None.
Not applicable.
Not applicable.
The present invention relates generally to equipment utilized, and operations performed, in conjunction with subterranean wells and, in embodiments described herein, more particularly to a two slip retrievable packer for extreme duty.
Conventional hydraulically set retrievable packers have three main components, at least one slip, packing elements and a setting cylinder all of which are assembled on a mandrel. Typical packers have a dual slip on top, packing elements in the middle and a setting cylinder on the bottom. This design works well in many typical well applications. However, the design has limitations on the loads it can bear. Upthrust on the mandrel due to pressure below the packer and/or applied upstrain on the tubing above sometimes cause excessive loads to be generated in the packing element. The packing element sustains two additive loads in this design. One load is the applied hydraulic pressure differential across the packer. This pressure is contained by the well casing and the element mandrel on which the packing elements ride. Any upthrust on the mandrel eventually terminates at the dual slip and into the casing. This second load must be transmitted through the packing elements to reach the slip. This mechanical load translates into additional element pressure, i.e. rubber pressure. This pressure is additive to the imposed hydraulic pressure.
For example, an extreme packer application may call for a packer to withstand 10,000 p.s.i. differential hydraulic pressure imposed from below, plus an additional tubing tension load, or upward pressure differential load on the mandrel, of 300,000 pounds. The mechanical load adds to the rubber pressure from the hydraulic pressure load. The rubber area exposed to the mechanical load is the difference in area of the casing internal diameter and the element mandrel outer diameter. In a typical case this area may be 25 square inches. For this area, a 300,000 pound load creates 12,000 p.s.i. rubber pressure, i.e. 300,000 divided by 25. This mechanically generated pressure load adds to the actual hydraulic pressure to produce a total pressure load on the packing elements of 22,000 p.s.i. The casing is subjected to this pressure as a burst load, and the mandrel is exposed to this pressure as a collapse load. In many cases, the well casing cannot be expected to sustain this pressure. If it does not have a solid cement sheath, it will fail.
In U.S. Pat. No. 6,112,811, a packer having two dual or double acting slips provided a solution to the problem of combined mechanical and hydraulic pressure loads on the packing elements. In that system, two dual slips were arranged so that one half of each dual slip resisted hydraulic pressure, up or down, applied to the packing elements and the other half of each dual slip resisted loads applied to the mandrel. The packing element was not exposed to a combination of the two types of loads. In that arrangement, the well casing is used as a tension member to store at least part of the setting force of the packer. This is a typical arrangement in two slip permanent packers also. However, in order for the packer to be retrievable, there must be some mechanism for effectively shortening the mandrel between the slips to release the tension in the well casing so that the dual slips can release from the casing. As reference to U.S. Pat. No. 6,112,811 shows, such releasing mechanisms require multiple releasing elements for releasing the setting force on the packing elements and for applying releasing forces to multiple wedges in order to actually release the two dual slips. Failure of one or more of the releasing elements to function properly may prevent retrieval of the packer or may require use of an explosive tubing cutter to sever the mandrel. It may be necessary to destroy the packer in order to remove it from the well.
It would be desirable to provide a packer which avoids excessive forces applied to packing elements, and which has a simplified releasing mechanism.
A packer according to the one embodiment includes one dual, or double acting, slip and a single acting slip positioned on a mandrel on opposite sides of a packing element and a setting cylinder. The single acting slip is designed to resist forces acting on the mandrel in one direction.
In one embodiment, setting forces are coupled to the mandrel through a release sleeve. When the release sleeve is decoupled from the mandrel, the setting forces on both slips and the packing element are released and the packer can be retrieved from a well. In a preferred form, the release sleeve may be decoupled from the mandrel by multiple triggering apparatus and methods.
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.
FIGS. 1A-G are successive axial portions of a cross-sectional view of a packer in its run configuration.
FIGS. 5A-E are successive axial portions of a cross-sectional view of the packer in a set configuration in a well and with one type of release trigger mechanism in place.
FIGS. 6A-E are successive axial portions of a cross-sectional view of the packer in its released configuration.
FIGS. 9A&B are cross-sectional views of axial portions of another embodiment of the packer.
Representatively illustrated in
The packer 10 is described herein as an example of a well tool which may be set and released in a well bore using the principles of the invention. The packer 10 is a well tool of the type which grips and seals against a well bore in which it is set. After being set in the well bore, the packer 10 may be released, or “unset”, thereby relieving its gripping and sealing engagement with the well bore so that it may be removed from the well bore. As used herein, the term “set” is used to refer to an operation producing a gripping and/or sealing engagement between a well tool and a well bore, and the term “release” is used to refer to an operation which relieves the gripping and/or sealing engagement between the well tool and the well bore.
The packer 10 is similar in many respects to a Model DHC dual string packer marketed by Halliburton Energy Services, Inc. and well known to those skilled in the art. For example, the packer 10 includes a mandrel 11 on which essentially all other elements are carried or assembled. Primary and secondary flow passages 12, 14 extend through mandrel 11. The primary flow passage 12 may, for example, be used for producing well fluids to the surface, and the secondary flow passage 14 may be used for gas injection. Carried on mandrel 11 are a dual slip 16, seal elements 18 and a setting cylinder assembly 20,
The packer 10 is also similar to the apparatus described in the above referenced U.S. Pat. No. 6,112,811, which includes two dual slips, one above its packing elements and one below. In addition to the dual slip 16 above seal elements 18, packer 10 includes a single acting slip 22 below the setting cylinder assembly 20. The embodiment described herein is for applications where the extreme loads are due to high pressures below the packer. Depending on the specific application, the slip positions may be reversed, that is the single acting slip may be at the upper end of the packer and the dual slip may be at the lower end of the packer.
A release ring 80,
The above described design of a packer according to the present invention resulted in part from a discovery concerning the most common loads experienced in extreme packer applications. As noted above, in extreme applications, the combination of direct hydraulic loads on the packer elements and the loads transferred through the mandrel to the packer elements may generate destructive loads to the elements themselves or to the well casing. U.S. Pat. No. 6,112,811 solved this problem by using two dual slips arranged to apply the direct hydraulic loads on the seal elements to one half of each dual slip and the mandrel forces to the other half of each dual slip. However, this design results in setting forces appearing as tension in the casing and this requires complicated release mechanisms which may fail. The present inventors have discovered that, in many extreme packer applications, the extreme mandrel forces occur in only one direction. Extreme single direction mandrel forces can be resisted by a single acting slip positioned to resist mandrel forces from the side opposite the dual slip. By using a single acting slip as the second slip in a two slip design, releasing apparatus may be very simple and very reliable.
The above described elements make up the primary components of the packer 10 according to an embodiment of the present invention. More details of the packer 10, its methods of operation and various release trigger mechanisms and methods are provided below. In
With reference to
Dual slip 16 in this embodiment is a circumferentially continuous axially slotted barrel slip of the type well know to those of ordinary skill in the art. However, it is to be clearly understood that the slip 16 may be differently configured without departing from the principles of the present invention. For example, the teeth 28 and 30 or other gripping structures may be separately attached to the remainder of the slip, the slip 16 may be C-shaped or otherwise circumferentially discontinuous, the slip 16 may be circumferentially divided into slip segments, the slip 16 may be formed of two single acting slips (circumferentially continuous, segmented, etc.) facing in opposite directions, etc.
A first wedge 32 is carried between the mandrel 11 and the upper portion of slip 16 and is held in position by an upper sub 33 so that it cannot move upward relative to the mandrel 11, although it is allowed to move downward a limited distance for unsetting the packer as discussed below. Slip 16 and wedge 32 have matching slanted surfaces 34 and 36 which cause the slip 16 to expand radially as it is moved upward relative to the wedge 32. A debris barrier 38 is preferably provided at the upper end of slip 16 to prevent debris, e.g. sand, from flowing between the slip 16 and the wedge 32, when the slip 16 is expanded radially.
A second wedge 40 is carried between the mandrel 11 and the lower end of slip 16 and extends below slip 16. Wedge 40 may slide to a limited extent in either direction relative to the mandrel 11. Slip 16 and wedge 40 have matching slanted surfaces 42 and 44 which cause the slip 16 to expand radially as the wedge 40 is moved upward relative to the slip 16. The wedge 40 is connected to, and slides with, a cover sleeve or upper element retainer 46, the lower end of which rests on the top of seal elements 18.
As shown in
With reference to
With reference to
Slip 22 in this embodiment is a circumferentially continuous axially slotted single acting barrel slip of the type well know to those of ordinary skill in the art. However, it is to be clearly understood that the slip 22 may be differently configured without departing from the principles of the present invention. For example, the teeth 70 or other gripping structures may be separately attached to the remainder of the slip, the slip 22 may be C-shaped or otherwise circumferentially discontinuous, the slip 22 may be circumferentially divided into slip segments, etc.
The elements described in detail above with reference to
Although the anchor ring 84 is described herein as being a means by which the release ring 80 is releasably retained against displacement relative to the mandrel 11, other retaining means may be used, if desired. For example, a supported collet, supported lugs or dogs, supported snap ring, etc.
With reference to
Although the piston 100 is described herein as being annular-shaped, it will be readily appreciated that other types of pistons could be used, such as a rod piston, etc.
The piston 100 is connected to the release mechanism 26 by a coupling 108. The coupling 108 includes a yoke 110 surrounding piston 100, a rod 112 having an enlarged end 114, and a tube 116. The rod 112 is telescopingly received in one end of the tube 116, and the other end of the tube 116 is attached to the clamp 98.
The yoke 110 is rigidly secured to the piston 100 and to the rod 112. Thus, the piston 100, yoke 110 and rod 112 displace, or remain stationary, as an assembly. In the bottom view of the packer 10 representatively illustrated in
The coupling 108 is of the type known as a slip or one-way coupling, in that the tube 116 (and the attached clamp 98) may displace downwardly relative to the rod 112, yoke 110, and piston 100 assembly, but when the rod 112, yoke 110, and piston 100 assembly displaces downwardly, the tube 116, and release clamp 98 assembly also displaces downwardly due to engagement of the enlarged rod end 114 with the lower end of the tube 116. This permits the clamp 98 to be displaced downwardly, thereby releasing the packer 10, without displacing the piston 100 downwardly. Various apparatus and methods are described below for moving the clamp 98 downward without moving the piston 100 downward. Thus, it is not necessary to displace the piston 100 downwardly to release the packer 10, but if the piston 100 is displaced downwardly, it will cause the clamp 98 to displace downwardly and release the packer 10.
As mentioned above, the upper and lower sides 102, 106 of the piston 100 are in fluid communication with the flow passage 12. In this embodiment of the invention, a pressure differential may be created in the flow passage 12, which pressure differential is communicated via the ports 104, 105 to the respective sides 102, 106 of the piston 100, to thereby bias the piston downward. Various apparatus and methods are described below for providing such a pressure differential. When this downwardly biasing force is sufficiently great, shear screws 118, which releasably secure the piston 100 in its run and set position, shear and the downwardly biasing force is transmitted via the coupling 108 to the clamp 98. When the downwardly biasing force transmitted to the clamp 98 is sufficiently great, shear pins 120, which releasably secure the clamp 98 in its run and set positions, shear and the clamp 98 displaces downward, along with the coupling 108 and piston 100, thereby releasing the packer 10, as explained in detail below with reference to
With reference to
In the packer 10, the flow passages 12, 14 are integrally formed in a single mandrel 11. In the top view of the packer 10 illustrated in
As the slip 22 is being deployed, force on lower element retainer 57 is applied to the seal elements 48, 50 and 52 and through them to the wedge 40 and slip 16. As shown in
The axial force on the seal elements 18 are also applied to the wedge 40 and slip 16. As the elements 18 move upward, the wedge 40 and slip 16 also move upward. The interaction of slip 16 with wedges 32 and 40 cause the slip 16 to expand radially into contact with the casing 124. The teeth 28 and 30 on the upper and lower portions of slip 16 bite into the casing 124 and resist axial movement of the slip 22 relative to the casing 124.
As the slips 16 and 22 and seal elements 18 are being set, the ratchet teeth between outer sleeve 58 and the inner sleeve 60 slip to allow the sleeve 58 to move upward and the inner sleeve 60 to move down. However, once the packer 10 has been set, the pressure may be removed from the space 64, because the ratchet teeth 66 prevent the outer sleeve 58 and the inner sleeve 60 from moving back to their run positions. The setting forces appear as compression forces in the seal element 18 and as tension force in the mandrel 11.
With further reference to
If the mandrel 11 should experience downward forces, they will be transferred through the wedge 32 to the upper end of slip 16. The downward facing teeth 28 on the upper end of slip 16 will transfer the downward force to the casing 124. Downward acting hydraulic forces will be applied to the elements 18 and transferred through them to the single acting slip 22. While the teeth 70 are designed to resist primarily upward forces, once the packer is set they will resist limited downward forces. To the extent the slip 22 should move relative to the casing 124, it will transfer downward force to the mandrel 11 and through it to the upper portion of the dual slip 16 as discussed above. As noted above, in many applications a packer will experience extreme forces in only one direction. In this case it is assumed that the extreme forces will only occur in the upward direction and more limited or normal forces will be experienced in the downward direction.
The elements described above with reference to
As depicted in
To ensure accurate positioning of the seals 134 between the ports 104, 105, a latch or other anchoring device 140 of the plug 132 engages the internal no-go profile 122 formed in the flow passage 12. Other anchoring and positioning means may be used for positioning the seals 134 so that they isolate the upper flow passage portion 136 from the lower flow passage portion 138, without departing from the principles of the invention.
Pressure in the upper flow passage portion 136 is communicated to the upper side 102 of the piston 100, while pressure in the lower flow passage portion 138 is communicated to the lower side 106 of the piston, and each is isolated from the other, when the plug 132 has been installed. The pressure differential may be applied across the piston 100 to bias it downwardly by increasing pressure in the upper passage portion 136, for example, by applying pressure to the primary tubing string 126 at a remote location, such as by using a pump at the earth's surface. Of course, the piston 100 could alternatively be biased downwardly by applying the pressure differential in another manner, such as by decreasing pressure in the lower passage portion 138.
As depicted in FIGS. 5A-E. pressure has been applied to the upper flow passage portion 136 after installing the plug 132, thereby applying the pressure differential across the piston 100. The downwardly biasing force due to the pressure differential acting on the piston 100 has caused the shear screws 118 to shear, permitting the downwardly biasing force to be transmitted to the release clamp 98 via the coupling 108. The downwardly biasing force has also caused the shear pins 120 to shear, permitting the release clamp 98 to displace downwardly, thereby releasing the packer 10, as explained in detail below with reference to
At this point, the seal elements 18 may still be located at least partially on the prop surface 56 and may still be in sealing engagement with the well casing 124. To completely release the seal elements 18 and the upper slip 16, upward force is applied to the mandrel 11. Note that removal of the packer 10 from a well occurs by lifting, i.e. applying upward force to, the mandrel 11 and this motion simultaneously completes the release or unsetting process. The mandrel 11 may move upward relative to the set of components including the wedge 32, slip 16, wedge 40 and the seal elements 18, since the setting forces below elements 18 have been removed. The amount of movement is limited by various elements including a pick up pin 142 connected to upper wedge 32 and sliding in a slot 144 in upper sub 33. The movement is sufficient to allow the seal elements 18 to move off of the prop surface 56 to a smaller diameter portion 54 of the mandrel 11. This movement therefore releases the seal elements 18 from the well casing 124 and allows the wedge 40 to move downward relative to slip 16 and allows the slip 16 to move downward relative to the wedge 32. These movements occur as the mandrel 11 is moved upward and disengages the slip 16 from the well casing 124. The entire packer 10 can then be pulled from the well by continued upward movement of the mandrel 11.
In
Referring additionally now to
In addition, in the method illustrated in
The upper side 102 of the piston 100 may be placed in fluid communication with the primary flow passage 12 by conveying a perforating device 152 through the flow passage and into the packer 10 as depicted in
The perforating device 152 may be accurately positioned relative to the packer 10 by using an anchoring device, such as the anchoring device 140 described above, attached to the perforating device.
An opening 160 is formed through the sidewall 150 of the mandrel 11 by firing a shaped charge 162 of the perforating device 152. Alternatively, the opening 160 may be formed by chemically cutting through the barrier, for example, by opening a valve 164 to release a chemical from a container 166 of the perforating device 152. Other methods of forming the opening 160 may be used in keeping with the principles of the invention.
It will now be appreciated that, with the opening 160 formed, a downwardly biasing force may be applied to the piston 100 by increasing the pressure in the upper portion 156 of the primary flow passage 12 relative to pressure in the annulus 148. For example, pressure may be applied to the primary tubing string 126 at a remote location, such as by using a pump at the earth's surface. When a sufficiently great downwardly biasing force is applied to the piston 100 by the pressure differential, the shear screws 118 shear, the downwardly biasing force is transmitted by the coupling 108 to the release clamp 98, and the packer 10 is released.
Note that the modified piston 100 of
As another alternative, the perforating device 152 could be used in the packer 10 illustrated in FIGS. 1A-G, that is, in the packer configured so that the piston 100 displaces in response to a pressure differential applied between isolated portions 136, 138 of the primary flow passage 12. In this alternative, the perforating device 152 could be used to form one or both of the ports 104, 105 when it is desired to apply the pressure differential to the piston 100 to release the packer 10.
An advantage of forming the ports 104, 105 or opening 160 only when it is desired to release the packer, is that this prevents exposure of the piston 100 and its seals 168 to fluid in the primary flow passage 12. The packer may be set in a well for a number of years during which fluids are produced through flow passage 12. During this time, the barrier 150 isolates the piston 100 and its seals 168 from those produced fluids and provides increased reliability by isolating the flow passage from the annulus 148.
Referring additionally now to
The device 170 includes seals 174, 176 which sealingly engage the flow passage 12 straddling the lower port 105. The seals 174,176 isolate an annular portion 178 of the flow passage 12 from the remainder of the flow passage. The annular passage portion 178 is in fluid communication with the lower port 105. When a valve 180 is opened, the lower side 106 of the piston 100 is placed in fluid communication with the pressure chamber 172.
The pressure chamber 172 may contain, for example, air at atmospheric pressure. In this example, opening the valve 180 will cause a reduction in the pressure applied to the lower side 106 of the piston 100, increasing the differential between the pressure in the remainder of the flow passage 12 applied via the upper port 104 to the upper side 102 of the piston and the pressure in the annular portion 178 of the flow passage. This increased pressure differential applies a downwardly biasing force to the piston 100.
When the downwardly biasing force is sufficiently great, the shear screws 118 will shear, thereby transmitting the force to the release clamp 98 via the coupling 108. The shear pins 120 will also shear when the sufficiently great downwardly biasing force is applied to the release clamp 98, the retaining device will displace downwardly, and the packer 10 will be released as described above.
In the above description of
Although the piston 100 is depicted in
Although in the
Referring additionally now to FIGS. 9A&B, another apparatus and method for releasing the packer 10 is representatively illustrated. In this embodiment, the piston 100 is responsive to a pressure differential between a control line 180 and the flow passage 12. Pressure is applied to the upper side 102 of the piston 100 through the control line 180, and pressure is applied to the lower side 106 of the piston via the lower port 105. Note that the upper port 104 is eliminated in this embodiment of the packer 10.
The control line 180 is depicted in
To release the packer 10, pressure is applied to the control line 180 to create a pressure differential between the control line and the flow passage 12. Pressure may be applied to the control line 180 at a remote location, such as by using a pump at the earth's surface. This pressure differential results in a downwardly biasing force being applied to the piston 100.
When the downwardly biasing force is sufficiently great, the shear screws 118 will shear, thereby transmitting the force to the release clamp 98 via the coupling 108. The shear pins 122 will also shear when the sufficiently great downwardly biasing force is applied to the release clamp 98, the retaining device will displace downwardly, and the packer 10 will be released as described above.
Instead of extending the control line 180 to a remote location, such as the earth's surface, in order to apply pressure to the control line, an alternative is depicted in
The sleeve 182 has seals 184 which initially straddle a port 186 extending from the control line 180 to the flow passage 14. By displacing the sleeve 182 downward, the port 186 may be exposed to the flow passage 14, thereby providing fluid communication between the flow passage and the control line 180. The sleeve 182 may be displaced downward using a variety of methods, such as by using a wireline or coiled tubing conveyed shifting tool, providing a differential piston area on the sleeve and applying pressure to the flow passage 14 to apply a biasing force to the sleeve, etc.
Furthermore, other means of providing selective fluid communication between the flow passage 14 and the control line 180, for example, a kobe or break plug, or a perforating device such as the perforating device 152, may be used without departing from the principles of the invention.
After the control line 180 is placed in fluid communication with the flow passage 14, pressure applied to the secondary tubing string 128 at a remote location, such as the earth's surface, is applied to the top side 102 of the piston 100. By applying a sufficiently great pressure differential between the control line 180 and the flow passage 12, the piston 100 may be displaced downwardly to release the packer 10 as described above.
Although the piston 100 is depicted in
Although in the embodiment of
Referring additionally now to
When a sufficiently great downwardly directed force is applied by the structure 182 to the release clamp 98, the shear pins 120 will shear. The release clamp 98 will then displace downwardly, permitting the release anchor 84 to expand, and thereby releasing the packer 10 as described above. The coupling 108 permits the release clamp 98 to displace downwardly, without the piston 100 also displacing.
Note that the
Referring additionally now to
A seal 186 carried on the displacement structure 184 sealingly engages an upper tubular cap 188 of the release clamp 98. The seal 186 may be an elastomer, metal to metal, or any other type of seal, and it may be integrally formed on the displacement structure 184.
When the seal 186 engages the cap 188, an upper portion 190 of the flow passage 14 is effectively isolated from a lower portion 192 of the flow passage. In this embodiment, the release clamp 98 is sealed in the flow passage 14, for example, using a seal carried on the release clamp 98. A pressure differential may be created from the upper portion 190 to the lower portion 192 by applying pressure to the secondary tubing string 128 at a remote location, such as the earth's surface. This pressure differential acting across the release clamp 98 will bias the retaining device in a downward direction.
When a sufficiently great downwardly directed force is applied by the displacement structure 184 to the release clamp 98, the shear pins 120 will shear. The release clamp 98 will then displace downwardly, permitting the release anchor 84 to expand, and thereby releasing the packer 10 as described above. The coupling 108 permits the release clamp 98 to displace downwardly, without the piston 100 also displacing.
Referring additionally now to
A lower end 204 of the device 194 contacts the release clamp 98. When a pressure differential is created from the upper flow passage portion 200 to the lower flow passage portion 202, the lower end 204 of the device 194 applies a downwardly biasing force to the release clamp 98.
When a sufficiently great downwardly directed force is applied by the displacement device 194 to the release clamp 98, the shear pins 120 will shear. The release clamp 98 will then displace downwardly, permitting the release anchor 84 to expand, and thereby releasing the packer 10 as described above. The coupling 108 permits the release clamp 98 to displace downwardly, without the piston 100 also displacing.
As the release clamp 98 displaces downwardly, the displacement structure 194 also displaces downwardly therewith. As a result, the seal 196 eventually leaves the seal bore 198. When the seal 196 is no longer sealed within the seal bore 198, the pressure differential applied between the upper and lower portions 200, 202 of the flow passage 14 will be relieved. If the pressure differential was applied by increasing pressure in the secondary tubing string 128, then this increased pressure will be relieved, thus providing a signal to the remote location that the displacement structure 194 and the release clamp 98 have displaced downwardly in response to the differential pressure. For example, this signal may alert an operator at the earth's surface that no further pressure increase is to be applied, and that the packer 10 has been released.
With reference to
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.