This application claims priority from Canadian Patent Application No. 2,746,171, filed Jul. 13, 2011.
The present disclosure relates generally to hydrocarbon well workover tools. More particularly, the present disclosure relates to zonal isolation tools for use during well workovers and methods of using the zonal isolation tools.
In cased well completion or stimulation operations, it is sometimes desirable to isolate one section or zone of the well from another. This is commonly accomplished with a “bridge plug”.
It is known that certain bridge plugs may be drilled out to remove them from the well.
It is known that certain bridge plugs may be selectively activated, for example by a drop ball, introduced into the well from surface, or other plugging systems.
It is known that certain bridge plugs may be retrievable, for example by retrieval from the well bore once the stimulation operation is complete.
One typical problem with conventional retrievable bridge plugs is that debris or other materials, for example frac sand or proppant, may accumulate on the top of the plug, which may make it difficult or even impossible to latch onto the plug for retrieval. The debris or other materials, may also accumulate in the annular region between the bridge plug and the casing, and may interfere with the release of the slips or the seals or both, making retrieval of the bridge plug more difficult or even impossible.
Another typical problem with conventional retrievable bridge plugs, in a multiple zone wellbore, where multiple retrievable bridge plugs are set to isolate the respective zones, is that it may be time and labour intensive to retrieve the multiple bridge plugs, one at a time, from the wellbore.
It is, therefore, desirable to provide an improved retrievable stimulation frac plug.
It is an object of the present disclosure to obviate or mitigate at least one disadvantage of previous retrievable bridge plugs.
A retrievable stimulation frac plug for a well casing includes a mandrel having a fluid flow bore, a seal for sealing between the mandrel and the casing, and an anchor for anchoring the frac plug in the casing.
A check valve operates to selectively seal off the fluid flow bore, opening to permit fluid or pressure below the frac plug to flow up through the fluid flow bore, and automatically closing to prohibit fluid or pressure above the frac plug to flow down through the fluid flow bore. The check valve includes a manual over-ride, which selectively holds the check valve in an open position.
The check valve is held in an open position when the frac plug is run into the casing, on a setting tool, and when the frac plug is retrieved from the casing, on a retrieving tool. When the frac plug is set in the casing, the check valve is allowed to operate normally, that is, as a check valve.
The retrievable stimulation frac plug may be used for stimulation-frac and production operations. Once the retrievable stimulation frac plug is set in the casing, production from below may pass through the inside diameter of the retrievable stimulation frac plug. Stimulation work may be performed above which seals the inside diameter of the retrievable stimulation frac plug, prohibiting the pressure/materials from the stimulation work to pass through the frac plug, isolating the zone below the frac plug from the zone above the frac plug.
The setting tool has a bore through to facilitate running the tool into the casing. Wellbore fluids can flow through the bore to reduce or eliminate the dragging/swabbing effect.
The retrieving tool has a bore through to facilitate circulating fluids, for example wellbore fluids, to wash the top of the frac plug prior to retrieving.
In a first aspect, the present disclosure provides a retrievable stimulation frac (RSF) plug for a well casing, having an elongate mandrel having a fluid flow bore, a one-way check valve mandrel seal moveable between an open position and a closed position for selectively sealing the fluid flow bore, a sealing mechanism for sealing between the mandrel and the casing, and a locking mechanism for axially locking the retrievable stimulation frac plug in the casing.
In an embodiment disclosed, the one-way check valve mandrel seal further includes a mechanical over-ride adapted to be actuated by a retrieving tool, to lock the one-way check valve mandrel seal in the open position.
In an embodiment disclosed, the one-way check valve mandrel seal includes a flapper. In an embodiment disclosed, the flapper is biased toward the closed position.
In an embodiment disclosed, the flapper has an extended lip adapted to urge the flapper into the open position upon engagement with a retrieving tool. In an embodiment disclosed, the extended lip is adapted to be operable by the retrieving tool, in order to retain the flapper in the open position.
In an embodiment disclosed, the retrievable stimulation frac plug further includes a setting tool, the setting tool having a shear rod extending through the fluid flow bore, retaining the mandrel seal in the open position, and a shear pin connecting the shear rod and a lower cone of the retrievable stimulation frac plug.
In a further aspect, the present disclosure provides a retrieving tool for a retrievable stimulation frac plug, the retrieving tool including an elongate mandrel having a bore therethrough, a collet retainer adapted to engage an extended lip of a flapper on a retrievable stimulation frac plug to move the flapper into an open position, and a collet adapted to engage and latch onto a catch of the retrievable stimulation frac plug.
In a further aspect, the present disclosure provides a method of stimulating a well having casing, including providing a retrievable stimulation frac plug having an elongate mandrel with a fluid flow bore; the fluid flow bore sealable with a check valve, the check valve moveable between an open position and a closed position and biased to the closed position, selectively moving the check valve into the open position; deploying the retrievable stimulation frac plug into the casing; and conducting a well operation.
In an embodiment disclosed, the check valve includes a flapper. In an embodiment disclosed, the well operation includes producing fluids from below the retrievable stimulation frac plug through the fluid flow bore, the check valve forced at least partially from the closed position by the fluids.
In an embodiment disclosed, the well operation includes frac-stimulation of the well above the retrievable stimulation frac plug, the check valve retained in the closed position by the frac-stimulation.
In an embodiment disclosed, the method includes retrieving the retrievable stimulation frac plug after conducting the well operation.
In an embodiment disclosed, the method further includes circulating fluids proximate an upper end of the retrievable stimulation frac plug prior to retrieving the retrievable stimulation frac plug.
In an embodiment disclosed, the method further includes providing a second retrievable stimulation frac plug having a second elongate mandrel with a second fluid flow bore; the second fluid flow bore sealable with a second check valve, the second check valve moveable between an open position and a closed position and biased into the closed position, providing a retrieving tool, attached below the second retrievable stimulation frac plug, selectively moving the second check valve into the open position, deploying the second retrievable stimulation frac plug into the casing, above the retrievable stimulation frac plug, and conducting a second well operation.
In an embodiment disclosed, the method further includes providing a retrieving tool on a work string, deploying the retrieving tool into the well to latch onto the second retrievable stimulation frac plug, releasing the second retrievable stimulation frac plug from the casing, further deploying the retrieving tool into the well, with second retrievable stimulation frac plug and second retrieving tool attached to latch onto the retrievable stimulation frac plug, releasing the retrievable stimulation frac plug from the casing, and pulling the work string from the well, with the second retrievable stimulation frac plug and the retrievable stimulation frac plug attached, in a single run.
Other aspects and features of the present disclosure will become apparent to those ordinarily skilled in the art upon review of the following description of specific embodiments in conjunction with the accompanying figures.
Embodiments of the present disclosure will now be described, by way of example only, with reference to the attached Figures.
Generally, the present disclosure provides a method and system for isolating one section of a well from another, for example to facilitate stimulating the well.
Referring to
The slip portion 40 includes slips 50 mounted within a slip cage 120, having slip springs 130 biasing the slips 50 toward the mandrel 20. The slips 50 are mounted between a lower cone 140 and upper cone 150. An o-ring 160 seals between the lower cone 140 and the mandrel 20. An end cap 170 sits between the lower cone 140 and the slip cage 120 and retains the lower cone 140.
The annular seal portion 60 includes one or more sealing elements 70 mounted between an upper gauge ring 180 and a lower gauge ring 190 on a seal mandrel 200. In an embodiment disclosed, a plurality of sealing elements 70 are used. In an embodiment disclosed, a spacer 210 sits between the sealing elements 70. An o-ring 220 seals between the mandrel 20 and the upper gauge ring 180.
A lower shear sub 230 connects the upper cone 150 of the slip portion 40 and the seal mandrel 200 of the annular seal portion 60. A shear screw 240 pins the connection between the lower shear sub 230 and the seal mandrel 200. In an embodiment disclosed, the shear screw 240 is designed to shear upon application of about a 2000 lb shear force.
A latch 250 is connected with the upper gauge ring 180 through a release shear sub 260 and an upper shear sub 270. The connection between the latch 250 and the upper shear sub 270 includes an upper ratchet 280. The connection between the upper shear sub 270 and the release shear sub 260 includes a release shear sleeve 290 and a lower ratchet 300. A snap-ring 330 engages the lower ratchet 300. A shear screw 310 pins the connection between the upper shear sub 270 and the mandrel 20. A shear screw 320 pins the connection between release shear sub 260 and the release shear sleeve 290. In an embodiment disclosed, the shear screw 310 is designed to shear upon application of about a 2000 lb shear force. In an embodiment disclosed, the shear screw 320 is designed to shear upon application of about a 2000 lb shear force.
In an embodiment disclosed, a deflector 340 proximate the latch 250 provides an annular seal between the retrievable stimulation frac plug 10 and the casing 350 (see
The fluid flow bore seal portion 80 includes a check valve, in the form of flapper seal 360, formed between a flapper 370 and the fluid flow bore 30 of the mandrel 20. The flapper 370 is mounted on a flapper pin 380 forming a flapper hinge 390, the flapper 370 is moveable between an open position 100 (
In an embodiment disclosed, the retrievable stimulation frac plug 10 may be used in vertical or horizontal wells or both.
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In conjunction with the sleeve adaptor 510, a shear rod 540 having an open bore 580 is inserted through the fluid flow bore 30 of the retrievable stimulation frac plug 10 mandrel 20 (see
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A lower end of the drag block housing 610 includes a collet mechanism 680. A collet retainer 690 and the drag block housing 610 are connected. A collet 700, having fingers 710 is received on a collet plug 720, within the collet retainer 690. Slots 730 between the fingers 710 are filled with a sealing material 740, such as an elastomeric material, for example highly saturated nitrile (HSN) or a molded rubber. A set screw 750 retains collet retainer 690 relative to the drag block housing 610.
In an embodiment disclosed, the retrieving tool 600 may include a centralizing system to align the retrieving tool 600 and the retrievable stimulation frac plug 10. In an embodiment disclosed a removable collet protector 760 (see
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The shear rod 540 extends through the fluid flow bore 30 of the mandrel 20 and holds the flapper 370 open, against the bias of the flapper spring 410. As the retrievable stimulation frac plug 10 is run into the casing 350, the flapper 370 is retained in the open position 100, allowing for additional fluid bypass (through the bore 580 and ports 590). When the retrievable stimulation frac plug 10 is in the desired location in the casing 350, the shear rod 540 is removed, for example by pulling upward on the connecting stud 550 with the setting line 600 such as slickline or electric line while the work string 570 is held in place. In pulling upward, the shear rod 540 pulls the lower cone 140 with it, activating the slips 50 and the sealing elements 70. When the shear screw 560 reaches its limit, the shear screw 560 breaks, releasing the shear rod 540 from the retrievable stimulation frac plug 10. The retrievable stimulation frac plug 10 is thus locked axially in place with the slips 50 and sealing elements 70 within the casing 350 form a barrier or plug between the portion of the casing 350 below the retrievable stimulation frac plug 10 and the portion of the casing 350 above the retrievable stimulation frac plug 10. In an embodiment disclosed, the shear screw 560 is designed to shear upon application of about a 2000 lb shear force. Once the retrievable stimulation frac plug 10 is set in place, the work string 570 can be pulled, leaving the frac plug 10 in place.
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As an example only, utilizing three (3) retrievable stimulation frac plugs 10, a first retrievable stimulation frac plug 10A may be run in and set within the casing 350 as described above. A first stimulation operation may be conducted above the first retrievable stimulation frac plug 10A, isolated from the casing 350 below the first retrievable stimulation frac plug 10A. A second retrievable stimulation frac plug 10B may be run in and set within the casing 350 above the first retrievable stimulation frac plug 10A. A second stimulation operation may be conducted above the second retrievable stimulation frac plug 10B, isolated from the casing 350 below the second retrievable stimulation frac plug 10B. A third retrievable stimulation frac plug 10C may be run in and set within the casing 350 above the second retrievable stimulation frac plug 10B. A third stimulation operation may be conducted above the third retrievable stimulation frac plug 10C, isolated from the casing below the third retrievable stimulation frac plug 100.
While, in this example there are three retrievable stimulation frac plugs, it is merely an example. Any number of retrievable stimulation frac plugs may be run. In an embodiment disclosed, an unlimited number of retrievable stimulation frac plugs may be run and retrieved in the same well.
Subsequently, each of the third retrievable stimulation frac plug 10C, second retrievable stimulation frac plug 10B, and first retrievable stimulation frac plug 10A may be retrieved, one at a time (i.e. one per trip), utilizing a retrieving tool 604 as described above. While, in this example there are three retrievable stimulation frac plugs, that is merely an example. Any number of retrievable stimulation frac plugs may be run. In an embodiment disclosed, an unlimited number of retrievable stimulation frac plugs may be run and retrieved in the same well.
However, in an embodiment disclosed, the third retrievable stimulation frac plug 10C, second retrievable stimulation frac plug 10B, and first retrievable stimulation frac plug 10A may be retrieved in a single trip, as follows.
Referring to
Once the stimulation operations are complete, the third retrievable stimulation frac plug 100 may be latched onto and released as described above. Once the third retrievable stimulation frac plug 100 is released, the work string 570, with the third retrievable stimulation frac plug 10C and third retrieving tool 604C attached is deployed further into the casing 350 to latch onto and release the second retrievable stimulation frac plug 10B. Once the second retrievable stimulation frac plug 10B is released, the work string 570, now with the third retrievable stimulation frac plug 100 and third retrieving tool attached 604C, and with the second retrievable stimulation frac plug 10B and the second retrieving tool 604B attached, is deployed further into the casing to latch onto and release the first retrievable stimulation frac plug 10A. Once the first retrievable stimulation frac plug 10A is released, the work string 570 now with the third retrievable stimulation frac plug 10C (and third retrieving tool 604C), the second retrievable stimulation frac plug 10B (and the second retrieving tool 604B), and the first retrievable stimulation frac plug 10A attached, may be pulled from the casing 350. Thus, a plurality, in this example three (3), retrievable stimulation frac plugs 10 may be pulled in a single run. While, in this example there are three retrievable stimulation frac plugs, that number is merely an example. Any number of retrievable stimulation frac plugs may be run. In an embodiment disclosed, an unlimited number of retrievable stimulation frac plugs may be run and retrieved in the same well.
The time and expense savings are self evident, particularly as the number of retrievable stimulation frac plugs 10 increases. In the example of three (3) frac plugs, two (2) trips are saved. If the number of frac plugs was instead ten (10), fifteen (15), or for example fifty (50), the number of trips saved may be nine (9), fourteen (14), or forty-nine (49) respectively, resulting in decreased time and therefore reduced equipment and labour costs.
In an embodiment disclosed, where the plurality of retrievable stimulation frac plugs to be retrieved becomes large, for example fifty (50) or more, they need not all be retrieved at the same time, and may instead be retrieved in convenient groups, for example, groups of 5, 10, 20, etc. as the case may be.
In the preceding description, for purposes of explanation, numerous details are set forth in order to provide a thorough understanding of the embodiments. However, it will be apparent to one skilled in the art that these specific details are not required. In other instances, well-known structures and components are shown in block diagram or simplified form in order not to obscure the understanding.
The above-described embodiments are intended to be examples only. Alterations, modifications and variations can be effected to the particular embodiments by those of skill in the art without departing from the scope, which is defined solely by the claims appended hereto.
Number | Date | Country | Kind |
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2746171 | Jul 2011 | CA | national |
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Number | Date | Country | |
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20130014958 A1 | Jan 2013 | US |