Patent Grant
9624736
This disclosure relates generally to the field of sucker rod strings used in oil wells and, more particularly, to an end design for a sucker rod.
The use of sucker rods within production tubing in an oil well is well known in the art.
The API 11B sucker rod string 5 must extend from the pumping unit 1 all the way down to the reciprocating pump, which may be several thousand feet below the surface. As noted above, the API 11B sucker rod string 5 is made up of multiple individual API 11B sucker rods coupled together in multiple a connection 10.
It has been observed that conventional API 11B sucker rods 20 have at least the following problems during use, e.g.:
Breakage in the zone of the upset bead 23 and wrench flat 24 due to fatigue failures (the upset bead is a zone frequently including a high number of surface defects) (due to the forging process that is used to produce that geometry) and the wrench square is subject to damage from torque wrenches when making up and breaking out the connection 20);
Many rods have to be reworked in the zone of the upset bead 23 due to kinking during forging; and
High wear of the rod string 5 due to erosion and corrosion by movement of production fluid 7 in the annulus between the inner wall of the tubing 3 and the sucker rod connections 10, 20.
A new sucker rod end connection design is desirable to overcome these problems and other problems with API sucker rod end connections.
Prior art sucker rod ends have been manufactured according to API standard 11B for many years. Even though the API design is suitable for sucker rods, some fatigue failures have taken place, particularly when they were subjected to high axial loads. The present disclosure describes a new design for a sucker rod end that includes improvements of rod end geometry which provides reduced stresses and better fatigue resistance particularly in the wrench square and forged zone of the new sucker rod. This new design provides reduced operation costs of wells using sucker rods. Additionally, the new rod design provides a more uniform geometry for induction heating during the manufacturing process.
The present disclosure describes and illustrates an improved sucker rod having a first end including: sucker rod body 122 having a generally cylindrical outer surface, a longitudinal axis and a rod diameter DR; and a transition section 125 having a longitudinal axis. The transition section has a distal end disposed adjacent to a proximal end of the sucker rod body with the longitudinal axis of the transition section and the longitudinal axis of the rod body aligned. The transition section further includes an outer surface disposed circumferentially around the longitudinal axis of the transition section, wherein the outer surface includes a longitudinal profile with a continuous curve beginning at the cylindrical outer surface of the rod body and having a concave curved portion having a radius RA and a convex curved portion having a radius (RB), wherein RB is less than RA and a diameter of the transition section 125 measured transverse to the longitudinal axis is continuously increasing with distance from the outer surface of the rod.
The sucker rod end further includes a wrench square section 127 having a distal end disposed adjacent to a proximal end of the transition section, wherein the wrench square section has a longitudinal axis aligned with the longitudinal axis of the rod body and the wrench square section includes at least four wrench flats 124 orthogonal to each other. Each wrench square section 127 has a cross sectional width WS measured transverse to an axis AA of the rod body and is the transverse distance across the rod body between two parallel wrench flats (see
The sucker rod end further includes a pin shoulder section 128 having a distal end disposed adjacent to a proximal end of the wrench square section. The pin shoulder section 128 has a longitudinal axis aligned with the longitudinal axis of the rod body, and a pin shoulder face 126 disposed on a proximal end of the pin shoulder section. The pin shoulder face is adapted to contact an end of a coupling and the pin shoulder face has an outer diameter DF.
The sucker rod end further includes a threaded pin connection section 129 having a longitudinal axis aligned with the longitudinal axis of the rod body, said threaded pin connection section having a distal end disposed adjacent to a proximal end of the pin shoulder section 128, said threaded pin connection section including threads disposed on a portion of a circumferential exterior surface of the threaded pin connection section wherein the threads are configured to mate with threads inside the coupling.
In some implementations, the sucker rod may further include a second sucker rod end having a second transition section 125 having a longitudinal axis. The second transition section may include a distal end disposed adjacent to a proximal end of the sucker rod body with the longitudinal axis of the transition section and the longitudinal axis of the rod body aligned, wherein the transition section has an outer surface disposed circumferentially around the longitudinal axis of the transition section and the outer surface has a longitudinal profile comprising a continuous curve beginning at the cylindrical outer surface of the rod body and having a concave curved portion having a radius RA and a convex curved portion having a radius (RB), wherein RB is less than RA and a diameter of the transition section 125 measured transverse to the longitudinal axis is continuously increasing with distance from the outer surface of the rod.
In some implementations, the second sucker rod end may further include a second wrench square section 127 having a distal end disposed adjacent to a proximal end of the transition section, wherein the wrench square section has a longitudinal axis aligned with the longitudinal axis of the rod body and the wrench square section includes at least four wrench flats 124 orthogonal to each other. Each wrench square section 127 has a cross sectional width WS measured transverse to an axis AA of the rod body and is the transverse distance across the rod body between two parallel wrench flats (see
In some implementations, the second sucker rod end may further include a second pin shoulder section 128 having a distal end disposed adjacent to a proximal end of the wrench square section. The pin shoulder section 128 has a longitudinal axis aligned with the longitudinal axis of the rod body, and a pin shoulder face 126 disposed on a proximal end of the pin shoulder section. The pin shoulder face is adapted to contact an end of a coupling, said pin shoulder face having an outer diameter DF.
In some implementations the second sucker rod end may have a second threaded pin connection section 129 with a longitudinal axis aligned with the longitudinal axis of the rod body. The threaded pin connection section having a distal end disposed adjacent to a proximal end of the pin shoulder section 128, and the threaded pin connection section includes threads disposed on a portion of a circumferential exterior surface of the threaded pin connection section. The threads are configured to mate with threads inside a second coupling.
In some implementations, the pin shoulder section 128, of either or both of the first rod end and second rod end, includes a circumferential outer surface that transitions between the wrench square section 127 and the shoulder face. The pin shoulder section 128 has a diameter measured transverse to the longitudinal axis and is continuously increasing with distance from the wrench square section along the longitudinal axis of the pin shoulder section.
In some implementations either or both of the first rod end and second rod end includes a stress relief groove 121 disposed between the pin shoulder face 126 and the threads of threaded pin connection section 129.
In some implementations either or both of the first rod end and second rod end has a relationship WS/DR is at least 1.5.
In some implementations either or both of the first rod end and second rod end includes a relationship RA/DR is at least 3.3.
In some implementations a maximum transverse diameter of the coupling of either or both of the first rod end and second rod end is greater than a maximum transverse outer diameter of the rod body 122, the transition section 125, the threaded pin connection section 129 and the pin shoulder section 128.
In some implementations either or both of the first rod end and second rod end includes a chamfered corner having a substantially flat surface circumscribed in a Diameter DC less that the diameter DF.
The present disclosure describes and illustrates an improved method of coupling sucker rods including the steps of:
providing a first sucker rod including:
a sucker rod body 122 having a generally cylindrical outer surface, a longitudinal axis and a rod diameter DR;
a transition section 125 having a longitudinal axis, said transition section having a distal end disposed adjacent to a proximal end of the sucker rod body with the longitudinal axis of the transition section and the longitudinal axis of the rod body aligned, said transition section including an outer surface disposed circumferentially around the longitudinal axis of the transition section, said outer surface having a longitudinal profile comprising a continuous curve beginning at the cylindrical outer surface of the rod body and having a concave curved portion having a radius RA and a convex curved portion having a radius (RB), wherein RB is less than RA and a diameter of the transition section 125 measured transverse to the longitudinal axis is continuously increasing with distance from the outer surface of the rod;
a wrench square section 127 having a distal end disposed adjacent to a proximal end of the transition section, said wrench square section having a longitudinal axis aligned with the longitudinal axis of the rod body, said wrench square section comprising at least four wrench flats 124, each said wrench flat 124 has a width WS measured transverse to an axis AA of the rod body;
a pin shoulder section 128 having a distal end disposed adjacent to a proximal end of the wrench square section, said pin shoulder section 128 having a longitudinal axis aligned with the longitudinal axis of the rod body, and having a pin shoulder face 126 disposed on a proximal end of the pin shoulder section, said pin shoulder face having an outer diameter DF, wherein the pin shoulder section 128 includes a circumferential outer surface that transitions between the wrench square section 127 and the shoulder face and wherein the pin shoulder section 128 has a diameter measured transverse to the longitudinal axis that is continuously increasing with distance from the wrench square section along the longitudinal axis of the pin shoulder section, wherein the relationship RA/DR is at least 3.3;
a threaded pin connection section 129 having a longitudinal axis aligned with the longitudinal axis of the rod body, said threaded pin connection section having a distal end disposed adjacent to a proximal end of the pin shoulder section 128, said threaded pin connection section including male threads disposed on a portion of a circumferential exterior surface of the threaded pin connection section; and
providing a second sucker rod including:
a sucker rod body 122 having a generally cylindrical outer surface, a longitudinal axis and a rod diameter DR;
a transition section 125 having a longitudinal axis, said transition section having a distal end disposed adjacent to a proximal end of the sucker rod body with the longitudinal axis of the transition section and the longitudinal axis of the rod body aligned, said transition section including an outer surface disposed circumferentially around the longitudinal axis of the transition section, said outer surface having a longitudinal profile comprising a continuous curve beginning at the cylindrical outer surface of the rod body and having a concave curved portion having a radius RA and a convex curved portion having a radius (RB), wherein RB is less than RA and a diameter of the transition section 125 measured transverse to the longitudinal axis is continuously increasing with distance from the outer surface of the rod;
a wrench square section 127 having a distal end disposed adjacent to a proximal end of the transition section, said wrench square section having a longitudinal axis aligned with the longitudinal axis of the rod body, said wrench square section comprising at least four wrench flats 124, each said wrench flat 124 has a width WS measured transverse to an axis AA of the rod body;
a pin shoulder section 128 having a distal end disposed adjacent to a proximal end of the wrench square section, said pin shoulder section 128 having a longitudinal axis aligned with the longitudinal axis of the rod body, and having a pin shoulder face 126 disposed on a proximal end of the pin shoulder section, said pin shoulder face having an outer diameter DF, wherein the pin shoulder section 128 includes a circumferential outer surface that transitions between the wrench square section 127 and the shoulder face and wherein the pin shoulder section 128 has a diameter measured transverse to the longitudinal axis that is continuously increasing with distance from the wrench square section along the longitudinal axis of the pin shoulder section, wherein the relationship RA/DR is at least 3.3;
a threaded pin connection section 129 having a longitudinal axis aligned with the longitudinal axis of the rod body, said threaded pin connection section having a distal end disposed adjacent to a proximal end of the pin shoulder section 128, said threaded pin connection section including threads disposed on a proximal portion of a circumferential exterior surface of the threaded pin connection section; wherein the pin shoulder section 128 includes a circumferential outer surface that transitions between the wrench square section 127 and the shoulder face; and
providing a coupling having proximal portion having female threads therein and a proximal face and a distal portion having female threads therein and a distal face;
inserting a proximal end of the threaded pin connection of the first rod into the proximal portion of a coupling; and
rotating the sucker rod or the coupling until the pin shoulder face of the first rod contacts the proximal face of the coupling; and
inserting a proximal end of the threaded pin connection of the second rod into the distal portion of a coupling; and
rotating the second sucker rod or the coupling until the pin shoulder face of the second rod contacts the proximal face of the coupling.
In some implementations, the method of coupling sucker rods includes the first rod wherein adjacent wrench flats 124 of first sucker rod that are orthogonal to each other and meet at a chamfered corner comprising a flat surface. Each wrench flat 124 has a width WS measured transverse to an axis AA of the rod body and is the transverse distance across the rod body between the two parallel wrench flats (see
Like reference symbols in the various drawings indicate like elements.
The transition section 125 includes a circumferential outer surface that has a first concave curved portion (viewed from the outside) having a radius RA and a second convex curved portion having a radius RB. The radius RA and the radius RB meet at an inflection point (IP) where the curved surfaces A and B are tangent to each other. RB is less than RA and a diameter of the transition section 125 measured transverse to the longitudinal axis is continuously increasing with distance from the rod body along the longitudinal axis of the transition section. The transition section 125 terminates at a wrench square section 127.
The wrench square section 127 includes a distal end disposed adjacent to a proximal end of the transition section, wherein the wrench square section has a longitudinal axis aligned with the longitudinal axis of the rod body and the wrench square section includes at least four wrench flats 124 orthogonal to each other. The wrench square section 127 terminates in a pin shoulder section 128 having a pin shoulder face 126 that contacts the end of a standard coupling (for an example of a standard coupling see item 27 in
The pin shoulder section 128 includes a circumferential outer surface that includes a convex surface (viewed from the outside) having a radius RDF. The pin shoulder section further includes a pin shoulder face 126 with a Diameter DF (See
A threaded pin connection section 129 having a longitudinal axis aligned with the longitudinal axis of the rod body is connected to the pin shoulder section. The threaded pin connection includes male threads adapted to mate with female threads inside the coupling. A stress relief groove 121 is disposed between the shoulder face 126 and the threads of thread pin connection 129.
Table I below includes values for physical parameters expressed in millimeters (“mm”) and dimensionless ratios of an exemplary embodiment of the present invention as illustrated in
The design of the present disclosure reduces stresses in the wrench flat section and the forged zone and reduces fatigue failures. The new design of the present disclosure illustrated in
The upset bead 23 in the API 11B connection positioned between the wrench flat 24 and the sucker rod body 22 is eliminated in the new design and instead of the upset bead 23, the rod body 122 of the new design is joined smoothly with the wrench square section 127 by a smooth continuous transition section 125 including a continuous circumferential outer surface that includes a first concave (viewed from the outside) curved portion having a radius RA and a second convex curved portion having a radius RB that meet at an inflection point IP. RB is less than RA and a diameter of the transition section 125 measured transverse to the longitudinal axis is continuously increasing with distance from the rod body along the longitudinal axis of the transition section.
Due to the absence of the upset bead 23 in the new design, it is possible to enlarge the dimension of the wrench square WS and the dimension of the radius RA in the new end design for a specific rod diameter, but keeping these values inside the API 11B standardized values in order to use standard equipment for handling the rods and torqueing the rod connections (e.g. elevators and rod wrenches and tongs). With the new rod end geometry, for example, you can use the value of “WSAPI” of a 1″ diameter API rod in a new design rod of ⅞″ diameter. This results in maximizing the dimension of the width WS of wrench square portion 127 of the new end sucker rod in comparison to the wrench flat 24 of a standardized by API 11B for the same rod diameter, but the dimensions of the wrench square still remain within the API standardized values.
The ratio relationship (WS/DR) of wrench square width WS to rod diameter RD is increased in the design of the present disclosure over the relationship of WSAPI/DRAPI of the width of the wrench square WSAPI of the API 11B rod end and the rod diameter of the API rod DRAPI. (See values and ratios in Tables I and II wherein the new design has a relationship WS/DR of at least 1.5 while API designs have a relationship WSAPI/DRAPI between 1.14-1.3). Increasing the size of the wrench square section of the sucker rod end in relation to particular rod sizes (e.g. increasing the value WS/DR) is advantageous because the wrench square is a part of the rod that can be easily damaged during handling (e.g. making up and breaking out of a connection). Damage to the wrench square section 127 can lead to stress concentrators and cracks that can generate fatigue failures during use.
Removing the upset bead used in the prior art API 11B design has the additional benefit of reducing wear of the interior surface of the tubing 3 by the moving rod string 5. This is accomplished using the new design by spreading out (distributing) the contact (abrasion) points between sucker rod and tubing. In API Rod end 11B designs the upset bead is a part of the rod having the largest diameter and is usually in contact with the tubing in a very small area, generating high contact pressures and damage in the softer of the contacting elements (i.e., the tubing) resulting in premature failure of the tubing via a worn hole.
Additionally, removing the upset bead eliminates an area where forging defects appear in standard prior art API rods that require a rework of the upset bead (23) after forging of the end for an API 11B rod due to cracks, forging fins and scale. The upset bead 23 of an API 11 B rod is subject to high deflection during forging which may result in high remaining stresses after forging that can produce cracks which are stress concentrators that may lead to fatigue failure, therefore it is desirable to eliminate the bead thereby avoiding these type of defects in the sucker rod surface.
Enlarging the radius of the continuous curved smooth transition section 125 of the rod of this disclosure with respect to transition section of the standardized API 11B rod for a specific rod diameter increases the corrosion fatigue resistance. This increased radius is illustrated using the ratio RA/DR of the radius RA of a curved portion of the transition section 125 and the rod diameter DR of the new sucker rod end to the ratio RAPI/DRAPI for the API rod (See values and ratios in Tables I and II wherein the new design has a relation RA/DR>3 while API 11B designs had a relation RAPI/DRAPI approximately equal to 3). This increased (RA/DR) ratio provides a smoother transition for the fluid flow across the sucker rod end, reduces turbulence areas (high friction areas). In the API rod the smaller (RAPI/DRAPI) ratio combined with the fluid corrosiveness and turbulent flow contribute to pitting initiation and lead to cracking that may result in a corrosion fatigue failure in the forged end transition section of the API rod.
Replacing the abrupt change of diameter between wrench square portions 27 and the shoulder 26 in the API rod design (See
Since there is no upset bead in the new sucker rod end design (as is present in the API 11 B sucker rod end), the new sucker rod end geometry has lower values of pressure losses in the production fluid 7 flowing along the outer surface of the sucker rod end for the same rod diameter and tubing diameter as an API 11 B rod. (See Table III and Table IV attached) This improved production fluid 7 flow increases the productivity of a well in which rods of the new design are installed and reduces erosion-corrosion of the rods in the well and thereby increases the lifetime of rods with the new sucker rod end design.
Additionally, since there is no upset bead in the new design, the contact surfaces between the connection and the tubing will be the maximum transverse outer diameter (e.g., a diameter measured perpendicular to a longitudinal axis) of the coupling 27 and the corners of the wrench square depending on the well deviation. Compared to the API 11B design where the upset bead creates high wearing pressure (because of the reduced contact area) thus increasing the tubing and sucker rod wearing rate. This new sucker rod end geometry will concentrate the wearing on couplings and in a lower degree (compared to the API 11B design) on the corners of the sucker rod wrench square. Therefore, the coupling is the most likely element to wear due to friction associated with contact of the coupling and tubing wall. This results in less wear on the other sucker rod end elements. Which ultimately results in lower maintenance costs for a well having sucker rods with the new design sucker rod end because the coupling is the least expensive item and the easiest item in the rod string to replace.
In Table III and Table IV below well fluid A and B represents two different types of typical fluid types for wells using sucker rods.
A fluid flow simulation has been performed in order to assess the flow characteristics (reverse flow, flow turbulence, pressure drop, force on the sucker rod due to fluid flow, force on the tube due to the fluid flow, Friction and Pression on the joint) comparing Tenaris design with API design.
Table IV: Flow Simulation Results Expressed in Absolute Values
In this Table IV, Tenaris-A are simulation results for a rod end of the present disclosure used in fluid A of Table III and API-A is the API rod simulation results in Fluid A of Table III. Tenaris-B and API-B are simulation results for Fluid B of Table III.
In Table V below the results are non-dimensional, meaning that they are split to the same value obtained in a simulation of 1 m of rod body (with no connection).
TABLE V Flow Simulation Results for One Meter of Rod Body (with No Connection) Expressed in Non-Dimensional Values
In this Table V, Tenaris-A are simulation results for a rod of the present disclosure used in fluid A of Table III and API-A is the API rod simulation results in Fluid A of Table III. Tenaris-B and API-B are simulation results for Fluid B of Table III.
A preferred embodiment has been disclosed and described herein. Other implementations are within the scope of the following claims.
| Number | Name | Date | Kind |
|---|---|---|---|
| 1849067 | Bridges | Mar 1932 | A |
| 2751194 | Rohrback et al. | Jun 1956 | A |
| 3489620 | Current | Jan 1970 | A |
| 4205926 | Carlson | Jun 1980 | A |
| 4401396 | McKay | Aug 1983 | A |
| 4430018 | Fischer | Feb 1984 | A |
| 4430787 | Paramore | Feb 1984 | A |
| 4432662 | Ronnkvist | Feb 1984 | A |
| 4433933 | Parsons, Jr. | Feb 1984 | A |
| 4475839 | Strandberg | Oct 1984 | A |
| 4484833 | Gallagher, Jr. | Nov 1984 | A |
| 4585368 | Pagan | Apr 1986 | A |
| 4653953 | Anderson | Mar 1987 | A |
| 4822201 | Iwasaki | Apr 1989 | A |
| 4919560 | Rutledge, Jr. | Apr 1990 | A |
| 6193431 | Rutledge | Feb 2001 | B1 |
| 6709234 | Gilbert | Mar 2004 | B2 |
| 7316268 | Peleanu | Jan 2008 | B2 |
| 20120186818 | Wollmann | Jul 2012 | A1 |
| Number | Date | Country |
|---|---|---|
| 2546615 | Apr 2003 | CN |
| 2809189 | Aug 2006 | CN |
| 201963212 | Sep 2011 | CN |
| Entry |
|---|
| “API Specification 11B 27th Edition”, American Petroleum Institute, Purchasing Guidelines Handbook, Nov. 2010, 13 pages. |
