The present invention generally relates to gas lift devices for rejuvenating low-producing or non-productive oil or gas wells, and more particularly to improvements in the design and construction of bypass plungers.
A conventional bypass plunger is a device that is configured to freely descend and ascend within a well tubing, typically to restore production to a well having insufficient pressure to lift the fluids to the surface. It may include a self-contained valve—also called a “dart” or a “dart valve” in some embodiments—to control the descent and ascent. Typically the valve is opened to permit fluids in the well to flow through the valve and passages in the plunger body as the plunger descends through the well. Upon reaching the bottom of the well, the valve is closed, converting the plunger into a piston by blocking the passages that allow fluids to flow through the plunger. With the plunger converted to a piston, blocking the upward flow of fluids or gas, the residual pressures in the well increase enough to lift the plunger and the volume of fluid above it toward the surface. Upon reaching the surface, the fluid is passed through a conduit for recovery, the valve in the plunger is opened by a striker mechanism, and the plunger descends to repeat the cycle.
In a typical bypass plunger the valve is similar to a poppet valve, with a valve head attached to one end of a valve stem, such as an intake valve of an internal combustion engine. The valve head, at the inward end of the stem, may be configured to contact a valve seat within the hollow body of the plunger. The stem protrudes outward of the bottom end of the plunger body. A clutch device may surround the stem of the valve to retard and control the motion of the stem and thereby maintain the valve in an open or closed configuration during the descent or ascent of the plunger, respectively. The valve thus moves between these two positions to open the flow passages at the surface when the plunger contacts the striker mechanism, and to close the bypass passages at the bottom of the well when the stem strikes the bottom, usually at a bumper device positioned at the bottom of the well. Descent of the plunger is controlled by gravity, which pulls it toward the bottom of the well when the valve is open. Based on characteristics of the well and the design of the plunger, fall speeds of the plunger within the well tubing will vary. If descent of the plunger is slow, shut-in or non-production time of the well may increase and production may be lost or delayed. However, if the descent of the plunger is too fast, the downhole bumper spring assembly and/or the plunger may be damaged when the plunger reaches the bottom of the well tubing. Typically, multiple designs and configurations of plungers must be manufactured and/or kept in stock to accommodate the various and changing conditions of the well.
This valve or “dart” may be held open or closed by the clutch-typically a device that exerts circumferential friction around the valve stem. The dart may be held within a hollow cage attached to the plunger by a threaded retainer or end nut at the lower end of the plunger assembly. Thus, the valve reciprocates between an internal valve seat (valve closed) in a hollow space inside the cage and the inside surface of the lower end of the cage (valve open). A conventional clutch is appropriate for some applications, especially when its assembly is well controlled to produce uniform assemblies. Such a clutch may be formed of a bobbin split into two hemispherical halves and surrounded by one or two ordinary coil springs that function as a sort of garter to clamp the stem of the valve or dart between the two halves of the bobbin, thereby resisting the sliding motion of the stem within the bobbin. The clutch assembly is typically held in a fixed position within the cage. Each ‘garter’ spring is wrapped around its groove and the ends crimped together, typically in a hand operation that is subject to some variability in the tension around the bobbin halves and possible failure of the crimped joint, which could affect the reliability of the clutch when in a downhole environment.
While generally effective in lifting accumulated fluids and gas of unproductive wells such conventional bypass plungers tend to be complex and suffer from reliability problems in an environment that subjects them to high impact forces, very caustic fluids, elevated temperatures and the like. Various ways have been attempted to simplify construction of bypass plungers, improve their reliability and performance, and to reduce the cost of manufacture. However, failures remain common, and a substantial need exists to eliminate the causes of these failures. What is needed is a bypass plunger design that solves the structural problems with existing designs and provides a more reliable and efficient performance in the downhole environment.
Accordingly there is provided a bypass plunger comprising a unitary hollow plunger body and valve cage formed in one piece having first and second ends, the valve cage formed at the second end, and the valve cage having internal threads at its distal end for receiving a retaining nut having external threads at one end thereof; a poppet valve having a valve head connected to a valve stem, the poppet valve reciprocatingly disposed within the valve cage such that the valve head is oriented toward a valve seat formed within the hollow body; a retaining nut having external threads formed in the outer surface thereof and corresponding to internal threads formed in the distal end of the valve cage to retain the poppet valve within the valve cage; and at least one helical groove formed for at least one-half revolution around the outer surface of the hollow plunger body for a portion of the length of the hollow body approximately midway between the first and second ends.
In another embodiment, there is provided a bypass plunger comprising a unitary hollow plunger body and cage, the valve cage formed at a lower end thereof and configured with internal threads at its lower end for receiving a retaining nut having external threads at one end thereof; a poppet valve having a valve head connected to a valve stem and reciprocatingly disposed within the valve cage; and a retaining nut having external threads for closing the lower end of the valve cage to retain the poppet valve within the valve cage; and at least two crimples to lock the retaining nut to the valve cage.
In another embodiment there is provided a bypass plunger comprising a unitary hollow plunger body and valve cage, the valve cage formed at a lower end thereof and configured with internal threads at its lower end for receiving a retaining nut having external threads at one end thereof; a poppet valve having a valve head connected to a valve stem and reciprocatingly disposed within the valve cage; a retaining nut having external threads for closing the lower end of the valve cage to retain the poppet valve within the valve cage; a continuous helical groove machined into a central portion of the hollow body midway between upper and lower ends thereof and having a predetermined pitch, depth, and profile according to required spin and rate of descent of the bypass plunger through a well tubing; first and second crimple detents extending inward from the surface of the valve cage at the second end of hollow body and along first and second opposite radii of the valve cage into corresponding relieved spaces in the proximate external threads formed in the outer surface of the retaining nut; and a canted coil spring disposed within a circumferential groove formed into the inside wall of the retaining nut such that the canted coil spring exerts a substantial radial clamping force on the stem of the poppet valve, thereby forming a clutch to retard the motion of the poppet valve between open and closed positions.
Accordingly there is provided a clutch assembly for a bypass plunger having a valve cage and a reciprocating dart valve, the dart valve having a round stem and disposed within the valve cage, the clutch assembly comprising: a partition nut, threadably installed within an internal thread of an open end of the valve cage following installation of the dart valve in the valve cage; a split bobbin assembly having first and second hemispherical halves, each half of the split bobbin assembly having formed there around at least one circumferential groove, and the assembly installed on the stem of the dart valve; a coil spring disposed in each circumferential groove to secure the split bobbin assembly around a stem of the dart valve, thereby forming the clutch assembly; a retaining nut threadably installed within the internal thread of the valve cage following installation of the clutch assembly within the valve cage; and at least first and second crimples formed into the outer surface of the valve cage and extending into relieved spaces formed in an external thread formed on each one of the retaining nut and the partition nut.
In another embodiment there is provided a clutch for a bypass plunger having a reciprocating valve, comprising a clutch body formed as a circular split bobbin assembly having first and second halves, the assembly defined by a central axis, an inside radius, an outside radius, and first and second opposite faces normal to the central axis; a circumferential groove disposed in the surface defined by the outside radius of the split bobbin assembly; and a canted-coil spring disposed in the circumferential groove to secure the split bobbin assembly around a valve stem.
Accordingly there is provided a dart valve for a bypass plunger, the dart valve disposed to move reciprocatingly within a valve cage of the bypass plunger between seated and unseated positions and constrained by a clutch mechanism within the valve cage or its retaining nut, comprising a poppet valve comprising a valve stem and a valve head; a valve head connected to one end of the valve stem, the valve head including a sealing face to make sealing contact with a valve seat within the bypass plunger; and the valve stem includes a predetermined surface profile for moderating tension produced by the clutch mechanism during the reciprocating motion of the poppet valve.
In another embodiment there is provided an improved valve dart assembly for a one-piece hollow plunger body and valve cage of a bypass plunger, the valve cage formed at a lower end of the hollow plunger body and configured with internal threads at its open lower end, the improvement comprising a poppet valve having a valve head connected to a valve stem and reciprocatingly disposed within the valve cage; a retaining nut having external threads at one end thereof for engaging internal threads formed in the open lower end of the valve cage to retain the poppet valve within the valve cage; and a canted coil spring disposed within a circumferential groove formed into the inside wall of the retaining nut such that the canted coil spring exerts a substantial radial clamping force on the stem of the poppet valve, thereby forming a clutch to retard the motion of the poppet valve between open and closed positions.
In accordance with this disclosure, the exemplary embodiments discussed herein may include bypass flow ports that can be altered or sealed to control and/or adjust the flow of fluids, including oil, gas, and other fluids, through the plunger.
The accompanying drawings are part of the present disclosure and are incorporated into the specification. The drawings illustrate examples of embodiments of the disclosure and, in conjunction with the description and claims, serve to explain various principles, features, or aspects of the disclosure. Certain embodiments of the disclosure are described more fully below with reference to the accompanying drawings. However, various aspects of the disclosure may be implemented in many different forms and should not be construed as being limited to the implementations set forth herein.
In an advance in the state of the art, the novel bypass plunger described herein with the aid of the accompanying drawings yields improvements in a number of areas. The result is a novel unibody bypass plunger (aka unibody gas lift plunger) as disclosed herein. The unibody bypass plunger includes the one-piece hollow plunger body and the integral valve cage formed at its lower end. The valve cage assembly includes a valve dart and a clutch mechanism enclosed within the cage. A retaining nut (or end nut) that retains the valve dart and clutch mechanism within the cage completes the valve dart cage assembly. Novel features of the present disclosure provide reduction of manufacturing costs, and enhanced performance, durability, and reliability, advantages that may result through substantially greater simplicity of design and construction. The features of this novel combination are described as follows.
One feature is a one piece or unitary hollow body and cage (the “unibody” construction) with flow ports in the integral valve cage (disposed at the lower end of the plunger body) that can be altered to control the flow of fluid through the plunger on descent. During descent, the plunger falls through the well and any fluids therein. The fluids flow though the angled ports in the valve cage and the hollow body of the plunger. The ports in the cage may be oriented at different angles, varied in number, relieved, sealed/plugged, etc. to adjust the rate of descent. This unibody design minimizes the number of parts and the number of joints that must be formed and secured, and the sealable flow ports minimize the number of different plungers to be manufactured and kept in inventory. One benefit of the one-piece or “unibody” construction is fewer parts to assemble and secure together, and the elimination of failures in the mechanisms used to secure the parts together.
The valve cage at the lower end and the end cap (if used) at the upper end are mated to the respective ends of the hollow plunger body with threaded joints and secured with a crimp (“crimple”) formed in at least two equally spaced locations around the hollow body. The crimple functions as an inward-formed dent that effectively indents the wall of the valve cage portion of the hollow body into a corresponding relief machined into the external threads of the (smaller) outside diameter of the retaining nut. The retaining nut (alternately “end nut”), thus threadably secured to the lower end of the valve cage, functions to close the open end of the valve cage and retain the poppet valve within the valve cage. The crimple feature eliminates the need for separate parts such as pins, screws, ball detents, lock nuts or washers, etc, to lock a threaded joint from loosening. The advantage of the crimple technique and mechanism is to more reliably prevent the inadvertent disassembly of the components secured to the bypass plunger with screw threads, thereby ensuring a true unibody bypass plunger that remains a single unit throughout many cycles of use. The term crimple is a contraction of the terms crimp and dimple, to characterize the crimp as approximating a crimp at a defined point as compared with a circumferential crimp.
The outer surface of the hollow plunger body of the present disclosure may include a series of concentric rings or ridges machined into the outer surface of the hollow body for approximately one third the overall length of the hollow body at each end. The rings or ridges thus provided act as a seal to minimize the clearance between the plunger and the inside of the well tubing through which it descends and ascends. In accordance with the present disclosure, between these two groups of concentric rings, one group at each end of the hollow body, a series of concentric spiral (or helical) grooves (not unlike the “valleys” of screw threads) may be machined into the central portion of the outer surface of the hollow body. The “central” portion may typically (but not exclusively) be approximately the central one-third of the length of the hollow body. The pitch and profile of these spiral grooves may be varied between a tight helix and an open helix to vary the rate of spin of the plunger as it descends and ascends. The purpose of spinning the plunger is to prevent flat spots from forming on the outside surface of the plunger, which reduce the effectiveness and the useful life of the bypass plunger. The cross section profile of the grooves may also be varied to facilitate the spin rate.
The “clutch” of one embodiment of the present disclosure may consist of a canted-coil garter spring disposed within a circumferential groove inside the end nut. In other words, no bobbin is used, split or otherwise; just the canted coil spring that is disposed within its groove and wrapped 360 degrees around the stem of the valve dart. As used in the inventive plunger, the coils of the spring as formed are canted in the direction of its torroidal centerline (i.e., a line passing through the center of each coil of the spring) in a circumferential direction around the stem diameter. The coils of the canted coil spring, unlike a conventional coil spring in which the coils are disposed substantially at right angles to the centerline of the spring, are disposed at an acute angle relative to the centerline of the spring. This configuration allows the spring to exert tension at right angles to its centerline against the outside diameter surface of the valve dart stem. This property is enhanced when the outer diameter of the canted-coil spring is constrained by a cylindrical bore or in a groove surrounding the spring. The surface of the valve dart stem in one embodiment is preferably machined to a surface roughness of approximately 8 to 50 microinches, a standard specification for a very smooth finish. The canted coil spring is supplied in a 360 degree form with its ends welded together (thereby forming a torroidal shape), enabling it to be dimensioned to fit within a machined groove in the end nut or retaining nut. Advantages of this design include elimination of the bobbin components and greater durability.
In the appended drawings, reference numbers that appear in more than one figure refer to the same structural feature. The drawings depict at least one example of each embodiment or aspect to illustrate the features of the present disclosure and are not to be construed as limiting the disclosure thereto. In addition, several alternative embodiments of a clutch mechanism for a plunger valve that utilizes canted-coil springs, and several alternative embodiments of a plunger valve dart having different valve stem profiles are included to suggest the scope of modifications that may be made to these components without departing from the concepts employed in the present disclosure. It should be understood that the term “plunger dart” or simply “dart” may also be named a poppet valve or a valve dart herein, all of which refer to the same component.
The valve cage 16 includes a plurality of flow ports 18 disposed at typically two to four equally-spaced radial locations around the valve cage 16, and in some embodiments may include, for example, one to eight or more flow ports 18 depending on the intended application. The flow ports 18 may be oriented at different angles, varied in number, relieved, sealed, and/or plugged to adjust flow rates through the plunger 10 and, thereby, control/optimize fall speed of the plunger 10. In exemplary embodiments, one or more of the flow ports 18 may be sealed by a plug 19 (
In the illustrated embodiment, two or more crimples 20 to be described may be positioned as shown near the lower end of the hollow body 12 at valve cage 16. The crimple 20 provides a mechanism to lock a retaining nut or end nut 40 threaded on the open, lower end of the valve cage 16. The hollow body 12 may further include wear grooves 30 disposed at selected ones of the sealing rings 22, 26 as shown. Further, disposed within the retaining or end nut 40 when the bypass plunger is assembled is a canted-coil spring 42 that functions as a clutch. This novel clutch design, which does not require use of a bobbin or similar structure, will be described herein below.
Continuing with
The crimple 20 thus functions similar to a set screw or a pin to prevent the loosening of the screw threads. This feature is shown and described in greater detail for
The coils of the canted-coil spring, unlike a conventional coil spring in which the coils are disposed substantially at right angles to the centerline of the spring, are disposed at an acute angle relative to the centerline of the spring 42. This configuration allows the canted coils of spring 42 to exert tension radially inward at right angles to its centerline against the outer surface of the valve stem 34. The particular specifications of the canted-coil spring, such as the material used for the spring wire, its overall diameter, the diameter of the coils, the acute angle the coils form relative to the centerline of the spring, etc., may be selected to suit the particular dimensions of the bypass plunger, its expected environment, and other conditions of use. The performance of the canted-coil spring design is facilitated by the surface finish provided on the surface of the stem 34. Optimum performance is provided when the surface finish, preferably produced by machining, is held within the range of 8 to 50 microinches.
Advantages of this bobbinless, canted-coil spring design include at least the following: (a) reduction in the number of components required to provide the clutch function; (b) the canted-coil spring 42 is supported in a more confined space, reducing the likelihood of failure during hard impacts; (c) the need to assemble a split bobbin-with-garter springs clutch is eliminated—the canted-coil spring is simply inserted into its circumferential groove 44; and (d) the use of a conventional clutch bobbin assembly is eliminated. These advantages arise from the simplicity and the construction of the canted-coil spring.
Unlike a typical garter spring, which as supplied is simply a coil spring that must be formed into a circle and the ends typically crimped together (a hand-assembly operation that is prone to errors such as in cutting to length and crimping, etc.), the canted-coil spring 42 is supplied to specification with the ends welded and the circular, torroidal-form coil properly dimensioned and configured for the particular application. Also unlike the garter spring, the canted-coil spring 42 need only be inserted into the circumferential groove 50 in the end nut 40, while the garter spring must be assembled onto the split bobbin; again a more complex hand-assembly operation. Thus the use of the canted-coil spring 42 ensures a leaner manufacturing process of a bypass plunger 10 that is substantially more reliable because of the more durable spring, and the more consistent tension it provides. These features markedly improve the impact resistance of the shifting mechanism (the valve cage 16, end nut 40, and canted-coil spring 42) of the unibody bypass plunger 10 disclosed herein.
Continuing with
There are several alternate surface finishes to be illustrated and described (See
Alternatively, the profile of the detent 20, 21 may be approximately conical in form, as though formed by a center punch having a conical point. In practice, the crimple detent 20, 21 may be formed using a press as is well-known in the art. One preferred example of a die used in a press to form the crimple is illustrated in
The continuous helical groove machined into the central portion of the hollow body midway between the upper and lower ends thereof may have a predetermined pitch, depth, and profile. The variation in the pitch of the helical grooves 62, 72 as shown in
It is important to note that the central helix 62, 72 is positioned mid-way between the sealing rings so as not to impair the sealing function of the sealing rings 22, 26 yet still provide a mechanism to cause the plunger 60, 70 to rotate during its up-and-down travels. Moreover, experience has shown that placing the helical grooves near the ends of the plunger body 60, 70 causes the outside diameter of the plunger to wear faster, reducing the profile depth and effectiveness of the helical grooves and reducing the life of the bypass plunger 60, 70.
The concept of the centralized helix may also be used with good effect in sand plungers used in sand-producing wells by improving the movement of the plunger through sand-bearing fluid because of the rotation imparted to the sand plunger. The rotation may also tend to keep the helical grooves—and the space between the plunger body and the well tubing free of sand build-up through the effects of centrifugal force.
One of the usual components of a dart or poppet valve as used in a bypass or gas-lift plunger is some form of clutch to restrain the motion of the dart, thereby ensuring the efficient operation of the dart in controlling the operation of the plunger. A conventional split-bobbin clutch may employ a circular bobbin split into two equal hemispherical halves to enable convenient assembly around the stem of the dart or poppet valve. The two halves are generally held against the stem by one or more (usually two) so-called “garter springs” disposed in grooves surrounding the bobbin assembly. Each bobbin half encircles the stem for slightly less than a full 180 degrees, so that the inside surface of each bobbin half may make direct contact with the stem of the dart under the tension provided by the garter spring(s). The clutch assembly is generally secured within the body of the plunger through which the dart reciprocates during its use. The clutch, through the friction exerted against the stem, acts to damp the motion of the stem within the bypass plunger so that it remains in the required closed or opened position during ascent or descent respectively through the well tubing.
The split bobbins of
It is possible to use a conventional coil spring in the embodiments depicted in each of
It should be appreciated by persons skilled in the art that a single canted-coil spring is adequate for most applications because the spring can be manufactured within a given size constraint and spring-constant as assembled to exert the required inward radial force and it is thus not required to perform trial and error operations to select the proper springs.
The minor radius 208 is provided for a similar reason—to allow the stresses of formation to flow outward along the work piece. A small fillet radius 210 is provided on the outside edges of the blade 204 to reduce stress riser occurrence, a phenomenon well-understood in the machine arts. The operation of the press with the die 200 installed proceeds in a slow, controlled manner, after the work piece—the body 12 of the plunger—is supported in a fixture or vise (not shown) opposite the die 200. This procedure achieves the desired crimp 21 into the recess 44 of the retaining nut 40. The curvatures of the major 206, minor 208, and fillet 210 radii, besides reducing stresses in the metal also retard the formation of cracks, both during manufacturing and during use of the bypass plungers in the field, where the plunger is subject to hard impacts under some conditions.
The valve dart 170, shown in
Returning to
The slipper seals 244, 246 may be formed from various ones of the PTFE (polytetrafluoroethylene) family of materials as O-rings having a square (or round) cross section. Alternatives are filled Nylon such as oil-filled Nylon 6 and equivalents Moly-filled Nylon 6, solid lubricant-filled Nylon 6. Other alternatives include semi-crystalline, high temperature engineering plastics based on the PEEK (polyetheretherketone) or PAEK (polyaryletherketone) polymers.
It is also within the scope of this disclosure that the plug 19 may be designed as a sleeve that includes a passageway therethrough (not shown), rather than a solid component. The plug sleeve including the passageway effectively reduces the inner diameter of the flow port 18 and reduces an amount of fluids and/or gases that are allowed to flow through the plugged flow port 18. This modification permits further adjustment and control of the fall speeds of the plunger 10.
The arrows in
While exemplary embodiments of the disclosure have been shown, the disclosure is not limited and various changes and modifications may be made without departing from the spirit thereof. For example, canted-coil springs may be used to advantage in split bobbin clutches as described herein. Further, the profiles of the helical grooves and the flow ports in the cage, the surface finishes, the relative placements of the canted coil spring within the retaining nut attached to the cage, the form of the poppet valve—its stem, valve head, and the corresponding valve seat in the plunger body, the number of canted coil springs used within the retaining nut or in a split bobbin clutch assembly, the shape of the crimple and the die used to form it, are some illustrative examples of variations that fall within the scope of the disclosure. Moreover, the crimple feature is a technique that may be used in place of set screws, pins, etc., to secure threaded components from turning relative to each other. For example, end nuts at either end of a plunger body or a bumper spring or other similarly constructed device, may employ a crimple as described herein to useful advantage. The canted-coil spring used as a clutch may also be used in other structures for controlling sliding or reciprocating motion of a shaft within the bore of a corresponding structure of a device.
In regard to the use of a canted-coil spring in a clutchless embodiment of a valve dart assembly, several of the disclosed embodiments may use split bobbin clutch assemblies in the claimed combinations, wherein canted-coil springs or conventional coil springs may be used to hold the bobbin halves together around the stem of the valve dart, without departing from the concepts of the disclosure as disclosed herein.
Conditional language, such as, “can,” “could,” “might,” or “may,” unless specifically stated otherwise, or otherwise understood within the context as used, is generally intended to convey that certain implementations could, but do not necessarily, include certain features and/or elements while other implementations may not. Thus, such conditional language generally is not intended to imply that features and/or elements are in any way required for one or more implementations or that one or more implementations necessarily include these features and/or elements. It is also intended that, unless expressly stated, the features and/or elements presented in certain implementations may be used in combination with other features and/or elements disclosed herein.
The specification and annexed drawings disclose example embodiments of the present disclosure. Detail features shown in the drawings may be enlarged herein to more clearly depict the feature. Thus, several of the drawings are not precisely to scale. Additionally, the examples illustrate various features of the disclosure, but those of ordinary skill in the art will recognize that many further combinations and permutations of the disclosed features are possible. Accordingly, various modifications may be made to the disclosure without departing from the scope or spirit thereof. Further, other embodiments may be apparent from the specification and annexed drawings, and practice of disclosed embodiments as presented herein. Examples disclosed in the specification and the annexed drawings should be considered, in all respects, as illustrative and not limiting. Although specific terms are employed herein, they are used in a generic and descriptive sense only, and not intended to the limit the present disclosure.
This application is a continuation of U.S. patent application Ser. No. 16/862,112, filed Apr. 29, 2020, which is a continuation of U.S. patent application Ser. No. 16/294,660, filed Mar. 6, 2019, now U.S. Pat. No. 10,669,824, which claims the benefit of U.S. Provisional Application No. 62/639,388, filed Mar. 6, 2018, and is a continuation-in-part of U.S. application Ser. No. 15/048,491, filed Feb. 19, 2016, now U.S. Pat. No. 10,273,789, which claims the benefit of U.S. Provisional Application No. 62/118,575, filed Feb. 20, 2015, the entire contents of each of which is incorporated herein by reference.
Number | Date | Country | |
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62639388 | Mar 2018 | US | |
62118575 | Feb 2015 | US |
Number | Date | Country | |
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Parent | 16862112 | Apr 2020 | US |
Child | 17147186 | US | |
Parent | 16294660 | Mar 2019 | US |
Child | 16862112 | US |
Number | Date | Country | |
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Parent | 15048491 | Feb 2016 | US |
Child | 16294660 | US |