There are numerous tools for use in a subterranean well that can be remotely actuated by a hydraulic, electric, and/or other type of signal generated remote from the tool. Some of these tools further include provisions for mechanical actuation, for example, by a shifting tool manipulated from the surface. The mechanical actuation provides an alternative or contingency mode of actuation apart from actuation in response to the remote signal. In actuating the tool manually, however, the shifting tool must overcome the remote actuator mechanism or the remote actuator mechanism must be uncoupled from the actuated element of the tool.
Like reference symbols in the various drawings indicate like elements.
The well bore 104 is lined with a casing 112 that extends from the well head 106 at the surface 108, downhole, toward the bottom of the well 104. The casing 112 provides radial support to the well bore 104 and seals against unwanted communication of fluids between the well bore 104 and surrounding formations. Here, the casing 112 ceases at the subterranean zone 110 and the remainder of the well bore 104 is an open hole, i.e., uncased. In other instances, the casing 112 can extend to the bottom of the well bore 104 or can be provided in another configuration.
A completion string 114 of tubing and other components is coupled to the well head 106 and extends, through the well bore 104, downhole, into the subterranean zone 110. The completion string 114 is the tubing that is used, once the well is brought onto production, to produce fluids from and/or inject fluids into the subterranean zone 110. Prior to bringing the well onto production, the completion string is used to perform the final steps in constructing the well. The completion string 114 is shown with a packer 116 above the subterranean zone 110 that seals the annulus between the completing string 114 and casing 112, and directs fluids to flow through the completion string 114 rather than the annulus.
The example valve 102 is provided in the completion string 114 below the packer 116, for example, in a lower completion, below the upper completion. The valve 102 when open, allows passage of fluid and communication of pressure through the completion string 114. When closed, the valve 102 seals against passage of fluid and communication of pressure between the lower portion of the completion string 114 below the valve 102 and the upper portion of the completion string 114. The valve 102 has provisions for both mechanical operation and operation in response to a remote originating signal. For mechanical operation, the valve 102 has an internal profile that can be engaged by a shifting tool to operate the valve. For remote operation, the valve 102 has an actuator assembly that responds to a signal (e.g., a hydraulic, electric, and/or other signal) to operate the valve. The signal can be generated remote from the valve 102, for example at the surface.
In the depicted example, the valve 102 is shown as a fluid isolation valve that is run into the well bore 104 open, mechanically closed with a shifting tool and then eventually re-opened in response to a remote signal. The valve 102, thus allows an operator to fluidically isolate the subterranean zone 110, for example, while an upper portion of the completion string 114 is being constructed, while subterranean zones above the valve 102 are being produced (e.g., in a multi-lateral well), and for other reasons. The concepts herein, however, are applicable to other configurations of valves and/or other equipment. In one example, the valve 102 could be configured as a safety valve. A safety valve is typically placed in the completion string 114 or riser (e.g., in a subsea well), and is biased closed and held open by a remote signal. When the remote signal is ceased, for example, due to failure of the well system above the valve 102, the valve 102 closes. Thereafter, the valve 102 is mechanically re-opened to recommence operation of the well.
Turning now to
The valve closure 204 is coupled to an elongate, tubular actuator sleeve 210 via a valve fork 212. The actuator sleeve 210 is carried in the housing 202 to translate between an uphole position (to the left in
The valve 200 has provisions for remote operation to operate the valve closure 204 in response to remote signal (e.g., a hydraulic, electric, and/or other signal). To this end, the valve 200 has a remote actuator assembly 220 that is coupled to the actuator sleeve 210. The actuator assembly 220 is responsive to the remote signal to shift the actuator sleeve 210 axially and change the valve between the closed and open positions. While the actuator assembly 220 can take a number of forms, depending on the desired operation of the valve, in certain instances of the valve 200 configured as a fluid isolation valve, the actuator assembly 220 is responsive to a specified number of pressure cycles (increase and decrease) provided in the central bore 208 to release compressed spring 222 carried in the housing 202 and coupled to the actuator sleeve 210.
The valve 102 has provisions for mechanical operation to allow operating the valve closure 204 with a shifting tool inserted through the central bore 206. To this end, the actuator sleeve 210 has a profile 214 on its interior bore 216 that is configured to be engaged by a corresponding profile of the shifting tool. The profile 214 enables the shifting tool to grip the actuator sleeve 210 and move it between the uphole position and the downhole position, thus operating the valve closure 204. In the present example, the uphole position corresponds to the valve closure 204 being in the fully closed position and the downhole position corresponds to the valve closure 204 being the fully open position. The shifting tool can be inserted into the valve 200 on a working string of tubing and other components inserted through the completion string from the surface. One example of such an actuator sleeve and shifting tool are those sold with the fluid loss isolation barrier valve sold under the trade name FS by Halliburton Energy Services, Inc. However, other tools capable of gripping the internal profile and manipulating the actuator sleeve 210 could be used.
To facilitate mechanical operation of the valve 200 when the actuator assembly 220 has been actuated, the actuator sleeve 210 can be coupled to the actuator assembly 220 with a coupling assembly 224 that allows the actuator sleeve 210 to move apart from the actuator assembly 220. In other words, because of the coupling assembly 224, the actuator sleeve 210 can move without moving the mandrel 230. Coupling the actuator sleeve 210 to the remote actuator assembly 220 in this manner reduces the amount of force the shifting tool must apply to move the actuator sleeve 210 and allows the actuator sleeve 210 (and thus the valve closure 204) to operated manually both before and after actuating the actuator assembly 220 remotely. For example, in a configuration having a spring 222, the shifting tool does not have to compress the spring 222.
The valve 200 can thus be installed in the well bore and operated manually, with a shifting tool, to open and close multiple times, and as many times as is needed. Thereafter, the valve 200 can be left in a closed state and remotely operated to an open state via a remote signal. After being opened by the remote signal, the valve 200 can again be operated manually, with a shifting tool, to open and close multiple times, as many times as is needed.
Referring now to
The lower end of the mandrel 230 is received within an annular piston 302 to define a fluid chamber 306 bounded by and between the actuator sleeve 210 on the chamber's inner diameter, the piston 302 on its outer diameter and at one end the mandrel 230 and the piston 302 at the opposing end. The piston 302 is sealed to the outer diameter of the actuator sleeve 210 and to the outer diameter of the mandrel 230 with seals 304 and 314. The fluid chamber 306 is filled (substantially or entirely) with an incompressible (substantially or entirely) fluid. In certain instances, the fluid is a silicon oil that is substantially incompressible in that it is much more resistant to compression than an aerated incompressible liquid, foam or gas, but nonetheless, can undergo some degree of compression. In certain instances, the piston 302 includes check valve 320 in communication with the fluid chamber 206. The check valve 320 is biased to allow passage of fluid into the fluid chamber 206 and seal against passage of fluid out of the fluid chamber 206, to ensure the fluid chamber 206 is at or above the ambient pressure.
When the actuator assembly 220 is activated in response to a remote signal, it moves the mandrel 230 downhole and the fluid in the fluid chamber 306 communicates this movement to the actuator sleeve 210, via the piston 302. Particularly, the mandrel 230 applies a compressive force to the fluid. The fluid is hydraulically locked in the chamber 206, and thus transmits this force to the piston 302. The fluid force on the piston 302 moves the piston 302 downhole to its actuated position.
With the actuator assembly 220 in the unactuated state and the actuator sleeve 210 shifted to the left to render the valve closure 204 closed, a downhole end 312 of the piston 302 is adjacent, and in certain instances abutting, an uphole facing push shoulder 310 on the outer diameter of the actuator sleeve 210. Thus, when the piston 302 is shifted downhole from its unactuated position to its actuated position, it engages the shoulder 310 and drives the actuator sleeve 210 to the right, opening the valve closure 204. However, with the actuator assembly 220 in the unactuated state, the actuator sleeve 210 can he manually shifted to the right, for example with a shifting tool, to open the valve closure 204. Thus, prior to actuating the actuator assembly 220 in response to a remote signal, the actuator sleeve 210 can be shifted left and right to close and open the valve closure 204 once or multiple times as needed.
Notably, the coupling assembly described above uses few moving parts, instead relying on the concept of hydraulic lock to couple the actuator assembly 220 to the actuator sleeve 210, and thus valve closure 204 or other actuated element. In certain instances, a coupling assembly that operates based on hydraulic lock can be much stronger in a compact space than, for example, a coupling relying on a spring snap ring or frangible connection (e.g., shear pin). The fluid of the hydraulic lock tends to damp impact loading on the coupling experienced when the spring 222 is initially released, and thus reduces the loads the coupling need accommodate. In certain instances, the configuration of the coupling assembly allows the actuator sleeve 210 to be manually manipulated, for example with a shifting tool, once or multiple times as needed both before and after remote actuation of the actuator assembly 220.
A number of examples have been described. Nevertheless, it will be understood that various modifications may be made. Accordingly, other examples are within the scope of the following claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US2013/046884 | 6/20/2013 | WO | 00 |