The present invention relates generally to valves utilized in subterranean wells and, in an embodiment described herein, more particularly provides a safety valve having an extension spring closure mechanism.
It is desirable for a valve utilized in a subterranean well to have a relatively thin wall thickness. This permits a larger diameter flow passage to be formed through the valve and/or permits the valve to be installed in a smaller diameter wellbore.
Most conventional safety valves use a torsion spring to bias a closure member toward a closed position relative to the flow passage. An example of a torsion spring biased closure member in a safety valve is found in U.S. Pat. No. 6,196,261, the entire disclosure of which is incorporated herein by this reference.
However, when faced with the task of reducing a safety valve's wall thickness, torsion spring closure mechanisms present several problems. For example, a torsion spring rapidly relaxes, that is, much less biasing force is produced by the torsion spring, as the closure member pivots toward the closed position. In addition, only limited space is available in the reduced wall thickness for positioning the torsion spring relative to the closure member, and a sufficiently strong torsion spring is difficult to fit into this limited space.
One solution to this problem of limited space has been to use one or more compression springs to bias the closure member to the closed position. An example of a compression spring closure mechanism in a safety valve is found in U.S. Pat. No. 6,227,299, the entire disclosure of which is incorporated herein by this reference.
However, the use of compression springs still has the disadvantage of the springs relaxing as the closure member displaces toward the closed position. In addition, the provision of the compression springs in the safety valve requires the length of the safety valve to increase, thereby increasing the cost of the safety valve. Furthermore, the compression spring mechanism requires a number of additional parts be provided in the safety valve.
From the foregoing, it can be seen that it would be quite desirable to provide an improved closure mechanism for valves, including safety valves and other types of valves, utilized in subterranean wells.
In carrying out the principles of the present invention, in accordance with an embodiment thereof, a valve for use in a subterranean well is provided which includes an extension spring closure mechanism.
In one aspect of the invention, a valve for use in a subterranean well is provided which includes a biasing device and a closure member having open and closed positions. The biasing device has a length which decreases as the closure member displaces toward the closed position.
In another aspect of the invention, a safety valve is provided. The safety valve includes a closure member having open and closed positions and at least one extension spring biasing the closure member toward the closed position.
In a further aspect of the invention, a safety valve is provided which includes a closure member having open and closed positions, a biasing device for biasing the closure member toward the closed position and a beam interconnected between the biasing device and the closure member. The beam is flexed to an increasingly curved configuration, thereby increasingly biasing the closure member toward the closed position, as the closure member displaces toward the open position.
In yet another aspect of the invention, a safety valve is provided which includes a closure member having open and closed positions and a biasing device for biasing the closure member toward the closed position. The biasing device is flexed to an increasingly curved configuration, thereby increasingly biasing the closure member toward the closed position, as the closure member displaces toward the open position.
These and other features, advantages, benefits and objects of the present invention will become apparent to one of ordinary skill in the art upon careful consideration of the detailed description of representative embodiments of the invention hereinbelow and the accompanying drawings.
Representatively illustrated in
Only a portion of the safety valve 10 is depicted in
The safety valve 10 illustrated in
As depicted in
A biasing device or extension spring 20 is used to bias the flapper 16 toward its closed position. As used herein, the term “extension spring” indicates a spring which exerts an increased biasing force as its length is increased or extended. Conversely, the biasing force exerted by an extension spring decreases as its length decreases.
The spring 20 is secured at its upper end to the seat 18, and is secured at its lower end to a beam 22. The beam 22 is pivotably connected at its upper end to the flapper 16.
Although only one spring 20 is visible in
Note that, in the closed configuration of the safety valve 10 depicted in
However, the biasing force applied by the spring 20 to the flapper 16 via the beam 22 decreases as the flapper pivots toward the closed position, because the spring decreases in length. The torque or moment (biasing force X moment arm) applied to the flapper 16 about the pivot 28 may remain substantially constant, or it may actually increase, as the flapper pivots toward the closed position. For example, the increase in the moment arm M length may offset the decrease in the biasing force exerted by the spring 20.
In
In
Note that a raised projection 34 formed on the flapper 16 contacts the beam 22 and the spring 20 as the flapper pivots to the open position shown in
This flexing of the beam 22 and spring 20 applies additional biasing force to the flapper 16 at the projection 34. This additional biasing force is useful to initiate pivoting of the flapper 16 toward its closed position from its open position. The additional biasing force is present as long as the projection 34 contacts and deflects the beam 22 and/or spring 20.
It is contemplated that, even if the spring 20 were to fail, the biasing force produced by flexing the beam 22 could be sufficient to at least initially pivot the flapper 16 toward its closed position from its open position. Once initially pivoted toward its closed position, fluid flow through the passage 14 would act to pivot the flapper 16 completely to its closed position and, once closed, a pressure differential across the flapper would maintain it closed to prevent accidental release of fluids from the well.
By positioning the projection 34 closer to the pivot 28, as depicted in
Referring additionally now to
As with the beam 22 described above, the beam 40 includes two lateral sides 44 joined to a central portion 46. When used in the safety valve 10, one or more of the spring(s) 20 is/are attached to the central portion 46 via an opening 47 (similar to the opening 26 described above), and the beam sides 44 are pivotably connected to the flapper 16 using laterally extending pegs 48. Thus, the biasing force exerted by the spring(s) 20 is transmitted from the central portion 46 to the pegs 48 via the beam sides 44, and thence to the flapper 16.
To attach the beam 40 to the flapper 16, the sides 44 are squeezed together to decrease the relative distance between the pegs 48. A pair of stops 49 are formed inwardly of the pegs 48 to limit the inward displacement of the sides 44. This prevents overstressing of sides 44 at the central portion 46.
When the flapper 16 pivots to the open position (as depicted in
Note that the sides 44 and the appendages 42 diverge away from each other at bends or elbows 45. When the flapper 16 is opened, the sides 44 are flexed toward the appendages 42. Eventually, the bends or elbows 45 of the respective sides 44 and appendages 42 will contact each other. This contact limits further flexing of the sides 44 and appendages 42 at the central portion 46, thereby preventing overstressing of the sides and appendages.
The beam 40 is depicted in
The appendages 42 of the beam 40 extend in a longitudinal direction relative to the sidewall 50 when the beam is used in the safety valve 10. The appendages 42 extend in the same longitudinal direction relative to the central portion 46 as do the sides 44. Thus, the beam 40 may be described as being “folded over” at the central portion 46.
This “folded over” design of the beam 40 provides a biasing force to close the flapper 16 over a substantial portion of its pivoting displacement. It is contemplated that the beam 40 could be used to close the flapper 16, even without use of the separate spring(s) 20.
Representatively illustrated in
Referring additionally now to
As the flapper 16 pivots to its open position, the spring 68 will eventually contact the sidewall 50. Further pivoting of the flapper 16 will compress the spring 68 between the flapper and the sidewall 50. This compression of the spring 68 will apply a biasing force to the flapper 16, biasing the flapper toward its closed position.
Similarly, as the flapper 16 pivots to its open position, the spring 70 will eventually contact the flapper. Further pivoting of the flapper 16 will flex or bend the spring 70. This flexing of the spring 70 will apply a biasing force to the flapper 16, biasing the flapper toward its closed position.
Thus, it will be readily appreciated by those skilled in the art that the springs 68, 70 and the appendages 42, 62 of the beams 40, 60 provide additional biasing forces for initiating pivoting displacement of the flapper 16 from its open position to its closed position.
Representatively illustrated in
A beam 72 is connected to a lower end of the spring 20 and extends downwardly therefrom to a central portion 74. From the central portion 74, the beam 72 extends upwardly to a pivoting connection with the flapper 16. Note that, as the flapper 16 pivots toward its open position, the beam 72 will be increasingly flexed or bent by its lateral compression between the flapper and the sidewall 50, thereby applying an additional biasing force to the flapper, the additional biasing force biasing the flapper toward its closed position.
Referring additionally now to
Each of the springs 76 would be connected to the beam 72 and would exert an upwardly directed biasing force on the beam. In this manner, an increased total biasing force (due to the increased number of springs 76) may be applied to the beam 72, and the springs may provide redundancy for each other in the event that one or more of the springs should fail. Another advantage may be that smaller springs 76 can be used (since there are more of the springs), thereby permitting the safety valve 10 to have a smaller outer diameter.
In
In
Referring additionally now to
As noted above, the spring 20 is bent or flexed by the flapper 16 when the flapper pivots to its open position. When the alternate configuration of
The beam 82 may be straight, or it may be bent or curved when the flapper 16 is in its closed position. When the flapper 16 is pivoted to its open position, the beam 82 may be straightened (if previously bent or curved), the beam may be bent (if initially straight), or further bent (if initially bent or curved).
Of course, a person skilled in the art would, upon a careful consideration of the above description of representative embodiments of the invention, readily appreciate that many modifications, additions, substitutions, deletions, and other changes may be made to these specific embodiments, and such changes are contemplated by the principles of the present invention. Accordingly, the foregoing detailed description is to be clearly understood as being given by way of illustration and example only, the spirit and scope of the present invention being limited solely by the appended claims and their equivalents.