Embodiments of the present disclosure generally relate to an operating tool for an artificial lift system.
A conventional oil well includes a cased wellbore with at least one string of tubing extending downwardly through the casing into the oil or other petroleum fluid contained in the subsurface mineral formation to be produced. The casing is perforated at the level of the production zone to permit fluid flow from the formation into the casing, and the lower end of the tubing string is generally open to provide entry for the fluid in the tubing.
Many hydrocarbon wells are unable to produce at commercially viable levels without assistance in lifting the formation fluids to the earth's surface. In some instances, high fluid viscosity inhibits fluid flow to the surface. More commonly, formation pressure is inadequate to drive fluids upward in the wellbore. In the case of deeper wells, the hydrostatic head that acts downwardly against the formation inhibits the unassisted flow of production fluid to the surface.
In many instances, artificial lift may be required to raise the produced fluids to the surface. A common approach for urging production fluids to the surface uses a mechanically actuated, positive displacement pump driven from the surface by a pumping unit, such as a pump jack connected to the pump by a sucker rod string. Reciprocal movement of the sucker rod string induces reciprocal movement of the pump for lifting production fluid to the surface.
For example, an artificial lift system 20 is shown in
The production fluid F may not produce naturally to reach the surface so operators use the artificial lift system 20 to lift the fluid F. The artificial lift system 20 has a surface pumping unit 22, a sucker rod string 24, and a downhole pump 30. The surface pumping unit 22 reciprocates the sucker rod string 24, and the reciprocating sucker rod string 24 operates the downhole pump 30. The pump 30 has internal components attached to the sucker rod string 24 and has external components positioned in a pump-seating nipple 31 near the producing zone and the perforations 17.
As best shown in the detail of
The barrel 40 has a standing valve 42, and the plunger 32 has a traveling valve 34. For example, the standing valve 42 disposed in the barrel 40 can be a check valve having a ball 44 and seat 46. Similarly, the traveling valve 34 can also be a check valve (e.g., one-way valve) having a ball 36 and seat 38.
As the surface pumping unit 22 reciprocates, the sucker rod string 24 reciprocates in the production tubing 26 and moves the plunger 32. The plunger 32 moves the traveling valve 34 in reciprocating upstrokes and downstroke. During an upstroke, the traveling valve 34 is closed (i.e., the upper ball 36 seats on upper seat 38). In some instances, the hydraulic force acting on the plunger 32 during the upstroke may exceed 30,000 pounds
Movement of the closed traveling valve 34 upward reduces the static pressure within the pump chamber 45b (the volume between the standing valve 42 and the traveling valve 34 that serves as a path of fluid transfer during the pumping operation). This, in turn, causes the standing valve 42 to unseat so that the lower ball 44 lifts off the lower seat 46. Production fluid F is then drawn upward into the chamber 45b.
Ultimately, the produced fluid F is delivered by positive displacement of the plunger 32, out passages 45a in the barrel 40. The moved fluid then moves up the wellbore 10 through the production tubing 26 to the wellhead 28. The production fluid is diverted from the wellbore via the flow line 29.
On the following downstroke, the plunger 32 moves downward in barrel 40 by the reciprocation applied by the pumping unit 22 via the sucker rod string 24. The weight of the sucker rod string 24 pushes the plunger 32 through the fluid in the barrel 40. The standing valve 42 closes as the standing ball 44 seats upon the lower seat 46. At the same time, the traveling valve 34 opens so fluids previously residing in the chamber 45b can pass through the valve 34 and into the plunger 32. The upstroke and down stroke cycles are repeated, causing fluids to be lifted upward through the wellbore 10 and ultimately to the earth's surface.
At some point, it may become necessary to disconnect or connect the sucker rod string 24 with the pump 30, such as in an oversize tubing pump installation where the pump plunger 32 is installed separately from the sucker rod string 24. In an insert pump or a standard tubing pump 30, the plunger 32 or other portions of the pump 30 may become sanded in, corroded, or otherwise difficult to remove from the wellbore 10. Typically, the sucker rod string 24 is not robust enough to transmit the necessary force required to remove stuck components without damaging the sucker rod string 24 for later use. In other instances, it may be desirable the remove only the sucker rod string 24 simply to adjust and maintain the sucker rod string 24 without removing either the plunger 32 or the barrel 40.
For these reasons, it may be desirable to use an on-off tool 50 on the sucker rod string 24, as shown in
To connect the sucker rod string 24 to the pump 30 disposed downhole, the on-off tool 50 connects automatically to the pump 30 as the sucker rod string 24 is lowered. The on-off tool 50 is rotated to the correct alignment position and uses the sucker rod string's weight to complete the connection. To disconnect the sucker rod string 24 from the pump 30, the on-off tool 50 is unlocked and disconnected by setting the pump 30 at the bottom of its stroke and turning the sucker rod string 24 in the release direction of the tool 50 while slowly picking up the sucker rod string 24. The on-off tool 50 can have either right-release or left-release direction based on the application and other equipment used.
The housing 52 includes a clutch tab 53 and an end shoulder 57. The key 70 includes a tab 73 and a shoulder 75. The engagement of the clutch tab 53 with the tab 73 limits the rotation of the housing 52 relative to the key 70 to align the key 70 relative to the housing 52. During a disconnecting operation of the tool 50, the engagement of the clutch tab 53 with the tab 73 aligns the oblong head 72 with the slot 60 such that the key 70 may be withdrawn from the housing 52.
The on-off tool 50 incorporates a cam-type system using the internal cam 58 under the spring's 56 force and being actuated (in a longitudinal direction) by rotating the cam 58 and the housing 52 relative to the key 70. This imparts torque, which requires the guide pins 59 to counteract the torque and to keep the cam 58 from rotating in the housing 52.
When connecting the key 70 to the housing 52 downhole, the housing 52 may be lowered onto the key 70 so that the housing 52 interfits and interlocks with the key 70. The connection is accomplished by the weight of the sucker rod string 24 above the housing 52, by a rotation of the sucker rod string 24 that causes relative rotary motion between the housing 52 and the key 70 to misalign the key head 72 with the slot 60, and by the locking action of the key's head 72 to the internal mechanism of the tool 50.
In particular, the key 70 inserts in a key slot 60 in the housing 52 so the key 70 in a locked position can engage a seat 62 and transmit the tensile forces exerted by the pumping unit 22 on the up stroke. The shoulder 75 of the key cooperates with the shoulder 57 of the housing 52 to transmit any compressive forces of the tool 50 to the plunger rod 33 and ultimately the plunger 32.
The housing 52 is lowered relative to the key 70. The head 72 of the key 70 has an oblong cross-section. If the key 70 is not properly aligned with the opening for the slot 60, then relative rotation between the housing 52 and key 70 can align the head 72 with the slot 60. Eventually, the housing 52 inserts over the key 70, which passes through the slot 60 in the housing 52. Passing up through the housing 52, the key 70 pushes the cam 58 against the bias of the spring 56, as shown in
To complete the connection, the sucker rod string 24 is rotated to rotate the housing 52 to misalign the head 72 with the slot 60. As the housing 52 is rotated, the cam 58 cooperates with the oblong head 72 and the spring 56 push the cam 58 over the head 72.
To disconnect the tool 50, sucker rod string 24 is rotated in a direction opposite of the direction of connecting the tool 50 to unlock the key 70 from the housing 52. For example, the sucker rod string 24 is rotated in a clockwise direction to rotate the housing 52 relative to the key 70. The cam 58 rotates with the housing 52, and the profile of the cam 58 slides along the key head 72. As the cam 58 slides along the key head 72, the cam 58 is forced to travel longitudinally within the housing 52 and thus compresses the spring 56. Rotation of the housing 52 relative to the key 70 is limited by the engagement of the clutch tab 53 with the tab 73. When the clutch tab 53 and tab 73 are engaged, the head 72 is aligned with the slot 60. The sucker rod string 24 can be lifted to withdraw the key 70 from the housing 52.
During use, for example, the key 70 and housing 52 are subjected to deformation due to downstroke and upstroke impacts. The housing's seat 62 deforms due to broaching of the key head 72, and the shoulder 75 and tab 73 of the key head 72 deforms from impact wear with the housing 52 as the pump 30 is stroked. Likewise, the shoulder 57 and clutch tab 53 is subjected to brinelling due to the impact with the key 70 as the pump 30 is stroked.
As wear progresses during use, the gap or play between the shoulder 57 and the shoulder 75 increases and produces a slide hammer effect as the play between the components progressively increases as wear occurs. The increased play between the housing 52 and the key 70 further beats the seat 62 against the head's bearing surface 75. Eventually, the key head 72 can break off due to impacts. Further, the wear of the clutch tab 53 and tab 73 may reduce their effectiveness in aligning the key head 72 with the slot 60 when disconnecting the tool. During high stroke speeds, the on-off tool 50 can also become disconnected, or the key 70 becomes unlocked from the housing 52, due to dynamic forces (axial loads and torque) imparted through the sucker rod string 24 coupled with low spring force on the cam 58.
The coil spring 56 biases the cam 58 toward the key head 72 to complete the connecting sequence. However, the coil spring 56 may fail to provide enough axial load needed to keep the tool 50 connected in higher speed pumping applications where the dynamics of the sucker rod string 24 can cause the key 70 to overcome the rotational torque needed to compress the coil spring 56, causing the tool 50 to disconnect.
The cam 58 has two forks 58f each having a cam profile. The cam profile is a helical progression with a gradual slope that corresponds to the profile of the key head 72. The key head 72 interfits with the cam 58 when the key 70 is locked within the housing 52. During the insertion of the key 70 into the housing 52, the profile of the head 72 engages of profile of the cam 58, which causes the cam 58 to travel within the housing 52 and compress the springs 56.
As shown in
To disconnect the tool 50 shown in
Thus, there exists a need in the art for a tool that can be reliably disconnected and reconnected downhole while having increased wear resistance.
In one embodiment, an operating tool includes a housing including a key slot. The operating tool further includes at least one biasing member disposed in the housing. The operating tool further includes a key including a key head having a key profile, wherein the key head is remove from the slot when aligned with the key slot. The operating tool further includes a cam including a cam profile, wherein the cam is disposed in the housing and biased toward the slot by the at least one biasing member, wherein the cam profile is configured to engage the key profile to align the key head with the key slot.
In one embodiment, an operating tool includes a housing including a slot and a seat. The operating tool further includes at least one biasing member disposed in the housing. The operating tool further includes a key including a key head and a shoulder. The operating tool further includes a cam including a pocket, a first clutch profile, and a second clutch profile, wherein the cam is disposed in the housing and biased toward the slot by the at least one biasing member. When operating tool is in a locked configuration, the key head is misaligned with the slot and the key head is disposed in the pocket of the cam, wherein the shoulder is configured to engage the seat when the key head is misaligned with the slot. When the operating tool is in an unlocked configuration, the first clutch profile and the second clutch profile are engaged with the key head and the key head is aligned with the slot.
In one embodiment, a method of using an operating tool, comprising disconnecting the operating tool. Disconnecting the operating tool includes unlocking the operating tool by rotating a housing of the operating tool relative to a key of the operating tool, wherein the rotation of the housing relative to the key is limited by the engagement of a clutch profile of a cam disposed within the housing with a key head of the key, wherein the key head is aligned with a slot of the housing when the clutch profile is engaged with the key head. Disconnecting the operating tool further includes moving the housing relative to the key to withdraw the key head from the slot.
So that the manner in which the above recited features of the present disclosure can be understood in detail, a more particular description of the disclosure, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only exemplary embodiments and are therefore not to be considered limiting of its scope, may admit to other equally effective embodiments.
To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures. It is contemplated that elements and features of one embodiment may be beneficially incorporated in other embodiments without further recitation.
The tool 100 may include a fitting 102, guide pins 104, the housing 110, the cam 140, the key 170, and one or more biasing members 190. The biasing member 190 may be a plurality of disk springs as shown in
The housing 110 has first and seconds end portions 114, 116 and defines an interior 112. The first end portion 114 connects to the fitting 102. The interior 112 defines a key slot 120 at the second end portion 116 of the housing 110. The key slot 120 terminates at a seat 122 within the housing 110. The second end portion 116 also includes an end shoulder 117.
Each fork 144 includes an interior surface 145 and a cam profile 150 having a helical progression along the fork 144. The cam profile 150 includes a lock profile 151 and a clutch profile 152. In some embodiments, and as shown in
The key 170 is shown in
The head 172 is configured to be inserted or removed the housing 110 once aligned with the slot 120. When the head 172 is inserted into the housing 110 past the slot 120, either the housing 110 or the key 170 may be rotated, such as clockwise by 90 degrees, to misalign the head 172 with the slot 120 to lock the key 170 to the housing 110. When the key 170 is locked to the housing 110, the shoulder 175 may engage the seat 122. The engagement of the seat 122 with the shoulder 175 transfers tensile forces during operation of the tool 100. Additionally, the shoulders 117 and 177 may be engaged when the tool 100 is in the connected. The shoulders 117 and 177 may have uniform surface areas. The cooperation of the shoulders 117, 177 may reduce wear of the shoulders 117, 177 as they contact one another during use of the tool 100 to improve the wear resistance and durability of the tool 110.
The tool 100 may be connected at its fitting 102 to a sucker rod string 24 with a coupling 25 and may be connected at its key 170 to the plunger rod 33 of a pump 30. For example, fitting 102 may be connected to the coupling 25 by a pin connector 102c and the key 170 may be connected to the plunger rod 33 via the box connector 178c. In some embodiments, the key 170 will be connected to the sucker rod string 24 and the fitting 102 may be connected to the plunger rod 33. As will be detailed below, locking and unlocking of the tool 100 is achieved through the interaction of the key 170 with the housing 110 and cam 140 biased by the biasing members 190.
To connect the tool 100, the key 170 is inserted into the housing 110 via the slot 120. As the key 170 is inserted into the housing 110 via the slot 120, the head 172 will engage the cam 140. The first profile portion 182 contacts the cam profile 150, such as contacting the clutch profile 152 as shown in
The key 170 is locked within the housing 110 because it cannot be withdrawn from the slot 120 due to the engagement of the shoulder 175 and the seat 122. The cam 140, the key head 172, and the biasing member 190 interact to maintain the misalignment of the key 170 with the slot 120 until an unlocking operation is performed.
Once the tool 100 is unlocked, the tool 100 may be disconnected as shown in
In some embodiments, the key 170 is connected to the sucker rod string 24 while the housing 110 is connected to the pump plunger 33. In some embodiments, the key 170 may be rotated by the sucker rod string 24 relative to the housing 110 to unlock or lock the tool 100.
In some embodiments, the on-off tool 100 may be used to connect and disconnect with a downhole tool that is not a pump.
In one embodiment, an operating tool includes a housing including a key slot. The operating tool further includes at least one biasing member disposed in the housing. The operating tool further includes a key including a key head having a key profile, wherein the key head is remove from the slot when aligned with the key slot. The operating tool further includes a cam including a cam profile, wherein the cam is disposed in the housing and biased toward the slot by the at least one biasing member, wherein the cam profile is configured to engage the key profile to align the key head with the key slot.
In some embodiments of the operating tool, the cam profile includes a clutch shoulder, wherein the clutch shoulder is configured to engage the key profile to align the key head with the key slot.
In some embodiments of the operating tool, the cam profile includes a lock profile.
In some embodiments of the operating tool, the lock profile has two or more pitches.
In some embodiments of the operating tool, the key profile includes a first profile portion and a second profile portion, wherein the clutch shoulder is configured to engage the first profile portion to align the key head with the key slot.
In some embodiments of the operating tool, the at least one biasing member is a plurality of disk springs.
In some embodiments of the operating tool, the housing includes a uniform shoulder configured to engage a uniform shoulder of the key.
In some embodiments of the operating tool, the cam includes a first fork and a second fork, wherein the cam profile is a first cam profile of the first fork, wherein the second fork includes a second cam profile.
In some embodiments of the operating tool, the operating tool further comprising at least one guide pin disposed in a corresponding slot of the cam.
In one embodiment, an operating tool includes a housing including a slot and a seat. The operating tool further includes at least one biasing member disposed in the housing. The operating tool further includes a key including a key head and a shoulder. The operating tool further includes a cam including a pocket, a first clutch profile, and a second clutch profile, wherein the cam is disposed in the housing and biased toward the slot by the at least one biasing member. When operating tool is in a locked configuration, the key head is misaligned with the slot and the key head is disposed in the pocket of the cam, wherein the shoulder is configured to engage the seat when the key head is misaligned with the slot. When the operating tool is in an unlocked configuration, the first clutch profile and the second clutch profile are engaged with the key head and the key head is aligned with the slot.
In some embodiments of the operating tool, the first clutch profile includes a first clutch shoulder and the second clutch profile includes a second clutch shoulder, wherein the first clutch shoulder and the second clutch shoulder are engaged with the key head in the unlocked configuration of the operating tool.
In some embodiments of the operating tool, the cam includes a first lock profile and a second lock profile.
In some embodiments of the operating tool, the first lock profile and the second lock profile have two or more pitches.
In some embodiments of the operating tool, the at least one biasing member is a plurality of disk springs.
In some embodiments of the operating tool, the housing includes a uniform shoulder configured to engage a uniform shoulder of the key.
In some embodiments of the operating tool, the operating tool further comprising at least one guide pin disposed in a corresponding slot of the cam.
In some embodiments of the operating tool, the housing is connectable to a sucker rod string and the key is connectable to a pump.
In one embodiment, a method of using an operating tool, comprising disconnecting the operating tool. Disconnecting the operating tool includes unlocking the operating tool by rotating a housing of the operating tool relative to a key of the operating tool, wherein the rotation of the housing relative to the key is limited by the engagement of a clutch profile of a cam disposed within the housing with a key head of the key, wherein the key head is aligned with a slot of the housing when the clutch profile is engaged with the key head. Disconnecting the operating tool further includes moving the housing relative to the key to withdraw the key head from the slot.
In some embodiments, the method of using the operating tool further includes connecting the operating tool after disconnecting the operating tool. Connecting of the operating tool includes inserting the key head into the slot, wherein the key head engages the clutch profile and the cam moves longitudinally relative to the housing away from the slot against the biasing force of at least one biasing member. Connecting the operating tool further includes rotating the housing to lock the key to the housing, wherein the biasing member causes the cam to travel longitudinally toward the slot as the housing is rotated until the key head is disposed in a pocket of the cam and misaligned with the slot, wherein a shoulder of the key head is engageable with a seat of the housing when the key is locked to the housing.
In some embodiments of the method of using the operating tool, the cam profile includes a clutch shoulder, wherein the rotation of the housing relative to the key is limited by the engagement the clutch shoulder with the key head.
While the foregoing is directed to embodiments of the present disclosure, other and further embodiments of the disclosure may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
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Number | Date | Country | |
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20220235616 A1 | Jul 2022 | US |