Patent Grant
7246668
1. Field of the Invention
Embodiments of the present invention are generally related to safety valves. More particularly, embodiments of the present invention pertain to subsurface safety valves configured to be actuated using wellbore pressure in the event of an unexpected pressure drop.
2. Description of the Related Art
Subsurface safety valves are commonly used to shut-in oil and gas wells and are typically fitted in a string of production tubing installed in a hydrocarbon producing well. The safety valves are configured to selectively seal fluid flow through the production tubing to control the flow of formation fluids upwardly should a failure or hazardous condition occur at the well surface.
Typically, subsurface safety valves are rigidly connected to the production tubing and may be installed and retrieved by conveyance means, such as tubing or wireline. During normal production, safety valves are maintained in an open position by the application of hydraulic fluid pressure transmitted to an actuating mechanism. The actuating mechanism in such embodiments may be charged by application of hydraulic pressure through hydraulic control systems. The hydraulic control systems may comprise a clean oil supplied from a surface fluid reservoir through a control line. A pump at the surface delivers regulated hydraulic fluid under pressure from the surface to the actuating mechanism through the control line. The control line resides within the annular region between the production tubing and the surrounding well casing.
In the event of a failure or hazardous condition at the well surface, fluid communication between the surface reservoir and the control line is interrupted. This, in turn, breaks the application of hydraulic pressure against the actuating mechanism. The actuating mechanism recedes within the valve, allowing a flapper to quickly and forcefully close against a corresponding annular seat—resulting in shutoff of the flow of production fluid. In many cases, the flapper can be reopened (and production flow resumed) by restoring the hydraulic fluid pressure to the actuating mechanism of the safety valve via the control lines.
For safety reasons, most surface controlled subsurface safety valves (such as the ones described above) are “normally closed” valves, i.e., the valves are in the closed position when the hydraulic pressure in the control lines is not present. The hydraulic pressure typically works against a powerful spring and/or gas charge acting through a piston. In many commercially available valve systems, the power spring is overcome by hydraulic pressure acting against the piston, producing axial movement of the piston. The piston, in turn, acts against an elongated “flow tube.” In this manner, the actuating mechanism is a hydraulically actuated and axially movable piston that acts against the flow tube to move it downward within the tubing and across the flapper.
Safety valves employing control lines, as described above, have been implemented successfully for standard depth wells with reservoir pressures that are less than 15,000 psi. However, wells are being drilled deeper, and the operating pressures are increasing correspondingly. For instance, formation pressures within wells developed in some new reservoirs are approaching 30,000 psi. In such downhole environments, conventional safety valves utilizing control lines are not operable because of the effects of hydrostatic pressure on the hydraulic fluid within the control line. In other words, high-pressure wells have exceeded the capability of many existing control systems, especially hydraulic control systems which rely on control lines, which are susceptible to reliability problems.
Therefore, a need exists for a subsurface safety valve that is suitable for use in high pressure environments. There is a further need for a subsurface safety valve that does not rely on a control system that requires the use of control lines conveying hydraulic fluid to an actuating mechanism. There is yet a further need for the ability to reopen the safety valve remotely from the surface of the well.
In one respect, the present invention provides a downhole valve for selectively sealing a bore. The downhole valve generally includes a closing member for seating in and closing the bore, and a pressure-actuated, retention member having first and second opposed piston surfaces for initially holding the valve in an open position but, in the event of a pressure differential between the piston surfaces, permits the closing member to operate and close the valve.
In another respect, the present invention provides a method of operating a downhole valve. The method generally includes providing the valve in a down hole tubular, the valve having a closing member and an axially movable retention member having a first piston surface and an opposing piston surface and an interfering member to interfere with the closing member and keep the valve in the open position. A sudden pressure drop in the wellbore, shifts the retention member due to a pressure differential between the first and second piston surfaces, and closing the valve due to the axial movement of the interfering member way from the closing member.
In yet another respect, the present invention provides a safety valve for use downhole. The safety valve generally includes a pivotly mounted flapper, biased towards a closed position for sealing a bore, an interfering member to hold the flapper in an open position, a first piston surface in fluid contact with the bore, a second opposing piston surface in fluid communication with a pressure chamber having restricted fluid communication with the bore, wherein the valve is constructed and arranged to close in the event of a pressure difference between the bore and the chamber.
So that the manner in which the above recited features of the present invention can be understood in detail, a more particular description of the invention, 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 typical embodiments of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments.
The apparatus and methods of the present invention allow for a subsurface safety valve for use in high pressure wells. Embodiments of the present invention provide safety valves that utilize normal wellbore pressure for actuation of the valve, which removes the need for hydraulic systems with control lines extending from the surface to the valve.
It should be understood, that as used herein, the term “production fluid” may represent both gases or liquids or a combination thereof. Those skilled in the art will recognize that production fluid is a generic term used in a number of contexts, but most commonly used to describe any fluid produced from a wellbore that is not a servicing (e.g., treatment) fluid. The characteristics and phase composition of a produced fluid vary and use of the term often implies an inexact or unknown composition.
The safety valve 200 comprises a flapper 203 and a flow tube 204. The flapper 203 is rotationally attached by a pin 203B to a flapper mount 203C. The flapper 203 pivots between an open position and a closed position in response to axial movement of the flow tube 204. As shown in
As stated earlier,
While production fluid is being conveyed to the surface under stable and controlled conditions, the safety valve 200 remains in the open position. Under such conditions, the flow tube 204 remains bottomed out against an upward facing internal shoulder 230 of the bottom sub 202, thereby restricting the flapper 203 from closing. The flow tube 204 is held in this position due to a net downward force resulting from the force exerted by a spring 211 biased towards the extended position. A gap 231 between the inner diameter of the upper mandrel 201A and the outer diameter of the flow tube 204 allows piston surface 209 to be in fluid communication with the wellbore.
As shown in
During normal operation, while the valve 200 is in the open position, the pressure chamber 205 is filled with production fluid that enters the pressure chamber 205 through an orifice 208. In this embodiment, the orifice 208 is the only path for fluid to enter and exit the pressure chamber 205. The orifice is designed to meter flow that passes through it, regardless of whether the fluid is entering or exiting the pressure chamber 205. While the valve 200 is in the open position, the fluid flow through the orifice ensures that the pressure of the fluid inside the chamber is equalized with the pressure of the fluid flowing through the bore of the flow tube 204.
As shown in
The pressure difference between the fluid within the pressure chamber 205 and the production fluid results in the pressure chamber 205 increasing in volume and the flow tube 204 being urged upward. It should be noted that as the flow tube 204 moves upward, it meets resistance as the spring 211 is compressed. Provided that the pressure difference is large enough and the pressure chamber 205 expands sufficiently, the flow tube 204 travels sufficiently upward so that it no longer restricts the flapper 203 from closing and shutting-in the well as seen in
After the flapper is closed, the pressure of the production fluid acting on the underside of the flapper 203 (pushing upward) is high enough to forceably keep the flapper 203 in the closed position. In terms of the pressure chamber 205, it should be noted that starting from the instant of the rapid pressure loss (corresponding to the loss of flow control) the metered flow of fluid through the orifice allows for the pressure equalization process to resume. However, even after the pressure equalizes again, the pressure of the downhole fluid against the bottom-side of the flapper will keep it shut.
Embodiments of the present invention also provide functionality to remotely reopen the subsurface safety valve 200. Obviously, this would be done after flow control apparatus at the surface of the wellbore are returned to working order. In order to reopen the safety valve 200 from the surface, fluid is pumped down to the safety valve 200 and the pressure is built up so that the pressure above the flapper 203 is the same as the pressure of the production fluid below the flapper 203 (i.e., pressure is equalized across the flapper 203).
It should be noted that by this time, the flow of fluid through the orifice 208 has allowed pressure of fluid within the pressure chamber 205 to again equalize with the pressure of fluid outside the pressure chamber 205. The spring 211 stays compressed, and the pressure chamber 205 does not return to it's previous volume because the flow tube 204 is not allowed to move downwards due to the closed flapper.
However, once there is equal pressure on both sides of the flapper 203, the spring 211, biased towards the extended position, will urge the flow tube 204 downwards, which in turn will push the flapper to the open position. Thereafter, the flow tube will bottom out against a corresponding interior shoulder of the bottom sub 202.
With reference to the discussion above, it can be understood that the amount of upward movement of the flow tube 204 is dependent on the difference in pressure (i.e., “pressure drop”) between the fluid in the pressure chamber 205 and the pressure of the fluid flowing through the bore of the flow tube 204 at the moment of loss of flow control. In other words, the higher the difference in pressure between the fluid in the pressure chamber and the fluid flowing through the bore of the flow tube 204, the greater the amount of upward movement of the flow tube 204. Maximizing upward movement of the flow tube 204 is important because it ensures that the flow tube does not restrict the flapper 203 from fully closing in the event of a loss of flow control.
Other embodiments of the present invention are envisioned for providing more upward movement of the flow tube for a given pressure drop.
Referring now to
As with the embodiment described earlier, safety valve 300 comprises a flapper 303 and a flow tube 304. The flapper 303 is rotationally attached by a pin 303B to a flapper mount 303C. The flapper 303 pivots between an open position and a closed position in response to axial movement of the flow tube 304. As shown in
An important component of this embodiment is the use of bellows 306 for creating an expandable pressure chamber 305. The bellows 306 may be made of a variety of materials, including, but not limited to metals. For one embodiment, the bellows 306 are configured with pleated metal to facilitate a volumetric variance between its compressed and uncompressed positions.
The pressure chamber 305 is defined by the annular space between the bellows 306 and the flow tube 304. The pressure chamber 305 is bound on the top by the connection between the bellows 305 and the bellows retainer 307. The lower end of the pressure chamber 305 is bound by a cap 320. There are two channels by which production fluid can enter the pressure chamber 305: fluid can go past a packing 309, or fluid can flow into the pressure chamber 305 via an orifice 308. While the valve 300 is in the open position, the fluid flow through the orifice 308 and the packing 309 ensures that the pressure of the fluid inside the pressure chamber 305 is equalized with the pressure of the fluid flowing through the bore of the flow tube 304.
In the context of the current application, the packing 309 can be thought of as a one-way valve. As seen in
A pressure equalization port 321 extending through the cap 320 is provided to ensure that the pressure on either side of the cap 320 is equalized. Further, the port 321 provides a secondary path for production fluid to reach the packing 309 in the event that the path formed around the bottom end of the flow tube 304 and through the area adjacent to the flapper 303 is plugged.
The safety valve 300 comprises a spring 311 that resists the upward movement of the bellows retainer 307 and the flow tube 304. The bottom of the spring 311 rests against the bellows retainer 307. The top portion of the spring 311 interfaces with a downward-facing internal shoulder of the housing 301. In the open position of the safety valve 300, with the flow tube 304 bottomed out, the spring 311 is fully extended. In the closed position of the safety valve 300, with the flow tube 304 all the way up, the spring 311 is compressed and it exerts a downward force against the bellows retainer 307.
In the event of a loss of flow control at the surface of the wellbore, there would be a pressure drop between the fluid flowing through the bore of the flow tube 304 and the fluid in the pressure chamber 305. As with the previous embodiment, the pressure in the pressure chamber 305 is not reduced in concert with the pressure of the production flow because the metering effect of the orifice 308 does not allow the fluid to flow out of the pressure chamber 305 to allow for pressure equalization to occur immediately. As a result, the pressure chamber 305 expands by extending the bellows 306 axially, which, in turn, urges the bellows retainer 307 and flow tube 304 to move upward, compressing the spring 311. Upon sufficient upward movement of the flow tube 304, the flapper 303 will close to shut-in the wellbore.
As with the embodiment described earlier with reference to
Referring now to
The lower end 422 of the crossover sub 402 seals into the lower housing 403 at position 422. It should be understood that because the lower end 422 of the crossover sub 402 is sealingly connected (e.g., press fit, static seal, etc.) to the lower housing 404, production fluid is not able to flow past the seal between the lower end 422 of the crossover Sub 402 and the lower housing 404. However, the lower end 422 of the crossover sub 402 does contain an orifice 408 that allows fluid to flow into and out of a pressure chamber 405. Fluid arrives at the orifice 408 by flowing around the top or bottom of the flow tube 404 and within the annular space between the lower end 422 of the crossover sub 402 and flow tube 404.
Referring now to
The lower end 422 of the crossover sub 402 seals into the lower housing 403 at position 422. It should be understood that because the lower end 422 of the crossover sub 402 is sealingly connected (e.g., press fit, static seal, etc.) to the lower housing 403, production fluid is not able to flow past the seal between the lower end 422 of the crossover Sub 402 and the lower housing 403. However, the lower end 422 of the crossover sub 402 does contain an orifice 408 that allows fluid to flow into and out of a pressure chamber 405. Fluid arrives at the orifice 408 by flowing around the top or bottom of the flow tube 404 and within the annular space between the lower end 422 of the crossover sub 402 and flow tube 404.
In the event of a sudden pressure drop, the fluid is not capable of immediately exiting the pressure chamber via the orifice 408 (for purposes of pressure equalization), so the pressure in pressure chamber 405 is higher than the pressure of the flowing production fluid. Consequently, the pressure chamber 405 expands and displaces the rods 421 upward from the cylinders. The rods 420 move the flow tube 404 upward against the spring 411. After the flow tube 404 has moved sufficiently upward, the flapper 403 closes and shuts-in the well.
It can be seen from
Those skilled in the art will recognize that safety valves according to embodiments of the present invention may be utilized in any wellbore implementation where a pressure differential (i.e. pressure drop) may arise. For instance, the safety valves described herein are fully functional if there is a pressure differential between fluid in the pressure chamber and fluid flowing through the bore of the safety valve, regardless of the absolute pressures of the respective fluids. Therefore, safety valves according to embodiments of the present invention may be utilized in low pressure wellbores as well as high pressure wellbores.
While the exemplary safety valves described herein are configured for use with production tubing, those skilled in the art will acknowledge that embodiments of the present invention may be configured for use in a variety of wellbore implementations. For example, some embodiments of the present invention may be implemented as safety valves configured for use with wireline. Yet other embodiments may be configured for use with drill pipe or coiled tubing.
While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention 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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| Number | Date | Country | |
|---|---|---|---|
| 20060070744 A1 | Apr 2006 | US |
