The present disclosure generally relates to check valves used in connection with petroleum extraction operations and associated devices. More particularly, the disclosure relates to a dart-style reverse-flow check valve such as provided in gas lift valves utilized in an oil well downhole environment.
For purposes of communicating well fluid to a surface of a well, the well may include a production tubing. More specifically, the production tubing typically extends downhole into a wellbore of the well for purposes of communicating well fluid from one or more subterranean formations through a central passageway of the production tubing to the well's surface. Due to its weight, the column of well fluid that is present in the production tubing may suppress the rate at which the well fluid is produced from the formation. More specifically, the column of well fluid inside the production tubing exerts a hydrostatic pressure that increases with well depth. Thus, near a particular producing formation, the hydrostatic pressure may be significant enough to substantially slow down the rate at which the well fluid is produced from the formation.
For purposes of reducing the hydrostatic pressure and thus enhancing the rate at which fluid is produced, an artificial lift technique may be employed. One such technique involves injecting gas into the production tubing to displace some of the well fluid in the tubing with lighter gas. The displacement of the well fluid with the lighter gas reduces the hydrostatic pressure inside the production tubing and allows reservoir fluids to enter the wellbore at a higher flow rate. The gas to be injected into the production tubing typically is conveyed downhole via the annulus (the annular space surrounding the production tubing) and enters the production tubing through one or more gas lift valves.
As an example,
The gas lift valve 18 typically contains a check valve arrangement having a check valve element that opens to allow fluid flow from the annulus 15 into the production tubing 14 and closes when the fluid would otherwise flow in the opposite direction. Thus, when the pressure in the production tubing 14 exceeds the annulus pressure, the valve element is closed to ideally form a seal to prevent any reverse flow from the tubing 14 to the annulus 15. The prior art check valve arrangements are defined essentially by a single pair of sealing surfaces. One of the sealing surfaces belongs to a seat which is generally fixed in a housing or the like. The other sealing surface belongs to a valve element that is typically spring biased and moved back and forth in and out of engagement with the seat to close and open the check valve arrangement depending on a fluid pressure differential. The valve element could be a ball, a dart (or poppet), a flapper, a diaphragm, etc. In certain high temperature working conditions such as in an oil well environment, it is common to use dart-type check valve arrangements where substantially only metal-to-metal sealing elements are used. Metal-to-metal sealing is mainly dependent on conformity between sealing surfaces, surface finish, and contact stresses. Contact stresses are functions of applied pressure and contact area. The present inventors have found that a challenge can arise when a particular check valve arrangement is required to perform steadily at low back pressures and over a wide range of back pressures. If the contact area is too small once the valve is subject to high pressure, it is plastically or non-reversibly deformed. If the contact area is too large, the valve arrangement can experience low contact stresses at low pressure and thus will not seal.
The present inventors have recognized that the prior art does not adequately provide the desired sealing behavior for check valve arrangements defined by a single pair of sealing surfaces such as typically used in downhole well environments and subjected to widely varying pressure extremes in operation. Accordingly, the present disclosure relates to solutions generally addressing issues having to do with an effective sealing action within a wide range of applied back pressures, typically 100-10,000 pounds per square inch (psi) on check valve arrangements which prevent reverse flow of fluid such as from the tubing to the annulus in a well application. The check valve arrangement contemplated by the inventors provides multiple dedicated sealing surfaces designed to prevent non-reversible deformation and leakage regardless of the applied back pressures over wide operating ranges.
In one example, an apparatus usable with a well includes a gas lift valve having a check valve arrangement located between an annulus and a passageway of a tubing. The check valve is adapted to selectively allow a fluid flow through the check valve arrangement from an inlet side of the check valve arrangement to an outlet side of the check valve arrangement, and is biased to prevent a leakage flow from the check valve from the outlet side to the inlet side. The check valve arrangement is defined by a valve element movable into and out of engagement with a valve seat wherein one of the valve elements and the valve seat has a first sealing structure engageable with a second sealing structure on the other of the valve element and the valve seat. At least one of the first and second sealing structures include at least one pair of sealing members.
The check valve arrangement is adapted to establish one-way flow of gas from the annulus to the passageway of the tubing and responds to a pressure differential therebetween. The valve seat is commonly formed by internal structure of the gas lift valve and includes a high pressure seat portion and a low pressure seat portion. In certain embodiments, the valve element has a high pressure dart portion engageable with the high pressure seat portion, and a lower pressure dart portion engageable with the lower pressure seat portion. The high pressure seat portion and the low pressure seat portion may be stationary or may be movably mounted relative to one another. The low pressure dart portion and the high pressure dart portion may be integral or may be movable relative to one another.
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In the following description, certain terms have been used for brevity, clearance and understanding. No unnecessary limitations are to be implied therefrom beyond the requirement of prior art because such terms are used for descriptive purposes and are intended to be broadly construed. The different configurations and methods described herein may be used alone or in combination with other configurations, systems and methods. It is to be expected that various equivalents, alternatives and modifications are possible within the scope of the appended claims.
Referring now to the drawings,
In the examples to follow, unless otherwise noted, the check valve arrangement utilizes metallic sealing elements as generally dictated by high temperature working environments, such as downhole in an oil well.
a-3c show one example of check valve arrangement 26 having an outer compliant dart check mounted in a lower portion of the gas lift valve 24. The gas lift valve 24 has an inlet section 28 attached to a tubular housing 30 which, in turn, is connected on its bottom end to a downwardly tapering check valve housing 32. The inlet section 28 has a series of radial inlet ports 34 which receive fluid (gas) that flows from the annulus through a venturi passageway 36 formed in a venturi housing 38 that is sealed to the inlet section 28, such as by O-ring 40, and supported at the top of housing 30. The venturi passageway 36 minimizes turbulence in the flow of gas from the well annulus to the production tubing, and is in communication with a tubular lower passageway 42 that extends into the check valve housing 32. Gas that flows into the check valve housing 32 exits through longitudinally extending outlets 44 that are in communication with mandrel outlets so that gas may be delivered into the production tubing. The gas lift valve 24 includes a seal 46 that circumscribes the tubing housing 30 for the purpose of forming a sealed region that contains the radial inlet ports 34 and aligned inlet ports of the mandrel 20.
The check valve arrangement 26 includes an annular valve seat 48 formed by a lowermost end of the gas valve housing 30 with the seat being opened and closed for controlling the one-way flow through gas lift valve 24 via a spring biased check valve assembly 50. As more clearly seen in
A high pressure dart portion 68 is constructed with a stem 70 that is received and fixed in the recess 66 and has a domed portion 72 selectively engageable with the high pressure seat 52. As seen in
Spring 84 normally operates to exert an upward force on check valve assembly 50 to close off fluid communication through the valve seat 48 as shown in
When the gas flow into the gas lift valve 24 is reduced and eventually shut off, the spring 84 returns the check valve assembly 50 towards seat 48. As the casing or annulus pressure decreases, a pressure differential is created with a low back pressure initially acting on the valve assembly 50 and causing sealing surface 76 of low pressure dart portion 74 to seal against low pressure seat 54 as shown in
a-4c show another example of a check valve arrangement 26 having an inner rather than outer compliant dart valve mounted in the lower portion of gas lift valve 24. In this example, the check valve assembly 50 employs a low pressure dart portion 86 that is selectively engageable with a low pressure seat 88. A high pressure dart portion 90 is fixed by a weldment 92 to upper end 64 of dart body 56, and is selectively engageable with a high pressure seat 94. A wave spring 96 is interposed in a recess 98 between the dart body 56 and the low pressure dart portion 86, and provides a preloaded spring force on low pressure dart portion 86 which is mounted for limited movement relative to high pressure dart portion 90. Operation is similar to that of the example of
a-5c show a further example of a check valve arrangement 26 having an outer compliant seat check. Here, a fixed high pressure seat 100 is defined by a lowermost tip of gas lift valve housing 30. A groove 102 machined in the bottom end of the gas lift valve housing 30 is provided with an annular wave washer or spring 104 which normally exerts a downward biasing force on a movable annular low pressure seat 106 engageable with a retainer nut 108. The low pressure seat 106 is located outside the flow path defined by passageway 42. An upper end of dart body 56 has a low pressure dart portion 110 integrally formed with a high pressure dart portion 112. After opening of the check valve assembly 50 as seen in
a-6c show an additional example of a check valve arrangement 26 having an inner compliant seat check. In this example, a movable low pressure seat 114 provides an inner diameter at the bottom of passageway 42 in gas lift valve housing 30 which can be varied in size to enable greater flow of gas to a chamber 115 and the outlets 44 in the check valve housing 32. As contrasted with the low pressure seat 106 of
a-7c show yet another example of a check valve arrangement 26 in which the valve seal structure has a fixed high pressure seat 126 defined by an inner surface at the bottom of tubular housing 30, and a movable low pressure seat 128 defined by a lowermost edge on an elongated portion 130 of venturi housing 38 forming passageway 42. O-rings 132, 134 are provided to seal gaps between the venturi housing 38 and the tubular housing 30. A spring 136 is interposed between respective shoulders on inlet housing 28 and venturi housing 38 to normally exert a downward biasing force on the venturi housing 38. Following opening of check valve housing 50 as shown in
a-8c show still another example of a check valve arrangement 26 similar to that described in
The present disclosure thus provides a gas lift valve having a check valve arrangement that involves the use of multiple dart and seat sealing surfaces to attain a desired sealing behavior over a wide range of applied back pressures without leakage or deformation. One of the dart and/or seat sealing surfaces is preloaded by a spring or other suitable elastic element. Below a predetermined low pressure, a spring loaded pair of sealing surfaces will be in small area contact. Beyond that predetermined low pressure, a second pair of sealing surfaces will come into a large area contact. The first pair of sealing surfaces will remain at all times under low level contact stresses and will not deform plastically. Although certain examples shown herein have two pairs of sealing surfaces, i.e. low pressure and high pressure darts and seats, it should be understood that the disclosure contemplates the use of more than two pairs of sealing surfaces as dictated by specific application and element size.
This application relates to and claims priority from U.S. Provisional Application Ser. No. 61/187,680, filed Jun. 17, 2009, which is fully incorporated herein by reference.
Number | Name | Date | Kind |
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3489170 | Leman | Jan 1970 | A |
4111608 | Elliott et al. | Sep 1978 | A |
4624316 | Baldridge et al. | Nov 1986 | A |
4951707 | Johnson | Aug 1990 | A |
5193577 | de Koning | Mar 1993 | A |
5707214 | Schmidt | Jan 1998 | A |
20090044948 | Avant et al. | Feb 2009 | A1 |
Number | Date | Country | |
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20100319924 A1 | Dec 2010 | US |
Number | Date | Country | |
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61187680 | Jun 2009 | US |