TECHNICAL FIELD
The present application generally relates to tools (e.g., kickover tools) for placement and removal of valves from side pocket mandrels.
BACKGROUND
The present application relates to valves such as waterflood/injection valves, gas lift valves (IPO Injection Pressure Operated and PPO Production Pressure Operated), chemical injection valves, shear orifice valves, orifice valves and dummy valves.
One of those, gas lift valves, are used to artificially lift oil from wells where there is insufficient reservoir pressure to produce the well. The associated process involves injecting gas through the tubing-casing anulus. Injected gas aerates the fluid to make the fluid less dense; the formation pressure is then able to lift the oil column and forces the fluid out of the wellbore. Gas may be injected continuously or intermittently, depending on the producing characteristics of the well and the arrangement of the gas-lift equipment.
A mandrel is a device installed in the tubing string of a gas-lift well onto which or into which a gas-lift valve is fitted. There are two common types of mandrels. In one conventional gas-lift mandrel, the gas-lift valve is installed as the tubing is placed in the well. Thus, to replace or repair the valve, the tubing string must be pulled. The second type is a sidepocket mandrel where the valve is installed and removed by wireline while the mandrel is still in the well, eliminating the need to pull the tubing to repair or replace the valve.
With the sidepocket mandrel, the gas lift valves are replaced with a kickover tool. The Kickover tool is lowered into wells to place and remove gas lift valves. Normally, a kickover tool is lowered downhole by wireline. A kickover arm of the kickover tool is actuated mechanically to actuate the kickover arm.
Existing kickover tools are generally intended for use in relatively vertical wells, i.e., wells with a deviation not more than about 45 degrees. Those designs are usually delivered by wireline. However, those designs have limited use in more horizontal wells that are prevalent now. Additionally, there are drawbacks associated with mechanical actuation of the kickover arm and the wireline deployment technique. Thus, there is a need for a kickover tool that will perform well in all situations and provide benefits in wells that are more horizontal.
The present application describes designs that address those issues and limitations associated with mechanically actuated kickover tools that are deployed by wireline in vertical holes.
SUMMARY
A non-limiting embodiment of the invention includes a tool for inserting and removing a valve in a mandrel having a body that extends in a longitudinal direction and has a first end and a second end. A hydraulic chamber is within the body and extending from the first end. The first end and the hydraulic chamber being hydraulically connectable to coiled tubing. A piston chamber is inside the body. The piston chamber extends from a second end of the body. One end of the piston chamber is hydraulically connected to the hydraulic chamber, and an opposite end of the piston chamber is connected with an opening that connects with outside of the body. A piston is slidably located within the piston chamber. When the piston is most distal from the hydraulic chamber the hydraulic chamber is fluidly connected through the opening with the outside of the body. An actuation device is connected to the piston. The actuation device has an actuation part having a first position and a second position. The piston is slidably connected with the actuation part and is fastened with the actuation part by way of a shear pin. When the shear pin is not sheared, upon actuation and movement of the piston the actuation part moves to the second position. The actuator device is mechanically connected to a kickover arm device. The kickover arm device has a non-kicked-over position and a kicked-over position. When the actuation part is in the first position, the kickover arm device is prevented from moving from the non-kicked-over position to the kicked-over position. When the actuation part is in the second position, the kickover arm tool is allowed to move from the non-kicked-over position into the kicked-over position.
BRIEF DESCRIPTION OF THE FIGURES
FIG. 1 shows a portion of a kickover tool.
FIG. 2 shows a portion of the kickover tool to the right of the portion shown in FIG. 1.
FIG. 3 shows a portion of the kickover tool to the right of the portion shown in FIG. 2.
FIG. 4 shows a portion of the kickover tool to the right of the portion shown in FIG. 3.
FIG. 5 shows a portion of the kickover tool to the right of the portion shown in FIG. 4.
FIG. 6 shows a portion of the kickover tool to the right of the portion shown in FIG. 5.
FIG. 7 shows a side view of a mandrel.
FIG. 8 shows a landing coupling portion.
DETAILED DESCRIPTION
In the following description, numerous details are set forth to provide an understanding of the present application. However, one skilled in the art will understand that the present application may be practiced without these details and that numerous variations or modifications from the described embodiments are possible.
As used here, the terms “above” and “below”; “up” and “down”; “upper” and “lower”; “upwardly” and “downwardly”; and other like terms indicating relative positions above or below a given point or element are used in this description to more clearly describe some embodiments. However, when applied to equipment and methods for use in wells that are deviated or horizontal, such terms may refer to a left to right, right to left, or diagonal relationship as appropriate.
As noted above, this application applies to kickover tools for use in connection with at least waterflood/injection valves, gas lift valves (IPO Injection Pressure Operated and PPO Production Pressure Operated), chemical injection valves, shear orifice valves, orifice valves and dummy valves.
FIG. 1 shows a first end of the kickover tool 100. The main body of the kickover tool 100 includes a first part 1. The first part 1 includes therein a pressure chamber 10 that extends along a longitudinal axis within the kickover tool 100. The first part 1 includes a female toothed region 11 that connects with a corresponding part of coiled tubing (not shown). The coiled tubing can provide pressure to the pressure chamber 10. Tubing other than coiled tubing can be used instead, e.g., piping or other materials. Wireline can also be used, and pressure in the chamber can be generated by a spring chamber or a nitrogen chamber. The spring chamber or nitrogen chamber could be actuated mechanically or by hydraulic pressure transmitted through the coiled tubing. Many attachment configurations can be used such as clamping, bolting or welding. Other gas type chambers can be used in place of the nitrogen chamber. The first part 1 connects to a second part 2. The first part 1 and the second part 2 can be secured to one another by one or more bolts 12. The first part 1 and the second part 2 could be replaced by a single unitary part or multiple parts.
FIG. 2 shows a portion of the kickover tool 100 to the right of the portion shown in FIG. 1. The second part 2 includes a snap lock portion 20. The snap lock portion 20 extends from the second part 2 in a radial direction and is moveable in and out in the radial direction. The in/out movement is achieved by spring action of the second part 2. The in/out motion can also be from hydraulic pressure, e.g., from the pressure chamber 10. The snap lock portion 20 has a stepped portion 20a that is configured to abut a corresponding surface in a landing coupling portion of a dowhole mandrel to provide a locking force in the uphole axial direction. The snap lock portion 20 also provides placement guidance for the kickover tool 100. An extension of the first part 1 connects to a third part 3. The first part 1 and the third part 3 are shown as separate parts but could be a single unitary part or multiple parts. The first part 1 and the third part 3 can be secured to one another by one or more bolts 12. The third part 3 includes an extension of the pressure chamber 10. The third part 3 also includes a locator key part 30. The locator key part 30 is supported on the third part 3 by springs 32 that provide bias in the radial direction and allows the locator key part 30 to move in/out in the radial direction. The locator key part 30 has protruding portions 34a, 34b, 34c, 34d, 34e and 34f that are formed in a predetermined pattern. There can be more or fewer protruding portions than shown. The pattern of protruding portions 34a, 34b, 34c, 34d, 34e and 34f is designed to match a corresponding pattern of recesses on an inside surface of a landing coupling portion of a downhole mandrel to locate the kickover tool 100. That is, the locator key 30 will lock into a mandrel with a proper configuration of recesses, thereby locating the kickover tool 100 properly in the intended mandrel. Though springs 32 are shown, a number of biasing devices could be used including elastomeric materials, cushions, linear springs, etc.
FIG. 3 shows a portion of the kickover tool 100 that is to the right of the portion shown in FIG. 2. A fourth part 4 is connected with the third part 3. The fourth part 4 and the third part 3 could be a single unitary part or multiple parts. The fourth part 4 makes up a valve 40 comprising an outer valve portion 40a and an inner valve portion 40b. The inner valve portion 40b is slidably located within the outer valve portion 40a. At least one passageway 46 fluidly connects a volume 42 inside the inner valve 40b to outside the kickover tool 100. The volume 42 is hydraulically connected with the pressure chamber 10. The inner valve 40b has a first position where the inner valve 40b is to the left. The inner valve 40b has a second position that is to the right. When the inner valve 40b is in the first position (to the left) the passageway 46 is open and the volume 42 is hydraulically connected to the outside of the kickover tool 100. When the inner valve 40b is in the second position (to the right) the passageway 46 is closed and the volume 42 is not connected to the outside of the kickover tool 100.
One advantage of the configuration described above is an ability to flush out debris that may be present in an inside diameter of a wellbore or completion component. Also, this configuration allows the coiled tubing to be filled by pumping while running in hole (if desired) without building up pressure differential or trapping air in the coiled tubing. Further, the configuration allows circulation to be maintained while running in hole to ensure that the coiled tubing can pump down the coil, which is related to well control reasons. That is, when the inner valve 40b is in the first position (to the left) fluid can be forced through the pressure chamber 10 and out the passageway 46 thereby performing the flushing out operation. The valve 40b can be moved from the first position (to the left) to the second position (to the right) by increasing the flow of fluid through the volume 42.
FIG. 3 shows a fifth part 5 that is connected with the fourth part 4. The fourth part 4 includes an extension 43 of the pressure chamber 10. The fifth part 5 and the fourth part 4 can be a unitary part or multiple parts. Further, the fifth part 5 includes a hydraulic piston chamber 10b. A hydraulic piston 50 is located inside the hydraulic piston chamber 10b. A first end of the piston 50a is hydraulically connected to the extension 43. As hydraulic pressure increases in the extension 43 pressure is transferred to the end 50a of the piston 50. The piston 50 moves within the piston chamber 10b.
FIG. 4 shows a portion of the kickover tool 100 that is to the right of the portion shown in FIG. 3. The piston 50 extends within the piston chamber 10b. A downhole side 10c of the piston chamber is shown. The piston chamber 10c is hydraulically connected to outside the kickover tool 100 by way of passageways 54. As is shown, when a certain pressure is applied to the end 50a a shear pin 15 is sheared and allows movement. When the end 50a moves to the right, the extension 43 becomes fluidly connected through the piston chamber 10b, the piston chamber 10c, and passageways 54 to allow for pressure relief. The fifth part 5 connects with a sixth part 6. The fifth part 5 and the sixth part 6 could be a single unitary part or multiple parts. An orientation key 60 is connected to the surface of the sixth part 6. The orientation key 60 comprises a protruding portion that extends beyond a surface of the sixth part 6. The orientation key 60 can be movable in/out in the radial direction and can be biased by springs 62 in the radial direction. Bolts 61 can be used to secure the orientation key 60. In operation, as the kickover tool 100 is lowered downhole and in proximity to a mandrel, orienting sleeves (FIG. 7) are encountered. The orienting sleeves are angled and contact the orientation key 60 thereby rotating the kickover tool 100 to a proper angle. A downhole direction orienting sleeve can be used, and an uphole orientating sleeve can be used. As the orienting key 60 passes through the downhole orienting sleeve in the downhole direction the kickover tool 100 is rotated. Also, as the orienting key 60 travels through the orienting sleeve in the uphole direction, the kickover tool 100 rotates. That aspect is beneficial because when lowering in the downhole direction, there is potential for the orienting key 60 to contact a “point” of the orienting sleeve and to not achieve rotation. Thus, by lowering the kickover tool 100 and then raising the kickover tool 100 within a mandrel, any chances of the kickover tool 100 being improperly oriented are greatly reduced.
FIG. 5 shows an extension 50c of the piston 50 that extends into a seventh part 7. The piston extension 50c connects with and extends into an actuation part 56 that is slidably located inside the seventh part 7. The actuation part 56 is biased to the left by a spring 59. The actuation part 56 is within and adjacent to another actuation part 58. Shear pins 57 extend from the actuation part 56 into the piston extension 50c. A shear pin 63 can extend between the actuation part 56 and the actuation part 58 as shown and can shear under certain force. Alternatively, no shear pin can be present between the actuation part 56 and the actuation part 58. Also, the actuation part 56 and the actuation part 58 can be a single unified part. Under a certain force, the shear pins 57 will shear, but absent shear the movement of the piston extension 50c and the actuation part 56 is unified. The actuation part 58 has a first position that is to the left and a second position that is to the right. As shown, the actuation part 58 has an “L” shaped tip that can impede an actuation pin 72. Upon movement to the right of actuation part 56 actuation part 58 will move to the right until further movement is prevented by a kickover arm 71. Upon application of a certain pressure of the piston 50 to actuation part 56, the shear pin 63 between actuation part 56 and actuation part 58 will shear and actuation part 56 will continue to move to the right into actuation part 58 until movement is prevented. Thus, once the shear pin 63 is sheared, when the actuation part 56 is withdrawn to the left, the spring 59 will extend and maintain the actuation part 58 in the position to the right abutting the kickover arm 71. As shown in FIG. 5, during extension of the piston 50, actuation part 56 will abut a shoulder 64 formed in part 7. Once movement to the right of actuation part 56 is prevented there, further stroke of the piston extension 50c into the actuation part 56 occurs by shearing of the shear pins 57 upon application of a certain force. The further stroke can allow the piston end 50a to move to the right into the piston chamber 10c thereby connecting the piston chamber 10 with the passages 54 to release pressure.
The kickover arm tool 70 is connected with the seventh part 7. The kickover arm tool 71 is rotatable with respect to the seventh part 7 by way of a hinge mechanism 74. Any rotating connection can be made so that the kickover arm 74 is in rotational connection with respect to the seventh part 7. The actuation pin 72 is connected to the kickover arm 71 and is positioned so that when the actuation part 58 is in the first position (to the left) the pin 72 is adjacent to the “L” part of the actuation part 58 thereby preventing counterclockwise rotation of the kickover arm 71. When the actuation part 58 moves to the second position (to the right), the kickover arm 71 is no longer prevented from rotating in a counterclockwise direction and moves to the kicked-over position.
FIG. 6 shows a portion of the kickover tool 100 further to the right than that shown in FIG. 5. The kickover arm 71 farther to the right, a second kickover arm 81, a valve port 200 and a spring 90 are shown. The spring part 90 provides bias to move the kickover arm 71 and a kickover arm 81 into a kicked-over position once the actuation part 58 moves to the second position (to the right). The force of the springs 90 causes the kickover arm 71 to rotate counterclockwise and the kickover arm 81 to rotate clockwise. The resulting kicked-over configuration leaves the kickover arm 71 at an angle compared to the longitudinal axis of the kickover tool 1 and the kickover arm 81 extending substantially parallel to the longitudinal axis of the kickover tool 100. That configuration leaves the kickover arm 81 in position to enter a side pocket of a mandrel.
Referring back to FIG. 5, as the piston 50 actuates and moves forward, due to the shear pins 57 and shear pin 63, the actuation part 56 and actuation part 58 are moved forward until the actuation part 58 is in the second position and contacts the kickover arm 71. Once the actuation part 58 is moved into the second position to the right out of alignment with the actuation pin 72, the kickover arms 71, 81 move to the kicked-over position. Upon further actuation of the piston 50, the actuation part 56 applies a force that shears the pin 63 between the actuation part 56 and the actuation part 58 and moves farther to the right. Upon further actuation of the piston 50 the actuation part 56 moves to the right until the actuation part 56 encounters the shoulder 64 in the seventh part 7 that prevents further movement. At that point, as the piston 50 continues extension, the seventh part 7 is moved with the piston 50 toward an extended position thereby locating the second kickover arm 81 and the valve port 200 (with valve in actual use) into a side pocket mandrel, where the valve (not shown) is either placed or removed into/from the side pocket mandrel. During the movement of the piston, pressure inside the piston chamber 10b is at a level thereby driving the piston 50 outward and moving the part 7. Given no impedance, once the piston 50 reaches the end of the stroke, the piston chamber 10 connects through the passages 54 to release pressure. If the snap lock portion 20 is engaged and if the kickover arm 81 is properly located with the side pocket mandrel, resistance will be provided against the piston stroke before the piston 50 reaches full stroke. Additional pressure is then applied thereby increasing pressure to a point where the shear pins 57 shear thereby providing additional stroke so that the piston end 50a can move to the right in the piston chamber 10c thereby providing connection through openings 54 and releasing pressure. The pressure in the piston chamber can be tracked, thereby providing indication that the tool has properly moved into a side pocket mandrel. For example, a minimum pressure will be reached as the piston 50 extends and moves part 7, a second minimum pressure will be reached in the piston chamber when the tool bottoms out in a side pocket mandrel before the pins 57 shear, and a pressure release will occur when the pins 57 shear and the piston 50 moves to full stroke thereby allowing for pressure to be released through the opening 54. In contrast, if bottoming out does not occur, resistance will not be encountered and the minimum pressure indicative of the pins 57 shearing will not be reached.
FIG. 7 shows a side view of a cross section of a mandrel. A downhole orienting sleeve and an uphole orienting sleeve are shown. As noted earlier, the downhole orienting sleeve and the uphole orienting sleeve can each interact with the orientation key 60. The body pipe includes a pocket assay wherein the valve is located. The mandrel is connected to production tubing at the thread sub.
FIG. 8 is a closer view of a portion of the mandrel, focusing on the snap latch profile and the locator key profile. The snap latch profile interacts with the snap lock portion 20. The locator key profile interacts with the locator key part 30.
The previous description mentions a number of devices, including mandrels and valves. Detailed specifications for both are available at www.slb.com (Schlumberger's website) and they are available for purchase from Schlumberger.
Also, one should note that this invention is in no way limited to applications concerning the valves noted herein, and can extend to other applications including but not limited to the noted valve applications.
The preceding description is meant to illustrate certain features of embodiments and are not meant to limit the literal meaning of the claims as recited herein.