Patent Grant
10801291
Not applicable.
Not applicable.
This section is intended to introduce various aspects of the art, which may be associated with exemplary embodiments of the present disclosure. This discussion is believed to assist in providing a framework to facilitate a better understanding of particular aspects of the present disclosure. Accordingly, it should be understood that this section should be read in this light, and not necessarily as admissions of prior art.
The present disclosure relates to the field of hydrocarbon recovery operations. More specifically, the present invention relates to a system for hanging a string of production tubing in a wellbore without applying appreciable torque to a banded chemical injection line downhole. The invention also relates to a method of hanging production tubing in a wellbore, in tension.
In the drilling of oil and gas wells, a wellbore is formed using a drill bit that is urged downwardly at a lower end of a drill string. The drill bit is rotated while force is applied through the drill string and against the rock face of the formation being drilled. After drilling to a predetermined depth, the drill string and bit are removed and the wellbore is lined with a string of casing. An annular area is thus formed between the string of casing and the formation. A cementing operation is typically conducted in order to fill or “squeeze” the annular area with cement. The combination of cement and casing strengthens the wellbore and facilitates the isolation of zones behind the casing for the production of hydrocarbons.
It is common to place several strings of casing having progressively smaller outer diameters into the wellbore. In this respect, the process of drilling and then cementing progressively smaller strings of casing is repeated several times until the well has reached total depth. The final string of casing, referred to as a production casing, is typically cemented into place.
As part of the completion process, the production casing is perforated at a desired level. Alternatively, a sand screen may be employed in the event of an open hole completion. Either option provides fluid communication between the wellbore and a selected zone in a formation. In addition, production equipment such as a string of production tubing, a packer and a pump may be installed within the wellbore.
As part of the completion process, a wellhead is installed at the surface. The wellhead includes a tubing-hanger used to gravitationally support the production tubing. Fluid gathering and processing equipment such as pipes, valves and separators are also provided. Production operations may then commence.
During the production process, the production tubing may experience thermal expansion over time. This is due to the presence of warm production fluids being produced up through the pipe and to the surface. To offset the anticipated expansion, it is known to place the production tubing under some degree of tension when the well is completed. This will maintain the production tubing in a linear state even while the pipe string relaxes in response to thermal expansion.
Typically, the tubing string may be tensioned approximately one inch for every 1,000 feet of tubing in order to minimize buckling. This way the travel distance associated with the expansion will be less than the distance the tubing is stretched during tensioning. Thus, even when the tubing expands over time, the tubing does not buckle within the wellbore during the production process but remains somewhat taut. This is of particular benefit when the wellbore is being rod pumped as pre-tensioning minimizes frictional engagement between the rod string and the surrounding production tubing.
In connection with hanging the tubing in the wellbore, it is also sometimes desirable to provide a fluid supply line such as a chemical injection line into the well. The chemical injection line extends from the tubing hanger at the surface, and down to a packer or pump downhole. Most existing tubing tensioning arrangements prevent the use of a fluid supply line that will descend through and below the tubing hanger. Moreover, known tubing hangers generally require that the tubing string be rotated or turned five or more times in connection with setting the tubing anchor and locking the tubing hanger. However, stainless steel chemical injection lines cannot tolerate the stress and tension induced by rotation of the tubing string.
Accordingly, a need exists for a tubing hanger that enables hanging tubing from a tubing head at the surface with less than one complete rotation of the production string from the surface. Further, a need exists for a tubing hanging system that is able to accommodate a chemical injection line being run down to the tubing anchor within the wellbore. Still further, a need exists for a tubing anchor/catcher that allows slips to be actuated to engage the surrounding casing with less than a full tubing rotation
A tubing hanger system for suspending a tubing string within a wellbore is provided. The system is designed to hold the tubing string in tension within the wellbore. The tubing hanger system comprises a tubing hanger and a separate tubing anchor. Both the tubing hanger and the tubing anchor are designed to reside in series with the production tubing.
The tubing hanger is threadedly connected to the tubing string at an upper end of the tubing string, and is configured to reside within a tubing head over the wellbore. The tubing hanger comprises a short tubular assembly having an inner diameter, an outer diameter, and a bore extending along its length. The tubing hanger also has a beveled shoulder along the outer diameter which is configured to land on a matching conical surface machined along the tubing head. Upon landing, the tubing hanger gravitationally supports the tubing string in tension.
The tubing anchor is also threadedly connected to the tubing string. Specifically, the tubing anchor is threadedly connected to the tubing string proximate a lower end of the tubing string. Thus, the tubing anchor resides within a string of production casing downhole. The result is that the tubing hanger is at the upper end of the tubing string and the tubing hanger is proximate a lower end of the tubing string.
Beneficially, the tubing hanger and the tubing anchor are each configured to be set through a rotation of the tubing string that is less than one full rotation. The tubing hanger is set in the tubing head, while the tubing anchor is set downhole in production casing. This enables use of a stainless steel chemical injection line extending from the tubing hanger to the tubing anchor.
In one aspect, the tubing hanger comprises a tubular assembly and a mandrel assembly. The tubular assembly comprises:
Of interest, the beveled shoulder resides along a bottom end of the interlocking bottom ring.
The mandrel assembly defines a tubular body that is configured to be slidably received within the bore of the tubular assembly. In one aspect, the mandrel assembly comprises:
In one embodiment, the mandrel assembly comprises:
During completion, the tubular assembly is placed along an inner diameter of the tubing head. As noted, the beveled shoulder of the tubular assembly will land on the conical surface machined into the inner diameter of the tubing head. The tubular assembly is then rotationally locked into place.
Next, the mandrel assembly is secured to the top joint of the production tubing. The mandrel assembly with connected production tubing is then lowered into the wellbore until the tubing anchor is at a desired location downhole. The tubing anchor is then set.
Next, the mandrel assembly is moved back up the wellbore in order to apply the desired tension to the production tubing. The angled shoulders of the bottom mandrel are lifted along the spaces provided between the splines of the cylindrical interlocking bottom ring. Once the angled shoulders have cleared the splines, the mandrel assembly is rotated less than 180 degrees, and the mandrel assembly is then set down onto the splines in order to lock the mandrel assembly and gravitationally supported tubing string in place. Preferably, a rotation of the mandrel assembly and connected tubing string by less than 180 degrees comprises a rotation of the mandrel assembly by a one-quarter turn clockwise relative to the bore of the tubular assembly.
The tubing hanger system may also comprise a channel machined through each of the interlocking top ring and the bottom mandrel along a longitudinal axis. The channel is designed to carry an injection fluid. A fitting may be provided at a lower end of the channel. The fitting is machined into the bottom mandrel for sealingly receiving a top end of a chemical injection line. The chemical injection line extends downhole from the fitting to the tubing anchor. In this way, a chemical treatment fluid may be injected into the channel and then into the chemical injection line, where it is transmitted downhole to the tubing anchor.
As noted, the tubing hanger assembly also includes a tubing anchor. In one aspect, the tubing anchor comprises:
wherein the locking body comprises a channel along an outer diameter dimensioned to mechanically connect to a lower end of the chemical injection line.
A method for hanging a string of production tubing in a wellbore, in tension, is also provided herein. The method employs the tubing hanger system as described above, in any of its various embodiments.
The method first includes providing a tubing hanger system. The tubing hanger system includes the tubing hanger and the tubing anchor, wherein the tubing hanger and the tubing anchor are each configured to be set through a rotation that is less than one full rotation.
The method also includes threadedly connecting a joint of production tubing to the tubing anchor. The method then includes running a string of production tubing into the wellbore, joint-by-joint, wherein the tubing anchor is threadedly connected to the production tubing proximate a lower end of the production tubing.
As part of the method, a steel chemical injection line is banded or clamped to the o.d. of the tubing joints. An upper end of the chemical injection line is connected to the channel at the lower end of the bottom mandrel. This may be by means of a compression fitting.
The method additionally includes threadedly connecting the tubing hanger to the string of production tubing at an upper end of the production tubing. The method then includes lowering the tubing hanger so as to land the tubing hanger onto a landing surface of the tubing head above the wellbore. Preferably, the landing surface of the tubing head comprises an inner conical surface machined into the inner diameter of the tubing head. In any instance, the tubing hanger gravitationally supports the production tubing.
The method further comprises setting the tubing anchor within a string of surrounding production casing within the wellbore. The method then includes applying tension to the tubing string.
In accordance with embodiments of the invention, the method additionally comprises setting the tubing hanger within a tubing head at a surface above the wellbore. In operation, a rotation of the mandrel assembly within the bore of the tubular assembly while the angled shoulders of the top mandrel are above the splines of the cylindrical interlocking bottom ring locks the tubing anchor in place within the production casing. This is followed by a rotation of the mandrel assembly and connected tubing string by less than 180 degrees, but sufficient to lock the mandrel assembly from further longitudinal movement within the wellbore.
The method may then include producing hydrocarbon fluids to the tubing hanger at the surface.
So that the manner in which the present inventions can be better understood, certain illustrations, charts and/or flow charts are appended hereto. It is to be noted, however, that the drawings illustrate only selected embodiments of the inventions and are therefore not to be considered limiting of scope, for the inventions may admit to other equally effective embodiments and applications.
Definitions
For purposes of the present application, it will be understood that the term “hydrocarbon” refers to an organic compound that includes primarily, if not exclusively, the elements hydrogen and carbon. Hydrocarbons may also include other elements, such as, but not limited to, halogens, metallic elements, nitrogen, oxygen, and/or sulfur.
As used herein, the term “hydrocarbon fluids” refers to a hydrocarbon or mixtures of hydrocarbons that are gases or liquids. For example, hydrocarbon fluids may include a hydrocarbon or mixtures of hydrocarbons that are gases or liquids at formation conditions, at processing conditions, or at ambient condition. Hydrocarbon fluids may include, for example, oil, natural gas, coalbed methane, shale oil, pyrolysis oil, pyrolysis gas, a pyrolysis product of coal, and other hydrocarbons that are in a gaseous or liquid state.
As used herein, the terms “produced fluids,” “reservoir fluids” and “production fluids” refer to liquids and/or gases removed from a subsurface formation, including, for example, an organic-rich rock formation. Produced fluids may include both hydrocarbon fluids and non-hydrocarbon fluids. Production fluids may include, but are not limited to, oil, natural gas, pyrolyzed shale oil, synthesis gas, a pyrolysis product of coal, oxygen, carbon dioxide, hydrogen sulfide and water.
As used herein, the term “fluid” refers to gases, liquids, and combinations of gases and liquids, as well as to combinations of gases and solids, combinations of liquids and solids, and combinations of gases, liquids, and solids.
As used herein, the term “wellbore fluids” means water, hydrocarbon fluids, formation fluids, or any other fluids that may be within a wellbore during a production operation.
As used herein, the term “gas” refers to a fluid that is in its vapor phase.
As used herein, the term “subsurface” refers to geologic strata occurring below the earth's surface.
As used herein, the term “formation” refers to any definable subsurface region regardless of size. The formation may contain one or more hydrocarbon-containing layers, one or more non-hydrocarbon containing layers, an overburden, and/or an underburden of any geologic formation. A formation can refer to a single set of related geologic strata of a specific rock type, or to a set of geologic strata of different rock types that contribute to or are encountered in, for example, without limitation, (i) the creation, generation and/or entrapment of hydrocarbons or minerals, and (ii) the execution of processes used to extract hydrocarbons or minerals from the subsurface.
As used herein, the term “wellbore” refers to a hole in the subsurface made by drilling or insertion of a conduit into the subsurface. A wellbore may have a substantially circular cross section, or other cross-sectional shapes. The term “well,” when referring to an opening in the formation, may be used interchangeably with the term “wellbore.” When used in connection with a drilling process, the term “bore” refers to the diametric opening formed in the subsurface.
A tubing hanger system is provided herein. The tubing hanger system includes a tubing hanger (or “tensioner”) configured to reside at the wellhead, and a tubing anchor (or “catcher”) configured to reside downhole. Ideally, the tubing anchor is positioned just above or adjacent a fluid pump. Together, the tubing hanger and the tubing anchor hold a string of production tubing in tension during the production of hydrocarbon fluids.
Residing within the inner diameter 155 of the tubing head 100 is a tubing hanger 150 of the present invention, in one embodiment. The tubing hanger 150 is designed to gravitationally support the string of production tubing 220 from the surface. It is understood by those of ordinary skill in the art that by suspending the tubing string 220 from the surface, at least an upper portion of the tubing string 220 will reside in a state of tension.
It is observed that in long strings of jointed tubing, and particularly those in which a reciprocating pump is used, the portion of the tubing string 220 closest to a downhole tubing anchor will rest on an anchored pump barrel. This causes at least the lower portion of the tubing string 220 to go into compression. As thermal expansion occurs during the production of hot reservoir fluids, the string of production tubing 220 is further induced into compression. As noted above, this compression causes buckling along the wellbore which, in turn, causes premature wear of the rods and tubing during pump reciprocation. Accordingly, operators will pull the tubing string 220 into slight tension before “hanging,” and then lock the tubing string 220 into place using the tubing hanger 150. In known systems, this locking procedure requires multiple rotations of the tubing string 220.
In the arrangement of
It is noted that the tubing head 100 includes opposing lock pins 180. The lock pins 180 help secure the tubing string 220 in place within the bore 155. More specifically, the pins 180 lock in the interlocking top ring 110 which operatively supports the tubing string 220. This then allows a mandrel assembly (top mandrel 140 and bottom mandrel 160) to travel relative to a bore 205 of the well 200 (shown in
The tubing head 100 also includes one or more side outlets 185. The side outlets 185 are used during production to control annulus fluids and to allow access to the annulus by regulators during testing. Additionally, the tubing head 100 includes an injection conduit 175 for a treating fluid. The treating fluid may be, for example, a corrosion inhibitor. The injection conduit is in fluid communication with a chemical injection line 230 using, for example, a compression fitting 172.
The chemical injection line 230 is preferably a small-diameter, stainless steel tubing. The injection line 230 extends down into the wellbore 200 and terminates near the pump inlet. In this way, treating fluid is delivered proximate the reciprocating pump (not shown) below the anchor 900 to treat the downhole hardware.
The chemical injection line 230 is banded to joints of production tubing during run-in. Banding helps protect the chemical injection line 230.
The wellbore 200 includes a wellhead. Only the tubing head 100 (or “spool”) of
The wellbore 200 will also have a pump (not shown) within or just above the subsurface formation 250. The pump may be either a reciprocating pump or a progressive cavity pump. The pump, of course, is used to artificially lift production fluids up to the tubing head 100. In the case of a reciprocating pump, the pump will be cycled up and down by means of a mechanical “pump jack” or by means of a hydraulic or pneumatic rod pumping system residing at the surface 201 over the wellbore 200.
An anchor is set at the lower end of the production tubing 220. The anchor prevents a corresponding axial movement of the pump barrel during reciprocation of the rod string. In the event a progressive cavity pump (or “PCP”) is used, the rod string is used to rotate a rotor within a stator in the progressive cavity pump to pump hydrocarbon fluids to the surface.
In
The wellbore 200 is completed with a final string of casing, known as production casing 206. The production casing 206 extends down to the subsurface formation 250. The casing string 206 includes perforations 215 which provide fluid communication between the bore 205 and the surrounding subsurface formation 250. In some instances, the final string of casing is a liner.
Each string of casing 202, 204, 206 is set in place through cement (not shown). The cement is “squeezed” into the annular regions around the respective casing strings, and serves to isolate the various formations of the subsurface 210 from the wellbore 200 and each other. In some instances, a production casing is not used and the subsurface formation is left “open.” In this instance, a sand screen or a slotted liner may be used to filter fines and solids while permitting formation fluids to enter the wellbore 200.
The wellbore 200 further includes a string of production tubing 220. The production tubing 220 has a bore 228 that extends from the surface 201 down into the subterranean region 250. The production tubing 220 serves as a conduit for the production of reservoir fluids, such as hydrocarbon liquids. An annular region 208 is formed between the production tubing 220 and the surrounding tubular casing body 206.
It is observed that the present inventions are not limited to the type of casing arrangement used or the type of pump used. However, the inventions are beneficial for applying tension to the tubing string 220 while also accommodating a chemical injection line. Thus,
The interlocking top ring 110 is configured to reside within the bore 155 of the tubing head 100. Various seals or o-rings (seen in
It is observed that the body 116 of the interlocking top ring 110 provides a small through-channel 475. The through-channel 475 runs the length of the body 116. Upon assembly, the through-channel 475 is aligned with conduit 175. The through-channel 475 serves as a conduit for passing the fluid chemical treatment from conduit 175 down to injection line 230.
The body 116 of the of the interlocking top ring 110 also includes a radial indentation, or reduced outer diameter portion 111. The reduced outer diameter portion 111 is configured to receive the opposing lock pins 180. When the lock pins 180 are screwed into the tubing head 100, they may be further tightened down onto the reduced outer diameter portion 111 to rotationally hold the interlocking top ring 110.
The distal end 124 of the body 126 comprises a beveled shoulder 129. The beveled shoulder 129 rests on a conical surface (seen at 102 in
In operation, the tubular assembly comprising the chemical injection ring 130, the interlocking bottom ring 120 and the interlocking top ring 110 are lowered into the tubing head 100 together. The beveled shoulder 129 of the bottom ring 120 lands on the matching conical shoulder 102 of the tubing head 100. Then, lock pins 180 are tightened down onto the interlocking top ring 110 to prevent rotation.
Next, the tubing anchor 900 is set (discussed below). The mandrel assembly (top mandrel 140 and bottom mandrel 160) and connected production tubing 220 are raised up and located along the interlocking bottom ring 120. With the angled shoulders 148 above the splines 128, the mandrel assembly 140/160 (and connected tubing string 220) is then rotated about a quarter turn, and the mandrel assembly 140/160 is dropped in order to lock the angled shoulders 148 onto the splines 128. This fixes the tubing string 220 (both longitudinally and rotationally) in tension.
As noted, the tubing hanger 150 also includes a chemical transfer ring 130.
It is also noted that recesses 139 are formed along the body 136 at the proximal end 132. The recesses 139 are threaded and are dimensioned to receive bolts (shown at 121 in
Also of interest, the illustrative chemical transfer ring 130 has two or more o-rings (seen at 137 in
The interlocking top ring 110, the interlocking bottom ring 120 and the chemical transfer ring 130 together form a tubular assembly. The tubular assembly resides along the inner diameter (or bore 155) of the tubing head 100. Preferably, the tubular assembly 110/120/130 is installed when the last (or uppermost) joint of production tubing 220 has been run into the wellbore 200, and before the top 140 and bottom 160 mandrels are connected. The conical beveled shoulder 129 of the interlocking bottom ring 120 is landed on the conical surface 102 within the tubing head 100.
During well completion, the proximal end 162 of the bottom mandrel 160 is threadedly connected to the distal end 144 of the top mandrel 140 using a 2⅞″ EUE 8 round thread. The distal end 164 of the bottom mandrel 160 defines female threads that connect with the pin end of the uppermost joint of production tubing 220. Once the connection with the string of production tubing 220 is made, the top mandrel 140 and the bottom mandrel 160 are lowered in the wellhead 100 together until the tubing anchor 900 is at a desired depth within the production casing 206. The entire tubing hanger 150 is now in place.
It is again observed that the top mandrel 140 and the bottom mandrel 160 together form a mandrel assembly. The dimensions of the top 140 and bottom 160 mandrels may be changed to accommodate the size of the tubing head 100 and the tubular assembly
As noted, the tubing hanger system also includes a tubing anchor 900.
It is observed that the tubing anchor 900 defines a generally tubular body having a proximal end 912 and a distal end 914. A bore 905 is provided along the length of the tubing anchor 900. This allows production fluids to flow up the production tubing 220 and to the tubing head 100 at the surface 201.
The upper tubing connector 902 resides at the proximal, or top end 912. The tubing connector 902 provides a female “box” connection that receives a male “pin end” of a jointed tubing 220. In one aspect, the female connection has a 2⅞″ outer diameter and 2½″ ACME threads along the inner diameter.
The tubing anchor 900 is intended to be run into the wellbore 200 near the bottom of the tubing string 220. Below the tubing anchor 900, perhaps less than 100 feet, is a downhole pump (not shown). The pump, or at least the standing valve portion, is installed along the tubing string 220 using, for example, a tap-type puller having an anvil.
In practice, a first joint of tubing string 220 is lowered into the well 205 while keeping the proximal (or top) end 902 of the tubing anchor 900 still at the surface 201. Another section of pipe is connected to the tubing connector 902. From that point, a check valve (not shown) connected to the ¼″ chemical injection line 230 is banded to the joint of pipe. The check valve prevents chemical treatment fluid and wellbore fluids from running up the chemical injection line 230.
As joints of pipe 220 are added and depth increases, banding of the ¼′ line 230 continues. Once the desired depth is achieved for setting the tubing anchor 900, the tubular assembly 110/120/130 of the tubing hanger 150 is placed inside of the tubing spool 100 at the surface 201. Next, the mandrel assembly (top mandrel 140 and bottom mandrel 160) of the tubing hanger 150 is connected to the string of pipe 220 and is lowered towards the tubing head 100. Preferably, a tubular landing sub (not shown) is connected to the proximal (or top) end 142 of the top mandrel 140. The tubing string 220 is then further lowered to a position where the tubing anchor 900 is to be set in the production casing 106.
It is again observed here that the bottom mandrel 160 threads into the top mandrel 140 with a 2⅞″ EUE 8 round thread. Threads are shown in
The top mandrel 140 is landed on the interlocking bottom ring 120. The conical beveled shoulder 129 of the interlocking bottom ring 120 rests on the conical surface 102 within the tubing head 100. The production tubing 220 is now gravitationally hanging in tension due to the weight of the tubing string 220. The lock pins 180 from the tubing head 100, or “spool,” are then rotated to engage with the cylindrical interlocking top ring 110. Specifically, the lock pins 180 tighten down into the recessed outer diameter portion 111.
The top mandrel 140 may be turned into and out of its locked position. When the top mandrel 140 is out of its locked position, it can freely float within the well bore 205. In this unlocked position, the angled shoulders 148 slide vertically through the spaces 123 between the splines 128 of the interlocking bottom ring 120. The tubing string 220 is then lowered and comes to a position where the tubing anchor 900 will be set.
The tubing anchor 900 also includes slips 940. The slips 940 define a set of opposing slip segments representing upper 945U and lower 945L segments. Actuation of the slips 940 causes the tubing anchor 900 to be set in the production casing 106.
The tubing anchor 900 also comprises upper and lower slip bodies. The upper slip body is an independent tubular body shown at 910 in
A slot 911 in the upper slip body 910 (seen in
Of interest, and as discussed further below in connection with
The groove arrangement 915 allows the chemical injection line 230 to reside within the wellbore 200 without being damaged during run-in and without interfering with operation of the anchor 900 during setting. This unique arrangement enables a downhole pump and other downhole hardware to receive inhibitors that prevent build-up of paraffin, wax and corrosive elements that can lead to failure.
It is observed that the chemical injection line 230 need not terminate at the tubing anchor/catcher 900, but may continue on past the anchor 900 to the pump inlet.
Around the slips 940 is a cone 920.
The J-lock control body 930 is a generally tubular wall 936 having a proximal end 932 and a distal end 934. A channel 939 is preserved along the shoulder to accommodate the chemical injection line 230. In addition, a bore 935 is formed within the wall 936 for the transport of production fluids en route to the surface 201.
The proximal end 932 comprises the lower slip body 938. The slip body 938 has radially disposed slots 937. The slots 937 latch into the lower slip segment 945L. In addition, the wall 936 of the control body 930 includes opposing J-lock profiles 933. Action of a pin (not shown) along the J-lock profiles 933 allows the operator to actuate the slip segments 945 into biting engagement with the surrounding casing string 206.
It is noted that the J-Lock control body 930 is a modified version of a known tubing anchor/catcher. The known tubing anchor catcher will have certain components not seen in
During run-in, the J-pin ring is attached to a bottom sleeve (not shown) by shear pins. The shear pins temporarily fix the bottom sleeve along the body 936. Shearing of the pins allows the bottom sleeve to slide out of a landing position and to start actuation of the slip segments 945. It is noted though that the pins are only sheared when pulling up on the tubing, causing the slips to release. Turn to the right will not release the slips.
During setting of the tubing anchor 900, the tubing string 220 with connected anchor 900 is turned clockwise. This positions the J-pin ring into a diagonal portion of the J-slot 933. The string 220 is then lowered the distance of the J-slot 933. A lower slip sleeve (not visible) is connected to the lower slip body 938, which houses the two slips (upper 945U and lower 945L slip segments). A releasing slip is provided in both the upper 945U and the lower 945L slip segments, where each has three segments in which two hold and one releases. Both the lower slip sleeve and the lower slip body 938 begin sliding on the outside diameter of the tubing anchor body 936. Once engaged by the top sub connected to the proximal end 932, the lower slip body 938 begins a downward descent relative to the wellbore 200. The upper slip segment 945U and upper slip body 938 come into contact with a notch that is on the tubing anchor body 936. This action pins the sleeve and the lower slip body 938 between the notch and the top sub.
The sleeve and the lower slip body 938 now come into contact with the cone 920. The cone 920 is connected to the lower slip segment 945L. With the string 220 still moving downward, the cone 920 that is now in contact with the lower slips 945L force the cone 920 and lower slips 945L to come in contact with the slips 945 that are being housed in the upper end 932 of the J-Lock control body 930. Setting of the slips 945 is caused by pulling up on the anchor body, which causes the springs 933 to drag along the tubing to be turned to the left ⅛ (45°) turn. This action causes the slips 945U, 945L in the J-Lock control body 930 to grip the casing internal diameter. As the J-Pin approaches the end of the J-slot 933, the string 220 makes a counter-clockwise turn to prepare to set. Once the J-Pin is in position, the string 220 is pulled back up slightly to set the anchor 900 in place.
It is observed that the tubing anchor 900 is uniquely configured to lock into the casing slips 945 using only the a ⅛ (45°) turn. In contrast, known tubing anchors use several turns to lock and set. Tubing anchors that need several turns to set can result in entanglement of any chemical tubing lines, causing them to bend and break. Further, some tubing anchors are set through use of the pressure of the chemicals or hydraulic pressure in the ¼″ line, which actuates the slips. The draw back to chemical or hydraulic pressure is that the tubing anchor may not hold tightly in the casing. Also, splices that connect the main line together in order for the tubing anchor to actuate often fail to hold pressure, and leak. In contrast, the present tubing anchor design 900 does not require such splices; instead, the present tubing anchor 900 is actuated merely by pulling back up on the tubing string 220, allowing drag of the springs 933 to pull the control body 930 and shear pins, followed by the ⅛th turn clockwise.
The J-control body ring 950 comprises a generally circular body 956 having a proximal end 952 and a distal end 954. The ring 950 serves as a “no-go” gauge that keeps the anchor 900 from being lowered into crushed casing. A short bore 955 is formed there through. The distal end 954 is flanged, with the flange preserving a channel 959 to receive the chemical injection line 230.
A plurality of holes 953 are formed radially through the body 956. The holes 953 reside equi-distantly about the body 956. The holes 953 are dimensioned to receive bolts (not shown) that secure the body 956 to the body 936 of the J-lock control body 930.
Finally,
As can be seen, an improved tubing hanger assembly is provided. The tubing hanger assembly includes a tubing hanger 150 and a tubing anchor 900, each of which is set in a wellbore using less than a full rotation, and in a preferred embodiment, less than a 180° rotation.
Using the tubing hanger assembly 150/900, a method for hanging a string of production tubing in a wellbore is also provided herein. The method employs the tubing hanger system as described above, in any of its various embodiments.
The method first includes providing a tubing hanger system. The tubing hanger system includes the tubing hanger and the tubing anchor, wherein the tubing hanger and the tubing anchor are each configured to be set through a rotation that is less than one full rotation.
The method also includes threadedly connecting a joint of production tubing to the tubing anchor. The method then includes running a string of production tubing into the wellbore, joint-by-joint, wherein the tubing anchor is threadedly connected to the production tubing proximate a lower end of the production tubing.
The method additionally includes threadedly connecting the tubing hanger to the string of production tubing at an upper end of the production tubing. The method then includes lowering the tubing hanger so as to position the tubing anchor at a desired depth downhole.
The method further comprises setting the tubing anchor within a string of surrounding production casing within the wellbore. The method then includes applying tension to the tubing string. Applying tension to the tubing string means pulling on the production tubing from the surface.
In accordance with embodiments of the invention, the method additionally comprises setting the tubing hanger within a tubing head at a surface above the wellbore. This first comprises landing a tubular assembly within the bore of a tubing head forming a portion of the wellhead. The tubing hanger has a beveled shoulder along the outer diameter which is configured to land on a matching conical surface machined along the tubing head. This also includes threadedly connecting a mandrel assembly to the upper end of the production tubing.
The method further comprises banding a chemical injection line 230 to the production tubing 220, joint-by-joint, during run-in. An upper end of the injection line 230 is connected to a lower end of the bottom mandrel 160, such as through use of a compression fitting 172. In this way, a channel within the interlocking top ring 110 and the bottom mandrel 160 are in sealed fluid communication with the injection line 230. The chemical injection line 230 extends downhole from the fitting 172 to the tubing anchor 900. In this way, a chemical treatment fluid may be injected into the channel and then into the chemical injection line 230, where it is transmitted downhole to the tubing anchor 900.
In operation, the mandrel assembly (top mandrel 140 and bottom mandrel 160) of the tubing hanger 150 is lowered into the bore 205 in order to set the tubing anchor 900. Material for the hanger 150 is determined by the well conditions. After the tubing anchor 900 is set, the mandrel assembly (top mandrel 140 and bottom mandrel 160) and connected tubing string 220 are raised back up to pass through the bore 135 of the chemical transfer ring 130 and the bore 125 of the interlocking bottom ring 120. This involves moving the angled shoulders 148 of the top mandrel 140 up through the spaces 123 between the splines 128 until the mandrel assembly 140/160 comes to a stop within the interlocking top ring 110. The angled shoulders 148 have now cleared the splines 128 and the string of production tubing 220 in tension.
The mandrel assembly (top mandrel 140 and bottom mandrel 160) is then rotated ¼ turn clockwise relative to the bore 115 while the angled shoulders 148 are above the splines 128. The method then includes lowering the mandrel assembly 140/160 back down along the tubular assembly 110/12/130 in order to lock the tubing hanger within the surrounding production casing. This prevents further rotational and longitudinal movement of the mandrel assembly 140/160 within the wellbore 200.
Beneficially, the tubing hanger is set by pulling tension on the production tubing 220 and the connected chemical injection line 230 without undue torsional stress. Chemicals can now be supplied to the wellbore 205 through the injection conduit 175. Chemicals are then flushed through the splines 128 of the interlocking bottom ring 120. The chemical injection tubing 230 preferably terminates proximate a downhole pump below the tubing anchor within the wellbore.
In one embodiment of the method, an adapter is placed above the tubing hanger. More specifically, an adapter is threadedly connected to the top mandrel 140. A pocket is provided at the bottom of the adapter that is configured to receive the top mandrel 140 and seals the well.
At the upper end, the adapter provides a connection for a valve, a pumping tee or other hardware that is part of the well head. This top connection can be either threaded or studded with a ring groove.
The adapter includes a first port that allows for the injection of the chemical treatment fluid into the tubing hanger. This first port provides fluid access to the channel 175 in the interlocking top ring 110 and down to the channel 163 in the bottom mandrel 160. The adapter also includes second and third ports that enable testing of the seals on both the chemical channels 175, 163 and the tubing hanger body.
The adapter is an optional feature. It typically is not needed with low producing wells where the operator produces from the top connection of the tubing hanger. In any event, the method then includes producing hydrocarbon fluids to the tubing hanger at the surface, through the production tubing 220.
As can be seen, a tubing hanger system is provided that includes both a novel tubing hanger 150 and a novel tubing anchor 900. The tubing hanger system provides an assembly of engineered parts that enable a method of pulling tension in the tubing string 220 from the surface 201, and then holding that tension by means of a locking design. Once in the locking position, chemicals (such as corrosion inhibitors) can be pumped through the tubing hanger 150 and down an injection line 230. In one aspect, the system is able to hold tension without use of shear pins and springs, saving considerable manufacturing costs.
Another advantage of the tubing hanger system presented herein is the ability to transfer downward force created from the gravitational force on the tubing string 220, and lock the top mandrel body 140 within the tubing head 100. This, in turn, prevents further rotation about the longitudinal axis of the casing strings 202, 204, 206 within the wellbore 200.
Still another advantage of the tension hanger system is in the method of delivering chemicals that treat the pump or that treat the formation. Such chemicals may include steam, corrosion inhibitors, foam and water. Chemicals are able to be delivered downhole under minimal pressure while the tubing hanger is in its locked position and while maintaining a seal within the tubing hanger itself. Further, a seal is maintained within the casing spool where the tubing hanger suspends from the tubing head.
While it will be apparent that the inventions herein described are well calculated to achieve the benefits and advantages set forth above, it will be appreciated that the inventions are susceptible to modification, variation and change without departing from the spirit thereof.
This application claims the benefit of U.S. Ser. No. 62/370,524 filed Aug. 3, 2016. That application is entitled “Tubing Hanger System, And Method Of Tensioning Production Tubing In A Wellbore,” and is incorporated herein in its entirety by reference.
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| Entry |
|---|
| Office Action for Canadian patent app. No. 2,973,027, dated Mar. 28, 2019. |
| Logan Kline Tools Tubing Anchor, published prior to Aug. 3, 2016. |
| Number | Date | Country | |
|---|---|---|---|
| 20180038186 A1 | Feb 2018 | US |
| Number | Date | Country | |
|---|---|---|---|
| 62370524 | Aug 2016 | US |
