invention has been described and illustrated with respect to several embodiments thereof, it is to be understood that changes and modifications can be made therein which are within the intended scope of the invention as hereinafter claimed.
This application claims priority to and the benefit of U.S. Provisional Application No. 61/717,941, filed Oct. 24, 2012 the contents of which are incorporated herein by reference.
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