The present disclosure generally relates to drill pipe, casing, and tubing used to locate and produce hydrocarbons in a subterranean environment and more specifically to a connection for joining sections of one of drill pipe, casing, and tubing together.
Large portions of hydrocarbon location and production activities involve drilling, pumping, and conduit installation beneath the earth's surface. Drilling, pumping, and conduit installation operations may include water location and distribution. Drilling, pumping, and conduit installation operations may also include sewage processing and distribution, or support installation of electrical power lines or telecommunications transmission lines. Drilling, pumping, and conduit installation activities often use lengths of pipes, which may be joined together in a variety of different manners. There are several considerations associated with joining pipes. For example, drilling activities may require torque to be transmitted across numerous pipes. Thus a joint may need to be strong enough to transmit torque and resist failure.
Additionally, some industry standards exist related to pipe section diameters. For example, internal pipe diameters are often standardized so expected flow and capacity of the drill string can be achieved. Standards also exist concerning pipe outer diameters that dictate clearances between the outer pipe surface and a wellbore casing, for example. Thus there are often limits on material sizes and thicknesses that can be used for drill pipe segments.
Currently, pipe segments are joined with threaded connections. Although a threaded connection will adequately join pipe segments, a threaded connection does not transfer torque effectively while rotating both to the left and to the right. That is, threads may loosen or disengage when the pipe segments are rotated in a direction opposite the direction used to tighten to pipe segments together. Some have addressed this issue by adding teeth to the ends of threaded joint sections. Teeth may be capable of transferring torque interconnected pipe segments, even if the pipe segments are rotated in a direction counter the tightening direction. But teeth are often ineffective and result in a weakened joint.
Drill pipe segments of the prior art are often made of steel alloy, such as 4140 steel or other steel alloys. As one of ordinary skill in the art will appreciate, such pipe segments are heavy and difficult to manage. As described in U.S. Pat. No. 3,126,214 to Wong, previous attempts to reduce drill pipe weight entailed providing an aluminum drill pipe with stainless steel joints adapted to interconnect two or more drill pipe segments together. For example,
One of ordinary skill in the art will appreciate that one drawback of the current method of joining stainless steel joint sections 2 and aluminum drill pipe section is that premature joint section cooling will prevent complete integration of the joint section to the pipe section. If the interconnection of joint section to pipe section is not ideal, the joint section cannot simply be removed by re-heating, as the heat required for joint section expansion will adversely affect the aluminum drill pipe section.
It is appreciated that one may postulate that further weight reductions can be achieved if both the drill pipe section and the joint sections are made of aluminum. The use of an aluminum drill pipe with threaded end interconnections as found in the prior art would weaken the drill string because under the conditions normally experienced in drilling operations, the threads of interconnected aluminum drill pipe joint segments would adhere and gall. Galling may lead to catastrophic failure. Further, even if an anti-galling coating is used, aluminum threads are weak and, thus, are not ideal to transfer torque.
Those of ordinary skill in the art will also appreciate that because steel joints are the widest portion of the drill pipe segment and, thus, the drill string; they often contact cement and casing walls or the stone wellbore. Abrasive contact between joint sections and the wellbore tends to wear the joint sections. Accordingly, hard bands are often integrated into the steel joint sections before they are connected to the aluminum pipe section. Hard bands are designed as a sacrificial surface that bears the brunt of the frictional interaction between the drill string and the wellbore. Thus the joint members must be re-banded from time to time which is done by removing the existing band and welding a new band onto the joint section. The excess heat required by this process will degrade the interconnected aluminum pipe.
Accordingly, a need exists for a method and apparatus, which takes into account one or more of the issues discussed above as well as possibly other issues.
One embodiment of the present invention is a drill pipe segment comprising: 1) a pipe section; 2) a first, male joint section; and 3) a second, female joint section. Those of skill in the art will appreciate that drill pipe segments are often referred to as “joints,” wherein a drill string is comprised of a plurality of interconnected joints. Further, a “joint” of the prior art comprises a drill pipe having “tool joints,” e.g., male and female connecting members, at each end. The first joint section includes a first number of splines, and the second joint section includes a second number of splines. The drill pipe segment has a circumferential outer surface that defines a longitudinal axis. The first number of splines extend in a direction generally parallel to the longitudinal axis and span a circumferential outer surface of the first joint section. Likewise, the second number of splines extend in a direction generally parallel to the longitudinal axis and span a circumferential outer surface of the second joint section. Each of the first number of splines and the second number of splines have a base, a tip, and a pair of flanks that extend from the base to the tip. The pair of flanks may form an acute angle. Each of the first number of splines is configured to be received between pairs of splines in the second number of splines of another drill pipe segment to form a connection between two drill pipe segments.
It is a further aspect of embodiments of the present invention described above to provide a coupling for securing the first joint section to the second joint section. More specifically, the coupling may be associated with the first joint section of the drill pipe segment. The second joint section includes a plurality of external threads that selectively interface with the internal threads of the coupling. The first joint section also has external threads that selectively interconnected to threads of a load ring. In operation, the coupling is moved away from the first joint section to expose the external threads of the first joint section, and the load ring is interconnected to the first joint section. The splines of the first joint section and the splines of the second joint section of another drill pipe segment are intermesh as the two drill pipe segments are interconnected. Finally, the coupling is threadingly interconnected to the second joint section, wherein excess movement of the coupling along the longitudinal axis is prevented by the load ring. Thus a rigid connection of two drill pipe segments is provided that can accommodate torque and axial loads often encountered during drilling operations.
It is yet another aspect of embodiments of the present invention to provide a drill string that is formed of a plurality of aluminum drill pipe segments joined by steel couplings. Those of ordinary skill the art will appreciate that “aluminum” means aluminum, aluminum alloys, or any other material that exhibits the properties of aluminum, such as corrosion resistance, reduced weight, strength, toughness, etc. Those of ordinary skill the art will also appreciate that “steel” means steel, stainless steel, and other alloys of steel, or any other material that exhibits the properties of steel, such as strength and durability.
The aluminum drill pipe segment of embodiments of the present invention does not require hard banding. More specifically, as the hard ban wears, the coupler can be removed from the drill pipe segment by slipping it over the second joint section. A new coupler can then be added to the drill pipe segment and the old coupler can be discarded, recycled, or repaired/reused. Of course, the coupler can be hard banded, and the hard band can be repaired away from the aluminum drill pipe section wherein the increase heat required for such repair will not affect the aluminum drill pipe section.
The Summary of the Invention is neither intended nor should it be construed as being representative of the full extent and scope of the present invention. Moreover, references made herein to “the present invention” or aspects thereof should be understood to mean certain embodiments of the present invention and should not necessarily be construed as limiting all embodiments to a particular description. The present invention is set forth in various levels of detail in the Summary of the Invention as well as in the attached drawings and the Detailed Description of the Invention and no limitation as to the scope of the present invention is intended by either the inclusion or non-inclusion of elements, components, etc. in this Summary of the Invention. Additional aspects of the present invention will become more readily apparent from the Detail Description, particularly when taken together with the drawings.
The novel features believed characteristic of the illustrative embodiments are set forth in the appended claims. The illustrative embodiments, however, as well as a preferred mode of use, further objectives and advantages thereof, will best be understood by reference to the following detailed description of an illustrative embodiment of the present invention when read in conjunction with the accompanying drawings, wherein:
It should be understood that the drawings are not necessarily to scale. In certain instances, details that are not necessary for an understanding of the invention or that render other details difficult to perceive may have been omitted. It should be understood, of course, that the invention is not necessarily limited to the particular embodiments illustrated herein.
In this illustrative embodiment, splines in both the first joint section 202 and the second joint section 204 have a shape defined by base 218, tip 220, and pair of flanks 222 that extends from base 218 to tip 220. The pair of flanks also form acute angle 224. Each spline in first number of splines 206 is configured to be received between adjacent pairs of splines 226 in second number of splines 212 of another drill pipe segment as first end 208 of the first joint section 202 and second end 214 of the second joint section 204 are joined together to form connection 228 between the first joint section 202 and the second joint section 204. The illustration of connection 200 in
As one of skill in the art will appreciate, the first joint section 202 and the second joint section 204 may be a tool joint. The first joint section 202 and the second joint section 204 may be secured to ends of drill pipes. The first joint section 202 and the second joint section 204 may also be formed on surfaces of drill pipes near the end of the drill pipes. The first joint section 202 and the second joint section 204 may have different inner diameters and outer diameters. For example, without limitation the first joint section 202 and the second joint section 204 may be a connection section for pipes having three and a half inch diameters, five inch diameters or any other sizes suitable for use in locating or producing hydrocarbons. In other embodiments, splines in the first number of splines 206 and the second number of splines 212 may be different sizes than each other. Splines in the first number of splines 206 and the second number of splines 212 may also have different spacing from each other to receive different sizes of splines.
In one embodiment of the present invention, the first joint section 302 and the second joint section 304 are made of aluminum or an aluminum alloy, and the coupling 306 is made of steel, a steel alloy, or a variation thereof. The load ring 308 may also be made of aluminum or steel. In operation, the splines 310, 314 of adjoining drill pipe segments are interconnected as described below with regard to
Plurality of splines 310 are also tapered, meaning that as plurality of splines extend from base 402 towards tip 404 width 416 of plurality of splines 310 decreases. For example, this decrease in width 416 is attributable to spline flank angle 418. Spline flank angle 418 is the angle between pair of flanks 406. Each flank in pair of flanks 406 form flank face angles 419 as each flank extends in radial direction 412 from outer surface 414. Additionally, the radial extension of plurality of splines 310 from outer surface 414 form recessed areas 420 between each of plurality of splines 310.
In this illustrative embodiment, plurality of splines 310 also includes root radii 422 as well as chamfers 424. Root radii 422 are the small edging portions near the interface between plurality of splines 310 and outer surface 414 of first joint section 302. Chamfers 424 are the rounding off or reduction of edge 426 of plurality of splines 310.
In this illustrative embodiment, plurality of splines 314 also includes root radii 516 as well as chamfers 518. Root radii 516 and chamfers 518 may be another example of root radii 422 as well as chamfers 424 in
As depicted, the load ring 604 has set of inner threads 626 that are matched to threads 628 located on the first joint section 600. The set of inner threads 626 allow the load ring 604 to be rotated onto threads 628 located on the first joint section 600. Once in place, the load ring 604 may be secured to the first joint section 600 and secured using the set screws 606. Any number of set screws 606 may be used to lock the load ring 604 in place. In alternative embodiments, the load ring 604 may be formed on the first joint section 600. Thus, the load ring 604 and the first joint section 600 may be the same physical part.
Turning now to
In this illustrative embodiment, the retaining ring 718 restricts the coupling 714 from sliding in an axial direction away from lower joint section 704. The retaining ring 718 is positioned in the coupling 714 by engaging threads 720 of the retainer ring 718 with threads 722 of the coupling 714 when it is slid over the load ring 716. Once engaged, the retaining ring 718 then contacts a shoulder 724 of the load ring 716 to restrict the coupling 714 from sliding away from the load ring 716 and the second joint section 704.
In this example, connection section 700 also includes a seal 808. The seal 808 is configured to prevent any leakage of fluids from the connection formed between outer surface 802 of upper joint section 702 and inner surface 804 of lower joint section 704. Additionally, filler may be inserted in gap 806 between end 710 of upper joint section 702 and end 712 of lower joint section 704. The filler may be made from a compressible material, such as, for example, without limitation, polymer or urethane material. For example, the filler may be a polymer ring. Fluids may flow through connection section 700 at certain pressures causing possible wear or erosion of components in connection 700. Inserting a filler in gap 806 in connection section 700 may reduce an amount of wear or erosion on end 710 of upper joint section 702 and end 712 of lower joint section 704.
With reference now to
In this depicted embodiment, as coupling 714 is shifted axially towards lower joint section 704, a point is reached where load ring 716 begins to physically resist further axial movement of coupling 714 towards lower joint section 704. At this point, further tightening of coupling 714 on threads 904 begins to force upper joint section 702 and lower joint section 704 further together. Forcing upper joint section 702 and lower joint section 704 together may reduce the axial distance of gaps 806 between upper joint section 702 and lower joint section 704. However, in this example, ends 710 and 712 do not bottom out on surfaces of lower joint section 704 and upper joint section 702. Thus, gaps 806 extending in the axial direction between surfaces of upper joint section 702 and lower joint section 704 remain.
With reference now to
As depicted, each spline of plurality of splines 706 is matched with a recessed area, such as one of recessed areas 512 in
In this depicted embodiment, tightening of coupling 714 forces plurality of splines 706 between and towards plurality of splines 707. Preload in the connection caused by tightening of coupling 714 is generated from the mechanical advantage created by the wedge shape of the flanks of each of each of plurality of splines 706 and 707. As used herein, preload, when referring to a joint connection, refers to the force in a tightened joint connection prior to using the joint connection for its primary function. Preload is a compressive force resulting from two or more surface pairs being forced together during the assembly of a connection. The surfaces in compression can be tightened by any mechanical forces up to the yield strength of the surfaces in contact.
Preload increases the connection stiffness of connection 700 between upper joint section 702 and lower joint section 704. Connection stiffness is the resistance of a connection section to deflecting when external loads are applied to the pipe string. Preload in a connection allows the connection section between pipe joints to respond to forces as if the connection is a continuous section of pipe, because the connection section does not deflect. In this example, preload is applied to connection section 700 as upper joint section 702 and lower joint section 704 are forced together in the axial direction. Additionally, this preload is applied to surfaces of flanks of opposing splines. As gaps 1005 exist, the splines in connection section 700 have not bottomed out. Thus, additional tightening of coupling 714 increases an amount of preload in both the axial and circumferential directions for connection section 700.
In this illustrated embodiment, the angle selected for spline flank angle 1002 and 1004 has a value of about 18 degrees. However, in other advantageous embodiments spline flank angle 1002 and 1004 may be selected from a range between an angle having a value of about 10 degrees and an angle having a value of about 50 degrees. One of ordinary skill in the art would understand that as a spline flank angle approaches 90 degrees the mechanical advantage between opposing splines is reduced. Correspondingly, as a spline flank angle approaches zero degrees, disassembly of the joint sections may become more difficult once forces have been applied to the connection.
The tapered shape of plurality of splines 706 and 707 supplies a number of advantages to connection section 700. First, the tip of each of the splines is narrower than the base of the spline. The narrower tip fits within the larger recessed areas between the splines at an initial engagement stage, such as depicted in
Another advantage which may be attributable to the tapered shape of plurality of splines 706 and 707 is a reduction in the demand for machine tolerances. For example, irregularities may exist in one of more of the splines. One of the flanks of a spline may not be completely planar or the spline flank angle for one of the splines may not be formed to the exact degree desired. As the opposing splines are wedged together, the forces exerted on the splines adjacent to the spline having an irregularity may cause the irregular spline to deform. This deformation of the irregularity as the splines are wedged together may reduce problems caused by the irregularities.
The illustration of connection section 700 in
With reference now to
In this illustrative embodiment, external forces applied to connection section 1100 are resisted by the connection stiffness of male joint section 1104 and female joint section 1106. Additionally, if torque were applied to connection section 1100, hoop stress and hoop tension would be experienced in connection section 1100. Hoop stress, in connection section 1100, is the resistance in male joint section 1104 that arrests retraction and the resistance in female joint section 1106 that arrests swelling as the two joint sections are compressed and/or rotated against each other. Hoop tension in connection section 1100 is the resisting force in the female joint section 1106 wall that provides support and counteracts the hoop stress in the male joint section 1104. For example, the thickness of inner wall 1114 of male joint section 1104 provides support for plurality of splines 1110. Support for plurality of splines 1110 provided by the thickness of inner wall 1114 of male joint section 1104 reduces the tendency for plurality of splines 1110 to retract. Inner wall 1114 also provides an area of support to reduce the exposure of plurality of splines 1110. The area of support provided by inner wall 1114 increases an amount of applied force that plurality of splines 1110 may withstand. In a similar manner, the thickness of outer wall 1116 of female joint section 1106 provides support for plurality of splines 1112. Support for plurality of splines 1112 provided by the thickness of outer wall 1116 of female joint section 1106 reduces the tendency for plurality of splines 1112 to expand. Outer wall 1116 also provides an area of support to reduce the exposure of plurality of splines 1112. The area of support provided by outer wall 1116 increases an amount of applied force that plurality of splines 1112 may withstand.
In addition, inner wall 1114 provides support in the area between the each spline in plurality of splines 1110. The support provided by inner wall 1114 reduces any tendency for splines of plurality of splines 1110 to shear inwardly. Similarly, outer wall 1116 provides support in the area between each spline in plurality of splines 1112. The support provided by outer wall 1116 reduces any tendency for splines of plurality of splines 1112 to shear outwardly. Thus, the cylindrical shape of inner wall 1114 and outer wall 1116 cause axial and torsional forces to be distributed evenly across plurality of splines 1110 and 1112 in connection section 1100. As torque is applied to one joint section, the torque is transferred to the other joint section through the plurality of splines 1110 and 1112 which are supported by the hoop stiffness caused by the cylindrically adjoined flanks. Thus, the overall torsional strength of the connection section 1100 is increased. As used herein, torsional strength, when referring to a connection section, means the amount of torsional forces the connection may withstand before the components of the connection section yield.
As depicted, both plurality of splines 1110 and 1112 have similar flank face angles 1118. In this illustrative embodiment, the angle of flank face angle 1118 is approximately 0 degrees. In this example, flank face angles 1118 are determined relative to the axis of the cylinder of connection section 1100. Flank face angles 1118 are an angle between a first line and a second line. The first line is perpendicular to the axis and intersects the spline flank at a point along the radial midpoint of the flank face. The second line is a line that is tangential to the point along the radial midpoint of the flank face that intersects with the first line. As depicted in
However, flank face angles 1118 may vary as the cross section of connection 1100 is shifted axially. For example, near the bases of splines in plurality of splines 1110 the flank face angle may be different than the flank face angle near the bases of splines in plurality of splines 1112. As depicted, in
Overall, flank face angle 1118 may be selected from a range between an angle having a value of about negative 30 degrees and an angle having a value of about 30 degrees. Additionally, flank face angle 1118 may vary in connection section 1100 from a range between an angle having a value of about negative 30 degrees and an angle having a value of about 30 degrees. Persons skilled in the art recognize and take note that an angle approaching 90 degrees may cause male joint section 1104 and female joint section 1106 to slip rotationally as torque load increases 1100. Persons skilled in the art recognize and take note that an angle approaching negative 30 degrees may cause the materials of the joint section to yield in response to certain levels of torque or other forces applied to connection section 1100.
The illustration of connection section 1100 in
With reference now to
In this illustrative embodiment, first joint section 1202 has plurality of splines 1212, while second joint section 1204 has plurality of splines 1214. Plurality of splines 1214 includes at least one spline, spline 1216, that is a different size than other splines in plurality of splines 1214. On the other end of pipe 1200, recessed area 1218 between splines in plurality of splines 1212 is larger than other recessed areas between splines in plurality of splines 1212. As depicted, both spline 1216 and recessed area 1218 are substantially centered on scribe line 1220. Scribe line 1220 is a reference line that extends from first end 1204 to second end 1208 on pipe 1200. In this example, centering both spline 1216 and recessed area 1218 along scribe line 1220 provides a particular orientation for pipe 1200.
In this illustrated embodiment, spline 1216 is larger than other splines in plurality of splines 1214. However, in other embodiments, splines 1216 may be smaller than other splines in plurality of splines 1214. In another example, splines 1216 may be tapered at a different angle than other splines in plurality of splines 1214. Still further, the different spline may be a part of one first joint section 1202 and any number of different sized splines may be used.
With reference now to
Connection section 1300 is configured such that spline 1308 may only be fit into and be received by recessed area 1306 when upper joint section 1302 and lower joint section 1304 are fully engaged. Configuring connection section 1300 such that spline 1308 may only be fit into and be received by recessed area 1306 when upper joint section 1302 and lower joint section 1304 are fully engaged allows connection section 1300 to maintain a particular orientation as illustrated by scribe line 1310. Further, maintaining this particular orientation of connection section 1300 may allow an entire string of drill pipe to maintain a selected and particular orientation. Additional methods and apparatuses for maintaining orientation of pipes are disclosed in U.S. Pat. No. 5,950,744 entitled “Method and Apparatus for Aligning Drill Pipe and Tubing,” incorporated herein by reference.
With reference now to
With reference now to
With reference now to
With reference now to
The illustrations of electrical wiring and electrical connections
With reference now to
With reference now to
Female joint section 1900 may be joined with a male joint section, such as male joint section 1800 in
While spline 1802 in
The illustrations of electrical connections and splines having substantially parallel sides in
The description of the different embodiments of the present invention has been presented for purposes of illustration and description, but is not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention the practical application to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.
This application is a continuation of Ser. No. 14/636,592, filed Mar. 3, 2015, which is a continuation-in-part of now abandoned U.S. patent application Ser. No. 12/695,569, filed Jan. 28, 2010, the entire disclosures of which are incorporated by reference herein.
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Number | Date | Country | |
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20170067297 A1 | Mar 2017 | US |
Number | Date | Country | |
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Parent | 14636592 | Mar 2015 | US |
Child | 15356305 | US |
Number | Date | Country | |
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Parent | 12695569 | Jan 2010 | US |
Child | 14636592 | US |