The present invention relates to a system and method for fracking a hydrocarbon formation and completing a well for production, and more particularly relates to a system and method which immediately after completion of fracking automatically locates a sand screen at an opened port in a production string to prevent ingress of sand from the hydrocarbon formation to allow of subsequent immediate production.
After an oil or gas well is drilled within an underground hydrocarbon formation, the well and zones of interest need to be completed prior to production commencing.
Part of the completion process typically firstly includes a fracking operation.
Fracking involves injection of high pressure fluids (namely incompressible liquids, often containing proppants) into the hydrocarbon formation/reservoir to initiate fractures within the surrounding rock to increase porosity of “tight” formations and thereby increase the ability of hydrocarbons within the formation to flow from within a hydrocarbon formation.
Fracking operations for completing a well within a reservoir may increase production from the well by many multiples in a given time period, in some cases up to 3× or greater if conducted over the entire length of a horizontal wellbore as compared to what would otherwise have been the case if a fracking operation had not been completed.
Accordingly, the fracking process can be a very important and critical step in preparing a wellbore for production.
It is important, however, to be able to both frac and further complete a wellbore and ready the well for production as quickly and efficiently as possible, with as little expense in doing so as possible.
As set out further herein, various prior art downhole tools and systems exist and have been used to stimulate wells by permitting treatment/fracturing in multiple contiguous regions within a hydrocarbon formation.
Fracking fluid may contain various adjuvants such as acids and/or diluents to increase followability of the oil/gas from the formation. In addition, however, fracking fluids commonly contain proppants such as fine sand (frac sand) or ceramic beads of consistent and engineered uniform diameter to uniformly “prop” open the created fractures and maintain such fractures in the formation so that hydrocarbons may better flow from the formation.
As explained below, the introduction of large quantities of frac sand into a formation during the fracking process typically results in significant quantities of frac sand being entrained in the oil or gas which flows back into the wellbore for pumping to surface when oil is produced through opened frac ports in a wellbore. Due to the abrasive nature of sand, deleterious and negative results occur during production, including additional increased and heavy wear on pump components within the well, greatly shortening pump life. Downhole pumps, and even downhole pumps most resistive to sand abrasion such as progressive cavity pumps, are typically expensive. Having to frequently replace such pumps results in increased costs not only in the replacing/refurbishing the pump and its components, but further in service rig time and costs in having to “trip out” of a well a downhole pump and “run back in” the production string with a new pump, to say nothing of the lost production and profits due to the well being “off line” during the time of such repairs.
Sand screens are known in the art, and are typically inserted within a production string, typically after the tripping out of the frac string from the well, when a production string having a sand screen covering open ports on such production string is then separately “run in” into the wellbore.
Disadvantageously, however, the aforesaid two-step process having to frac, then trip out the frac string, and then run in a production string with pre-installed sand screens thereon results in considerable additional time and expense in tripping out the frac string, and thereafter running in the production string with elongate cylindrical screens installed thereon.
There is also an inherent risk of damaging the screens during “run in” of the production string in the wellbore.
A more efficient system which allows not only fracking, but further installs sand screens without having to trip out a frac string, has been recognized as beneficial to the wellbore completion industry.
For example, U.S. Pat. No. 9,976,394 along with US 20180320488 each entitled “System and Methods for Fracking and Completing a Well which Flowably Installs Sand Screens for Sand Control”, each commonly invented with the within application and commonly assigned to the present applicant, both disclose use of actuating members to selectively engage a respective desired sleeve covering associated ports along the production string. Thereafter, under influence of uphole-applied pressure, the actuating members cause such respective sleeves to be slidably moved downhole to expose an open port in the production string. Fracking fluid is then injected in the production string to frac the formation in the region of the opened port(s). After fracking of the formation in the region at the location of the opened port (s), flowable sand screen subs are thereafter flowed downhole to cover the respective opened port(s) and thereby prevent sand from flowing into the opened port(s) and allow only hydrocarbons from the formation to flow into the production string via the opened port(s).
Disadvantageously, however, such above system and method of U.S. Pat. No. 9,976,394 et. al. requires two (2) members to be flowed downhole for each port to be fracked, namely a first actuating member flowed downhole to selectively engage the sleeve covering the respective port to slidably move such sleeve downhole under uphole-applied hydraulic pressure to thereby open the respective port, and another (second) flowable member having a sand screen thereon to likewise be flowed downhole and fixedly located in the production string at the region of the opened port to thereafter screen sand from entering the wellbore via the opened port when fracking has ceased and the production string is receiving hydrocarbons via the opened port and such hydrocarbons are thereafter being pumped to surface.
Similarly, US 2019/0353005 (now U.S. Pat. No. 10,648,285) entitled “Fracturing System and Method” to Baker Hughes teaches a fracturing sleeve having both an opening sleeve and a closing sleeve, which as disclosed and as shown in
Numerous other designs exist for moving a sliding sleeve so as to open a port and thereafter to cover the port, but do not provide for sand control or provision of screens.
As one example, US 2016/0108711 entitled “Sliding Sleeve for Stimulating a Horizontal Wellbore, and Method for Completing a Wellbore”, in inter alia
While problems of “screen-out” are mentioned in US 2016/01088711 [a condition where continued injection of fluid inside the fracture requires pressures in excess of the safe limitations of the wellbore or wellhead equipment—“screen-out” occurs when the proppant (sand or other solids) in the fracture fluid being injected into the formation restricts flow within the wellbore or into the perforations], there is no teaching or suggestion whatsoever in US 2016/01088711 of use of sand screen screens to cover new apertures created in casing 610 in the region of sleeves 500A-500H, nor is there any disclosure or suggestion of how a sand screen could be incorporated into the apparatus.
Accordingly, a need exists for a less time-consuming, least costly, but yet efficient system and method for both fracking and completing wells, which provides a less expensive and less time-consuming method. Specifically, there exists a need for an “all-in-one” well fracking and completion system which allows flowing into a tubular string one actuating member per port which is fracked, which allows not only fracking of the reservoir at the given port but further without pulling the tubular string automatically installs a sand screen and thus be able to immediately thereafter produce from such port.
It is an object of the invention that a tubular string used for fracking need not be “tripped out” after a fracking step in order to complete the well and allow production from the well after fracking operations.
It is a further object of the present invention that sand from a hydrocarbon formation containing oil sand as well as additional sand resulting from conducting a fracking operation be substantially prevented from entering a wellbore during production operations and otherwise detrimentally affecting pumping equipment, to say nothing of increased costs of disposing of such sand.
It is a further object of the invention to provide a system and method which reduces instances of damage being inflicted to sand screens when they are positioned within a wellbore downhole.
It is a still further object to be able to immediately after fracking, provide sand screens at the locations of the frac ports, to immediately thereafter prevent, as much as possible, the ingress of sand into the wellbore and the deleterious results which occur therefrom.
It is a further object of the invention to avoid having to flow downhole a plurality of actuation members for each port to be fracked, and to be able to use only one actuation member for each port.
Reference herein and below to “uphole” and “downhole” with regard to a particular component of the system, or with respect to the method of the present invention, is a reference to a location on the component within a wellbore where uphole means in the direction of the surface along a wellbore, and “downhole” is the correspondingly opposite direction towards a toe of the wellbore.
Reference to the term “unique profile” herein shall be construed as including, but not limited to, a unique longitudinal width dimension.
Accordingly, in order to meet some or all of the above objects and advantages, in a first broad embodiment the present invention comprises a system for fracking a hydrocarbon formation at a given location along a wellbore, comprising;
wherein when said cylindrical actuation member having said unique profile thereon has been flowed downhole in said tubular liner by pressurized fluid and has selectively engaged said desired sliding sleeve member having a corresponding unique profile thereon and caused said sliding sleeve to move downhole so as to open said frac port, said spring member is compressed so as to permit said sand screen member to be longitudinally positioned within said tubular member so as not to cover said opened frac port thereby allowing unobstructed flow of said pressurized fluid through said frac port; and
wherein when said pressurized fluid is ceased being applied to said actuation member, said spring member immediately decompresses and slidably moves said sand screen member longitudinally within said tubular liner to a location beneath and covering at least a portion of said opened frac port.
Advantageously, the above system provides for the immediate installation of a sand screen at such given location of an opened port without having to “trip out” a frac string prior to commencing production at such location, and further provides for the use of only one actuation member, and not having to flow downhole a second member having a sand screen thereon.
In a refinement of such first broad aspect, each of the sliding sleeve members are configured so as to lockingly engage the tubular liner when the respective sliding sleeve members are each respectively moved so as to uncover a corresponding frac port. In such manner the sliding sleeve members, once in said open position, are thereby prevented from thereafter inadvertently returning to a closed position and covering the opened port in the tubing liner. Absence of this feature would mean that the slidable sleeve could potentially close, thus preventing oil from being produced from such (now closed) port along the tubular liner. It is contemplated in a preferred embodiment that the locking engagement comprise mating engagement means on both the sliding sleeve members and on the tubular members.
Accordingly, in a preferred, non-limiting embodiment, the mating engagement means on the sliding sleeve members comprise a plurality of collet fingers, radially outwardly biased, and extending from a downhole end of each sliding sleeve member, and the corresponding mating engagement means on the tubular liner comprises an annular circumferential ring on the tubular liner, which when one of said slidable sleeve members is caused to be moved to the open position, the radially outwardly-biased collet fingers, and in particular protuberances on respective distal ends of such collet fingers, matingly engage said annular circumferential ring on said sliding sleeve member so as to lockingly engage and secure the sliding sleeve member in the open positon to the tubular string. Other manners of providing mating engagement of each sliding sleeve with the tubular liner will now be apparent to persons of skill in the art and are specifically contemplated as part of the within invention.
In a further particular refinement, the unique profile of the radially-outwardly biased protuberance on the actuation member is of a unique width W1, and the interior circumferential groove on the mating sliding sleeve is of a width equal to or greater than W1.
Thus in a still-further refinement, the system for fracking and completing a well in a hydrocarbon formation of the present invention further comprises:
a second actuation member, insertable within the interior bore of the tubular liner, comprising:
wherein when the cylindrical actuation member having said unique profile thereon has been flowed downhole in the tubular liner by pressurized fluid and has selectively engaged the desired sliding sleeve member having a corresponding unique profile thereon and caused the sliding sleeve to move downhole so as to open the associated frac port, the spring member on the actuation member is compressed so as to permit the sand screen member to be longitudinally positioned along said actuation member in a region within said tubular member so as not to cover the opened frac port, thereby allowing unobstructed flow of said pressurized fluid through said frac port during a fracking operation; and
wherein when the pressurized fluid is ceased being applied to the actuation member, the spring member is configured to be immediately decompressed and slidably move the sand screen member longitudinally within said tubular liner to a location beneath and covering at least a portion of said opened frac port.
In a preferred or additional refinement, the radially-outwardly biased protuberance on the actuation member may be configured such that after matingly engaging the interior circumferential groove or profile on the respective sliding sleeve member it remains lockingly engaged with the interior circumferential groove or profile on said slidable sleeve. Thus advantageously, the actuation member is prevented from further movement within said tubular liner, and thus the sand screen thereon remains fixed in the open position with the associated frac port and all oil flowing into the tubular liner via such port will necessarily be required to pass through such sand screen.
In a further or alternative refinement of the first broad embodiment, the dissolvable or burstable plug member is a dissolvable plug member which is dissolvable upon a dissolving fluid being provided to the interior bore of the tubular liner. The dissolvable plug member may further comprise a dissolvable ball which may be flowed downhole in the tubular liner, and which after being exposed to a dissolving fluid, after a passage of time dissolves so as to allow flow of bitumen along the tubular string. Composition of balls which may dissolve in time, and corresponding fluid which may cause such dissolution, are well known to persons of skill in the art, and are thus not further discussed in detail herein.
In a further refinement, the cylindrical actuation member further comprises a seating surface, configured to provide a sealing surface against which said dissolvable or burstable plug member may abut, which sealing surface in combination with said plug member, at least for a limited time, prevents pressurized fluid from travelling through said actuation member.
In another broad aspect of the system of the present invention, such invention comprises a cylindrical actuation member, insertable within a tubular liner for use when fracking a hydrocarbon formation at a given location along the tubular liner, which after opening a port and after a fracking step, immediately locates a sand screen member at said location without having to “trip out” a frac string prior to commencing production, comprising:
In a still-further broad aspect of the present invention, the present invention comprises a method for conducting a fracking procedure at a given location along a wellbore. Such method advantageously locates a sand screen at such location immediately after a fracking step at such location is completed, thereby immediately preventing ingress of any sand into said tubular liner and allowing subsequent production from the formation without having to first “trip out” any frac string insert a production string in order to commence production.
Such method comprises the steps of:
In a refinement of such method, the plug member on said actuation member is a burstable disk and such method further comprises the step, after step (v), of injecting a pressurized fluid into said interior bore at a pressure sufficient to rupture said burstable disk, so as to thereafter allow fluid to flow through said first actuation member. This advantageously then allows oil which has flowed into the tubular string after fracking through the opened port to thereafter be pumped to surface.
Where the plug member is a dissolvable member, the method further comprises the step, after step (v), of injecting a dissolving fluid or using said frac fluid if said frac fluid is a dissolving fluid, to dissolve said dissolvable member so as to thereafter allow fluid to flow through said first actuation member.
In a preferred embodiment of the above method, such method further comprises the step when said first actuation member engages the corresponding sliding sleeve member and moves such sliding sleeve member to the open position, of causing the sliding sleeve member when at said open position to lockingly engage the tubular liner. This feature thereby advantageously allows the sliding sleeve member and associated frac port within the tubular liner to be maintained in an open state to ensure production may continue through such opened frac port.
In such preferred embodiment, the step of causing said one of said sliding sleeve members when at said open position to lockingly engage said tubular liner comprises the step, of causing a biased protuberance on said sliding sleeve member to engage a mating groove in said tubular member so as to retain said first sliding sleeve member in a position where the respective associated frac port is uncovered.
Alternatively, the said step of causing said one of said sliding sleeve members when moved to said open position to lockingly engage said tubular liner comprises the step of causing a ratchet member on said sliding sleeve to engage a mating ratchet member on said tubular liner, so as retain said one of said sliding sleeve members in a position where the respective associated frac port is uncovered and return movement of the sliding sleeve in an uphole direction is thereby prevented.
In a further preferred embodiment of the above method, a shear pin is provided to initially maintain each sliding sleeve initially covering an associated port, so that during insertion of a tubular liner into a well bore any detritus or tailings remaining from drilling the wellbore, or any sand or obstructive material, will be prevented from entering the wellbore. Accordingly, in a preferred embodiment, step (iv) of the above method of causing said one sliding sleeve member and first actuation member engaged therewith to together move downhole and uncover and thereby open an associated of said plurality of frac ports further comprises the step of using such applied pressurized fluid to cause a shear pin fixing said sliding sleeve within said tubular liner to shear so as to then allow said one sliding sleeve member and first actuation member engaged therewith to together move downhole within said tubular liner and uncover and thereby open an associated of said plurality of frac ports.
In a still further embodiment of the above method, when said first actuation member engages said one sliding sleeve member and moves said sliding sleeve member to the open position, the first actuation member may further be caused to lockingly engage the sliding sleeve member, thereby preventing further movement of said actuation member relative to said one of said sliding sleeve members. This advantageously allows for each actuation member used to be fixed in position and evenly distributed along the tubular liner, and each engaged with a respective sliding sleeve.
In a preferred embodiment of the aforesaid method, such method further comprises the steps, after step (vi), of:
In other words, it is contemplated that the method of the present invention be repeated for each port located along the tubular string, and thus the method of the present invention further comprises repeating steps (i)-(v) using a second, third, and consecutive cylindrical actuating members, each having a unique profile mating with a similar unique interior circumferential groove or grooves on the interior of each sliding sleeve, until all of said plurality of spaced-apart ports along the tubular liner have been uncovered, the wellbore fracked at each opened frac port and a sand screen situated at each opened frac port.
Typically, the most-distal port along the wellbore from surface will be opened first by a first actuation member, and the formation fracked at such location and a sand screen installed, and thereafter the second actuating member will be targeted to the second—lowermost (second most distal) port, and the sequence repeated for each successive port and corresponding sliding sleeve, until the entirety of wellbore has been fracked along its entire length, and sand screens installed at each port after fracking.
In one embodiment the unique profile may vary uniquely in terms of the relative width of the protuberance(s) on the actuating member and the corresponding width of the circumferential groove (s) on the interior of the various sliding sleeves. Thus pairs of mating profiles may be a series of protuberances and circumferential interior mating grooves, each of varying widths and/or spacing relative to other pairs of actuating members and sliding sleeves, to provide unique engagement of one actuating member with a unique sliding sleeve to open a port at a desired length along.
In a further refinement, the radially-outwardly biased protuberance of said first actuation member is of a width W1, and said resiliently-outwardly biased protuberance of said second actuation member is of a width W2, wherein W2<W1.
Further advantages and permutations and combinations of the invention will now appear from the above and from the following detailed description of various particular embodiments of the invention, taken together with the accompanying drawings each of which are intended to be non-limiting, in which:
A plurality of cylindrical hollow sliding sleeve members 18 (“sliding sleeve”) are provided within interior bore 15 of and along tubing liner 14, each sliding sleeve 18 configured when in an initial closed position to cover a corresponding of said longitudinally spaced-apart frac ports 16, as shown for example in
As best seen for example in
As best seen for example in
Configuration of sliding sleeves 18 in such manner wherein they are comprised of a plurality of individual members 18a, 18b threadably joined together provides the significant advantage of allowing easier and less expensive machining of internal grooves 22a, 22b, and 22c on each of the respective individual members 18a, 18b, the purpose of such internal grooves 22 (ie. 22a, 22b, and 22c) being more fully explained herein.
As more fully explained below and with reference to applicant's corresponding U.S. Pat. No. 10,563,482 entitled “Profile-Selective Sleeve for Multi-stage Valve Actuation” which is incorporated by reference in its entirety with respect to the manner of using profile selective sleeves and their manner of selective engagement by unique actuation members, by providing sliding sleeves 18 each with an interior circumferential groove or grooves 22 of a unique “key” profile (in this case each groove 22 or series of grooves for example 22a, 22b, & 22c, being of a varying width W1 and a varying longitudinal distance between each groove 22—see for example
After “keyed” engagement of the protuberances 27a, 27b, and 27c of the actuation member 25 with a selected sliding sleeve 18 having therein correspondingly sized and spaced internal grooves 22a, 22b, and 22c and upon application of uphole fluidic pressure to actuation member 25, the particular desired sliding sleeve 18 and actuation member 25 are together caused to be slidably repositioned downhole to thereby uncover and thereby open the associated frac port 16.
As seen for example in
A plurality of shear members 37 are provided, typically shear pins, with at least one shear member 37 extending through the tubing liner 14 into a threaded aperture 37a in each sliding sleeve 18, to initially secure respectively each sliding sleeve 18 to the tubular liner 14 in the initial closed position covering each port, as shown for example in
As referenced above, at least one actuation member 25 is provided, as can best be seen in
A plug member 30, which may be a dissolvable plug member 32 such as a dissolvable ball, or alternatively a burstable plug member (not shown), may be flowed into or originally positioned in the actuation member 25, to initially prevent flow of fluids through hollow interior bore 17 of actuation member to allow;
As regards collet sleeve portion 33 of actuation member 25, such collet sleeve portion 33 allows the actuation member 25, when flowed downhole, allows actuation member 25 to selectively engage a desired sliding sleeve 18 along tubing string 14. Collect sleeve portion 33 has at least one radially-outwardly biased protuberance 27 on a periphery thereof having a unique profile for such purpose, which is configured to matingly engage an interior circumferential groove or grooves 22 of similar unique (mating) profile on a corresponding one of the plurality of sliding sleeve members 18, as best shown in
As regards a dissolvable or burstable plug member 30, such plug member 30 (for a limited time in the case of a dissolvable plug, or up to a specified pressure in the case of a burstable plug member) prevents pressurized fluid injected downhole in said interior bore 15 from travelling through said actuation member 25. Such thereby allows actuation member 25 along with engaged respective sliding sleeve 18 to be forcibly flowed downhole in said tubular liner 14 by the pressurized fluid, as shown by arrow in
After the supply of a dissolvable fluid which acts on the plug member 30 to cause it after a period of time to dissolve, or where the plug member 30 is a burstable plug (not shown), after the provision of a pressure pulse uphole of the burstable plug causing it to burst, oil which enters interior bore 15 of tubular liner 14 may be freely pumped uphole.
As regards longitudinally-extending sand screen member 40 forming part of actuating member 25, such sand screen member 40 as best seen in
As may be best seen from
As regards spring member 42 forming part of actuating member 25, spring member 42 is in a preferred embodiment a helical coil spring, as best shown in
Upon cessation of supply of pressurized fluid to an uphole end of actuation member 25 and plug member 30, spring 42 decompresses and slidably repositions sand screen member 40 in an uphole direction so as to position at least a portion of sand screen member 40 of immediately beneath port 16, as best shown in
As noted above, each of said sliding sleeve members 18 and the tubular liner 14 at a location proximate each of said frac ports 16 have mating engagement means which become respectively lockingly engaged when said sliding sleeve members 18 are each respectively moved so as to uncover a corresponding frac port 16. In a preferred embodiment, and as best seen in
As best shown in
In the embodiments shown and as best seen in
This configuration, whereby the width of the protuberance 27b on successive actuation members 25 and the width of annular grooves 22 on the tubular liner 14 in the region of progressively more uphole ports successively lessens thus ensures that successively-inserted actuation members 25, each with successively lesser widths of protuberance 27b, will successively engage and open each of progressively more uphole sliding sleeves 14.
Thus in a further refinement of the present invention, a second, third, fourth and potentially additional actuation members 25′, 25″, 25′″ and 25″″, etc., may be similarly utilized, where each are identical to actuation member 25 save and except for a different mating profile such as but not limited to, a progressively lesser width W2, W3, W4, and W5 on the respective collet sleeve portion 33 additional actuation members 25′, 25″, 25′″ and 25″″, etc, may be used to successively engage and open progressively more uphole sliding sleeves 18 to successively expose ports 16, frac the formation in such region through the opened port, and thereafter immediately install sand screens 40 after completion of the fracking step for each of the respective ports 16.
Again, in such an embodiment, for each successive actuation member 25′, 25″, 25′″ and 25″″, etc., the radially-outwardly biased protuberance 27b on the respective actuation member is configured such that after matingly engaging the interior circumferential groove or profile 22 on the corresponding sliding sleeve member 18, such radially-outwardly biased protuberance on the respective actuation member 25′, 25″, 25′″ and 25″″, etc remains lockingly engaged with the interior circumferential groove or profile 22 on the slidable sleeve 18, and the respective actuation member is thereby prevented from further movement within sliding sleeve 18.
Similarly, for each of the associated sliding sleeve members sleeve members 18 and the tubular liner 14 at a location proximate each of said frac ports 16, each have mating engagement means which become respectively lockingly engaged when said sliding sleeve members 18 are each respectively moved so as to uncover a corresponding frac port 16.
Such mating/locking engagement means may take the form, as shown for example in
In one embodiment, where the plug member is dissolvable ball 32, and as best seen in
In the embodiment shown (ie. immediately prior to being provided with an additional plug member 30 and being flowed downhole), the uphole end thereof is provided with a seating surface 60 to allow the seating of a plug member 30 therewithin, namely a dissolvable ball 32. Dissolvable ball 32 may be flowed downhole by fluid pressure, and caused to seat in seating surface 60, thereby preventing, along with o-ring seals 96 located on seating surface 60, any subsequent passage of fluid past actuation member 25 and thereby and causing dissolvable ball 32 and actuation member 25 to be together flowed downhole.
Alternatively, in place of seating surface 60 the actuation member 25 may have a plug member 30 in the form of a burstable disk (not shown), which, up to a given fluid pressure applied uphole of actuation member 25, resists passage of fluid through bore 17.
Upon uphole fluid pressure exceeding a certain pressure, for example immediately subsequent to supplying pressurized fracking fluid through ports 16, a short high fluid pressure pulse may be provided to burst the burstable disk (not shown) to thereafter allow flow of fluid, including produced oil, through internal bore of actuation member 25.
On actuation member 25 a collet sleeve 33 is provided at the downhole side thereof. Collet sleeve 33 has a series of longitudinal slots 97 therein, to allow resilient flexing of raised protuberances 27a, 27b, and 27c.
Specifically, exterior periphery of collet sleeve 33 possesses a unique profile 27, comprising one or more resiliently-flexible raised protuberances 27a, 27b, and 27c, each of unique widths and spacing relative to similar protuberances on other actuation members 25 used for actuating and uniquely engaging other sliding sleeves 18 located along tubing liner 14. For example, the longitudinal width W1 of raised protuberance 27b may be of a unique and different width W1 which is different that a width W2 of a corresponding raised protuberance 27b on another actuation member 25, to thereby allow each actuation member to selectively engage a corresponding groove 22b of similar unique width within a sliding sleeve 18.
A screen support assembly 43 is threadably secured to an uphole end of collet member 33 of actuation member 25. Screen support assembly 43 has mounted on the outer periphery thereof a coil spring 42, which is initially secured on screen support in a compressed state. A ring member 55 allows a guide pin/stop member 92 therein to slidably move in longitudinal channel 91 within screen support assembly 43.
A cylindrical sand screen 40 is further provided, which circumferentially surrounds screen support assembly 43 and is located thereon between seating surface 60 and ring member 55. Seating surface 60 is initially secured to screen support assembly 43 by shear screws 94 which are threadably inserted and extend into threaded apertures 95 in screen support assembly 43. Means (not shown) may further be provided to retain seating surface 60 attached to screen support assembly 43 after shear screws 94 have been sheared, to prevent seating member 60 inadvertently being flowed uphole and covering an opened port 16.
A gap/space 93 is further provided between the uphole end of screen support assembly 43 and seating surface 60, to allow movement downhole of seating surface member 60 upon application of uphole fluidic pressure when a ball 30 is used as the plug member to thereby allow shearing of shear screws 95. Upon shearing of shear screws 95, an uphole force exerted by compressed coil spring 42 is then able to cause desired uphole displacement of sand screen member 40, ring member 55, and seating surface 60.
Specifically,
As may be best seen in
As may be seen in
Operation of the Invention
Step 401 comprises the initial step of providing a tubular liner, having a hollow interior bore 15 with a plurality of frac ports 16 longitudinally spaced therealong and a corresponding plurality of sliding sleeve members 18 covering each of said frac ports 16, within a wellbore in a hydrocarbon formation 10.
Step 402 comprises the step of situating a substantially cylindrical actuation member 25 having a radially-outwardly biased protuberance(s) 27 having a unique profile thereon within the tubing liner 14.
Step 403 comprises the step of applying a pressurized fluid to an uphole end of the actuation member 25 and causing the actuation member 25 to flow downhole in the tubing liner 14 and causing the radially outwardly-biased protuberance 27 thereon to engage a corresponding unique mating profile 22 possessed by the sliding sleeve member 25.
Step 404 comprises the step of continuing to apply pressurized fluid to the actuation member 25 in the tubular liner 14 and causing the sliding sleeve member 14 and actuation member 25 engaged therewith to together move downhole and cause the sliding sleeve 14 to uncover the associated frac port 16.
Step 405 comprises the step of injecting a fracking fluid under pressure into the tubular liner 14 and causing the fracking fluid to flow into the hydrocarbon formation 10 via the opened frac port 16.
Step 406 comprises the step of ceasing supply of the supply of fracking fluid under pressure, or reduced pressure, so as to allow a spring member 42 on the actuation member 25 to decompress and thereby reposition a sand screen member 40 on the actuation member 25 to a position covering at least a portion of the opened associated frac port 16, such that hydrocarbon flowing from the hydrocarbon formation 10 through the opened frac port 16 into the hollow interior bore 15 of the tubular liner 14 pass through the sand screen member 40.
Step 407 comprises the step, if a dissolving plug member 30 is used, providing dissolving fluid to dissolve same, or if a burstable plug 30 is used on the actuation member 25, providing uphole fluid pressure sufficient to burst the burst plug 30, so as to allow flow of oil into the interior bore 15 of the tubing liner 14.
Step 408 comprises the step of determining if all ports have been uncovered and fracked. If not, steps 401-407 are repeated, using another actuation member 25′ having a unique(different) profile is utilized to open a progressively more uphole port 16, and a sand screen 40 installed in the same manner in respect of such additional port 16.
If all ports 16 have been uncovered and fracked, and sand screens 40 inserted at each successively opened port 16, then as recited in step 409, oil is thereafter produced from the completed wellbore 12.
Other permutations and combinations of the above steps in the above method will now occur to persons of skill in the art, and are contemplated herein.
The foregoing description of the disclosed embodiments of the system and methods of the present invention are provided to enable any person skilled in the art to make or use the present invention. The scope of the claims should not be limited by the preferred embodiments set forth in the examples, but should be given the broadest interpretation consistent with the specification, including the description and drawings, as a whole. Thus, the present invention is not intended to be limited to the embodiments shown herein, but is to be accorded the full scope consistent with the claims.
For a complete definition of the invention and its intended scope, reference is to be made to the summary of the invention and the appended claims read together with and considered with the disclosure and drawings herein.
This application is a divisional of U.S. patent application Ser. No. 17/202,211 filed on Mar. 15, 2021.
Number | Name | Date | Kind |
---|---|---|---|
9976394 | Campbell et al. | May 2018 | B1 |
10648285 | Gaudette et al. | May 2020 | B2 |
20140034308 | Holderman | Feb 2014 | A1 |
20160108711 | Lynk | Apr 2016 | A1 |
20180320488 | Campbell et al. | Nov 2018 | A1 |
20190353005 | Gaudette et al. | Nov 2019 | A1 |
Number | Date | Country |
---|---|---|
2899990 | Oct 2014 | CA |
3057652 | Jun 2019 | CA |
Number | Date | Country | |
---|---|---|---|
20220290546 A1 | Sep 2022 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 17202211 | Mar 2021 | US |
Child | 17737780 | US |