In the drilling and completion industry, the formation of boreholes for the purpose of production or injection of fluid is common. The boreholes are used for exploration or extraction of natural resources such as hydrocarbons, oil, gas, water, and alternatively for CO2 sequestration. A production tubing string is typically run thousands of feet into a well bore. Generally, when running a tubing string downhole, it is desirable, and in some cases required, to include a safety valve on the tubing string. The safety valve typically has a fail safe design whereby the valve will automatically close to prevent production from flowing through the tubing, should, for example, the surface production equipment be damaged or malfunction.
Should the safety valve become inoperable, the safety valve may be retrieved to surface by removing the tubing string, as described hereinafter. The tubing retrievable surface controlled subsurface safety valve (“TRSV”) is attachable to production tubing string and includes a flapper pivotally mountable on the lower end of the safety valve assembly by a flapper pin. A torsion spring is provided to bias the flapper in the closed position to prevent fluid flow through the tubing string. When fully closed the flapper seals off the inner diameter of the safety valve assembly preventing fluid flow therethrough. A flow tube is provided above the flapper to open and close the flapper. The flow tube is adapted to be movable axially within the safety valve assembly. When the flapper is closed, the flow tube is in its uppermost position; when the flow tube is in its lowermost position, the lower end of the flow tube operates to extend through and pivotally open the flapper. When the flow tube is in its lowermost position and the flapper is open, fluid communication through the safety valve assembly is allowed. A rod piston contacts the flow tube to move the flow tube. The rod piston is located in a hydraulic piston chamber within the TRSV. The upper end of the chamber is in fluid communication, via a control line, with a hydraulic fluid source and pump at the surface. Seals are provided such that when sufficient control fluid (e.g. hydraulic fluid) pressure is supplied from surface, the rod piston moves downwardly in the chamber, thus forcing the flow tube downwardly through the flapper to open the valve. When the control fluid pressure is removed, the rod piston and flow tube move upwardly allowing the biasing spring to move the flapper and thus the valve, to the closed position.
If the TRSV becomes inoperable or malfunctions due to the buildup of materials such as paraffin, fines, and the like on the components downhole, e.g., such that the flapper does not fully close or does not fully open, it is known to replace the TRSV by retrieving the safety valve assembly to surface by pulling the entire tubing string from the well and replacing the safety valve assembly with a new assembly, and then rerunning the safety valve and the tubing string back into the well. Because of the length of time and expense required for such a procedure, it is known to run a replacement safety valve downhole within the TRSV. These replacement safety valves are run downhole via a wireline, and thus often referred to as wireline insertable safety valves (“WISV”). Before inserting the WISV into the TRSV assembly, however, two operations are performed. First, the TRSV is locked in its open position (i.e., the flapper must be maintained in the open position); and second, fluid communication is established from the existing control fluid line to the interior of the TRSV, thus providing control fluid (e.g. hydraulic fluid) to the WISV. Lockout tools perform the former function; communication tools perform the latter. When it is desired to lock the safety valve assembly in its open position, the lockout tool is lowered through the tubing string and into the TRSV. The lockout tool is then actuated to lock the valve mechanism (e.g. the flapper) of the TRSV in the open position.
Before inserting the WISV, communication is established between the hydraulic chamber of the TRSV and the internal diameter of the TRSV. The communication tool is utilized to provide fluid communication between the inner diameter of the TRSV and the hydraulic chamber, so that the hydraulic control line from surface can be utilized to operate the WISV. Once communication has been established with the hydraulic chamber, the WISV is run downhole. The WISV may resemble a miniature version of the TRSV assembly. The WISV is placed within the inner diameter of the TRSV assembly. The WISV includes an upper seal above the communication flow passageway and a lower seal below the flapper and at a bottom sub, and the control line to the TRSV is used to actuate the valve mechanism of the WISV. More specifically, the upper and lower seals allow control fluid from the control line to communicate with the hydraulic chamber and piston of the WISV in order to actuate the valve of the WISV between the open and closed positions. Once the WISV is in place, the wireline is removed and the tubing string placed on production.
The art would be receptive to more robust downhole systems incorporating TRSV and WISV, and improved methods for operating downhole in varying and extreme conditions experienced by such downhole systems.
A safety valve including at least one tubular housing having an interior surface, a flow path provided within an interior of the at least one tubular housing; a movable flow path blocking member arranged to block the flow path in a closed condition of the blocking member and open the flow path in an open condition of the blocking member; a first seal bore on the interior surface of the at least one tubular housing; a hydraulic control chamber within a wall of the at least one tubular housing; and, a second seal bore on the interior surface of the at least one tubular housing; wherein the hydraulic control chamber is disposed longitudinally between the first and second seal bores, and the second seal bore is disposed longitudinally between the hydraulic control chamber and the movable flow path blocking member.
A method of accommodating a high control pressure wireline insert safety valve within a tubing retrievable safety valve, the method including: sealing a first seal of the wireline insert safety valve within a first seal bore in the tubing retrievable safety valve; and sealing a second seal of the wireline insert safety valve within a second seal bore in the tubing retrievable safety valve; wherein the second seal bore is disposed between the first seal bore and a movable flow path blocking member of the tubing retrievable safety valve.
Referring now to the drawings wherein like elements are numbered alike in the several Figures:
As shown in
The housing units 14 of the housing 12 include a nipple adaptor 22 having a relatively thick tubular wall 24, an interior surface 26 of which includes a lock profile 28 and the first seal bore 16 for accessory tools. One such accessory tool is a wireline insert safety valve (“WISV”) 30, an exemplary embodiment of which is shown in
The housing 12 further includes a control housing 32, an uphole portion of which is attached to a downhole portion of the nipple adapter 22. The control housing 32 includes a hydraulic communication port 34 for conveying hydraulic control pressure from the wellhead or other remote location or chamber to the TRSV 10. The hydraulic communication port 34 may be attached to a hydraulic control line (not shown). The control housing 32 further includes a control chamber 36, which may be annular or otherwise, and may also be external to the valve. An extended control housing 38 attached to the control housing 32 further incudes a piston bore 40 to hold a control piston 42 which actuates a flow tube 44. The piston 42 may alternatively be integral with the flow tube 44. The extended control housing 38 further includes the second seal bore 18 on an interior surface 46 of the extended control housing 38. The second seal bore 18 may be positioned radially inward of the piston bore 40. More particularly, the second seal bore 18 may be positioned radially inward of an uphole portion of the piston bore 40 such that a cross-section taken perpendicular to a longitudinal axis 48 (
Additional housing units 14 in the housing 12 of the TRSV 10 include, but are not limited to, a housing 66 covering a power spring 68 and a housing 70 covering a movable flow path blocking member 72, such as a flapper 74. While the movable flow path blocking member 72 of the TRSV 10 is illustrated as a flapper-type safety valve, alternatively a ball-seat type of valve, or other types of valves may be incorporated in the TRSV 10. The movable operating components including the piston 42 and power spring 68 may be replaced by other or additional components to operate the movable flow path blocking member 72.
The housing 12 of the TRSV 10 also includes a bottom sub 76, which contains the third seal bore 20 along an interior surface 78 of the tubular bottom sub 76. The third seal bore 20 may be referred to herein as a lower seal bore of the TRSV 10. This lower or third seal bore 20, in conjunction with the upper or first seal bore 16, provide the seal bores 16, 20 for sealing therein a separation sleeve 92 (shown for illustrative purposes in
For purposes of manufacturing and assembly, the nipple adapter 22, control housing 32, extended control housing 38, housing 66 covering the power spring 68, housing 70 covering the flapper 74, and bottom sub 76 are separate housing units 14 combinable to form the housing 12, however any two or more adjacent combinations of the above housing units 14 may alternatively be integrally combined. It should further be understood that each housing unit 14 connects to an adjacent uphole and downhole housing unit 14 via suitable connectors and/or connection features, such as, but not limited to, nested fittings, set screws, welds, screw threads, etc. Each housing unit 14 is tubular in shape surrounding the longitudinal axis 48 of the TRSV 10 such that the interior 52 of the housing 12 of the TRSV 10 provides the flow path 15 for extraction of natural resources or injection of fluids.
A surface-controlled subsurface safety valve (“SCSSV”) (wireline WISV 30 or tubing retrievable TRSV 10) must be able to fail into the closed position; that is to say, the power spring 68 must be able to lift the flow tube 44 (and any other moving parts) against the hydrostatic force of the hydraulic control fluid from the surface. Therefore, a SCSSV must be able to tolerate a control pressure strong enough to not only overcome the force of the tubing pressure (pressure within the WISV 30 or TRSV 10) against the bottom of the control piston, such as piston 42 of TRSV 10, but must also be able to compress the power spring, such as power spring 68 of TRSV 10. Due to these strong forces against the deflection of piston, the necessary hydraulic control pressure of a SCSSV is higher than the tubing pressure caused by the well. For deepset valves in high pressure wells, the internal pressure caused by this hydraulic control pressure acting upon thin housing sections, such as thin sections 80, 82 of the power spring housing 66 and flapper housing 70, can be a limiting design factor as to whether the TRSV can accommodate a WISV. At a certain point, a WISV cannot be accommodated that can operate with the control pressure limitation imposed by the burst rating of the spring and flapper housings 66, 70. That is, there are design limitations imposed upon the WISV 30 due to the imposed limit on hydraulic control pressure that TRSV housings can be exposed to.
Since a typical WISV interfaces with the TRSV 10 in such a manner that turns substantially the entire interior 52 of the TRSV 10 into a control chamber for the WISV, from the first seal bore 16 to the third seal bore 20, thin sections 80, 82 in the housings 66, 70 must be designed to accommodate not only tubing pressure, but also control chamber pressure. Normal SCSSV design ends up rating WISV 30 to lower control chamber ratings than the TRSV's control chamber is capable of withstanding, while designing housings to a pressure intermediate to well pressure and TRSV control chamber pressure. This balancing act works at setting depths of up to 4,000 or 5,000 feet, but for TRSV 10 set deeper than that, serious design trade-offs start to occur in order to keep the TRSV 10 compatible with a WISV 30 that can overcome tubing pressure.
Thus, the exemplary TRSV 10 disclosed herein incorporates the second seal bore 18 just downhole of the control chamber communication area 54, so that the WISV 30 can seal into the thick housing 12 at that point. In particular, the wall 11 of the housing 12 at the second seal bore 18 includes a wall thickness of at least the extended control housing 38, and may additionally include a wall thickness of the control housing 32. In either case, since this area of the housing 12 is already designed to accommodate hydraulic control pressure, having the second seal bore 18 positioned at this area limits the control chamber of the WISV 30 to the area between the first and second seals 56, 58. This removes the thin sections 80, 82 of housings 66, 70 from the volume exposed to hydraulic control pressure for the WISV 30. That is, the second seal bore 18 in the extended control housing 38 limits the TRSV involvement with the WISV control chamber to the nipple adapter 22 and the control housings 32, 38. Since the nipple adapter 22 is thick, it is better able to withstand elevated control chamber pressures, and the control housings 32, 38 are able to withstand full control chamber pressure by design. This will allow WISV 30 to accept higher operating pressures, and therefore stronger power springs. With a stronger power spring, the WISV 30 can be set in deeper wells. Additionally, this will remove a limiting load case from TRSV design.
An exemplary embodiment of the WISV 30 for use in the downhole system 100 shown in
A method of accommodating an ultra high control pressure WISV 30 in a TRSV 10 includes securing the movable flow path blocking member 72 in an open condition as shown in
While the invention has been described with reference to an exemplary embodiment or embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the claims. Also, in the drawings and the description, there have been disclosed exemplary embodiments of the invention and, although specific terms may have been employed, they are unless otherwise stated used in a generic and descriptive sense only and not for purposes of limitation, the scope of the invention therefore not being so limited. Moreover, the use of the terms first, second, etc. do not denote any order or importance, but rather the terms first, second, etc. are used to distinguish one element from another. Furthermore, the use of the terms a, an, etc. do not denote a limitation of quantity, but rather denote the presence of at least one of the referenced item.