The present invention is a tandem releasable bridge plug system and a method for setting such tandem releasable bridge plugs in a casing.
Retrievable bridge plugs or “RBP” are well known in the well service industry. A single retrievable bridge plug carried on a drill pipe string may be set by the following actions:
In the prior art presented in U.S. Pat. No. 9,279,307, two consecutive plugs in a well are removed in one run. However the US patent is not enabled to set two plugs in one run. The plug of the prior art has no through bore, and a special axially arranged release tool is required below the upper plug, and this is required before setting.
In the prior art U.S. Pat. No. 4,928,762 to Mamke, “Retrievable bridge plug and packer”, he discloses a lower, retrievable bridge plug and an above casing annular packer.
U.S. Pat. No. 5,020,597 to Braddick et al., “Arrangement and method for conducting substance and lock therefor” describes a cementing string for a liner, with upper and lower wiper plugs with external seals thereon, releasably connected to the operating string. A lock arrangement prevents premature release of the upper and lower wiper by mechanical force, but is responsive to fluid pressure to first release the lower wiper prior to release of the upper wiper.
US patent application published as US2004/0050546 relates to an arrangement of sequentially configured packer J tools for one trip sequential setting of packer tools and for subsequent one trip sequential release of the tools.
U.S. Pat. No. 2,806,532 provides an improved method and apparatus for straddling casing perforations and for applying high pressures safely to the locations surrounding the casing perforations.
U.S. Pat. No. 4,794,989 discloses an apparatus for use in completing oil or gas wells having two or more perforated production zones which includes packers and assemblies for closing off the annular space between the tubing string and the well bore intermediate adjacent zones to isolate one from the other in order to produce from each individually.
US patent application published as US2004/0251024 describes a method for performing single trip perforation and packing operations via a downhole assembly in a cased well bore. The assembly is provided with an upper packer and a lower packer and has fluid communication established therethrough. The upper packer of the assembly is set to isolate a perforated production zone by introducing pressurized fluid through the assembly and against the casing below the lower packer of the assembly.
International patent application publication WO2014/0044843A2 Lipp, Interwell AS, describes a toolstring comprising a first and a second downhole tool, more specifically, an upper and a lower plug. The tool described in Lipp is a wireline bridge plug without any central bore. It is thus not designed for pressure testing the plug with regard to sealed-in pressure from below the plug. The dual plug tool is described as being able to set the first plug at a first location and the second plug in a second location, in one single run. The second plug is movable with the toolstring from the first location to the second location between setting the first plug and setting the second plug. The wireline bridge plugs of Interwell require electrical control signals via the wireline and Lipp provides no mechanism for distinguishing between a control signal for the upper plug from the control signal for the lower plug. Lipp suggests in p. 17, line 26-32 that test operations may be performed with the plug set and the toolstring detached, and subjecting the seal of the plug to a pressure test. Then the toolstring may be re-attached to the plug and pulled uphole. Such an operation would be undesirable, particularly for a wireline tool, due to the lack of knowledge of the pressure conditions below the plug to be pulled.
A problem in the drill pipe string operated bridge plug industry, since the lower plug is set by manipulating the drill pipe string movements through rotational left hand (RL) or rotational right hand (RH), and/or axial movements up or down, and if combining two similarly operated plugs, one may hardly control upon manipulating the drill pipe string rotationally and axially, which plug does what. One solution may be to design the plugs with mutually excluding different setting and releasing mechanisms but this requires much special preparation of each tool and a large stock of tools with separate setting and release mechanisms. The result, in practice, is that one may only set one plug on one drill pipe string at a time, requiring a second run for setting the second plug. So setting the plug may take twice the time compared to removing them.
Another problem arises if, during a drilling operation, an emergency situation develops and it may be decided to prepare for hanging off part of the drill pipe string in a bridge plug in the well, such as due to bad weather forecast. If time is sufficient, it is desirable to pull out as much drill pipe string as required, insert a hang-off bridge plug in the drill pipe string, and run into hole the hang-off bridge plug on the drill pipe string, and then set and close the hang-off bridge plug at a desired depth, carrying below it the remainder of the drill string. Then the drill string is disconnected from the hang-off bridge plug, and the drill string pulled out. The wellhead valves may now be temporarily closed. Further, it may subsequently be prepared for disconnecting the drilling casing without risk of petroleum fluid leakage.
In such the prior art with setting there is usually only time for setting the single hang-off bridge plug and there is thus no double barrier of bridge plugs within the casing. It would be desirable to run in a second and shallower set upper bridge plug in order to form the second barrier within the casing, disconnecting the above drill pipe string from the upper plug, and pulling out the drill pipe string and prepare for disconnect from the well. However such a second, upper bridge plug is time consuming and there may not be sufficient time for such a second bridge plug setting if the weather or sea state conditions worsen fast.
Another problem arises if the lower bridge plug must be set deep in a well, and an upper bridge plug must be set relatively shallow, then the distance from the lower bridge plug to the upper bridge plug is long. The time it takes to pull out the drill pipe string after having disconnected from the lower bridge plug may be unacceptably long, and time may be short for setting the second, upper bridge plug if the weather or sea state conditions worsen fast.
It is possible to arrange two bridge plugs on a common drill pipe string and set the first one in a first depth and the second one in a second depth, but this would require different setting and disconnecting mechanisms for the lower and upper bridge plug, respectively, in order not to set and disconnect from the upper plug while trying to set and disconnect from the lower plug.
A further problem arises if, using two plugs for searching and locating of a casing string leakage. One may run a lower plug on a first drill pipe string and then locate the lower bound of the leak, then run an upper plug on a second drill pipe string to locate the upper bound of the leak, and thus locate the location of the leak. Such a leak may be in a casing string of continuous even diameter, or it may be in a transition from one casing diameter to a liner diameter, i.e. for testing a liner hanger seal. The operation is time consuming due to the running in of plugs on two separate drill pipe strings.
A main object of the present invention is to disclose a tandem releasable bridge plug system and a method for setting such tandem releasable bridge plugs. The method for setting the releasable bridge plugs is defined as follows:
A method of setting a tandem releasable bridge plug system in a casing (0), characterized by the steps of:
The plug system used in the above method is a tandem releasable bridge plug system arranged for setting in a casing (0),
The attached figures illustrate some embodiments of the claimed invention.
The invention will in the following be described and embodiments of the invention will be explained with reference to the accompanying drawings.
The invention is a method of setting a tandem releasable bridge plug system in a casing (0). The method comprises, the steps of:
After the above steps one may pull out the drill pipe string (4) from the well, depending on the subsequent operation to be made on the well.
The disconnectable connectors (2U, 2L) are both usually named “running and retrieving tool” of which an upper sleeve portion, please see
The setting of the upper plug's (1U) slips (14U) and packer (16U) is facilitated as follows:
Upper Plug General Structure
In an embodiment of the invention, the upper plug comprises from bottom to top, a drag block section with upper drag blocks (12U) and a lateral aperture (17U), a set of slips (14U) here named “upper” slips (14U), a set of packers (16U) hereafter named “upper” packers (16U), a ball valve section (18′U) with an “upper” ball valve element (18U), a stinger (2U1) with J-slot dogs arranged for connecting to an upper connector (2U) with J-slots, also called a “running tool”, the upper connector mounted at the lower end of a drill pipe string (4) for running in the upper plug (1U) and the lower plug (1L) into the well. In an embodiment of the invention the upper plug has the lock (5) initially disabling the slips and packer functions of the upper plug (1U) except for its drag blocks, so as for initially making it to operatively appear as a drill pipe string section, thus enabling normal operations on the lower plug (1L).
In an embodiment of the invention, the upper plug's (1U) mandrel (11U) has an axial through-bore (19U), and is provided with an outer drag block barrel (121U) which is arranged for, when not prevented by anti-rotation pins (55P), to rotate about the mandrel (11U) when the upper plug (1U) with its connector (2U) has been activated. On its surface, the drag block barrel (121U) is provided with drag blocks (12U) which are spring loaded to drag on the inner wall (0i) of a surrounding casing pipe (0) forming part of the well. Those drag blocks (12U) are always engaged in friction against the surrounding wall. When activated, i.e. when the anti-rotation pins (55P) do not lock the drag block barrel (121U) to the mandrel (11U), the mandrel may be screwed right-hand (RH) downwardly in the drag block barrel (121U). In an embodiment of the invention, weight is then put on the drill pipe string (4) including the mandrel (11U), thus the drag block barrel (121U) is forced upward relative to the mandrel (11U) so as for an above arranged slip wedge (141U) to wedge force out the slips (14U), which further leads to compression of said further above upper packers (16U). The setting mechanism is releasable so as for allowing resetting or retrieval of the plug (1U).
Ratchet Block/Ratchet Lock Mechanism
According to an embodiment of the invention, internally, the drag block barrel (121U) has an inward facing annular pocket for holding spring-loaded ratchet blocks (122U) with threads arranged for running on a composite thread portion (123U) of the mandrel (11U), the composite thread portion comprising an upper, left-hand thread portion (123UUL), an intermediate blank section (123UIB), and a lower right-hand threaded portion (123ULR), so as for enabling axial movement of the mandrel (11U) relative to the drag block barrel (121U).
In an embodiment of the invention, the lower, right-hand threaded portion (123ULR) has a larger diameter than the upper, left-hand threaded portion (123UUL). Similarly, the ratchet blocks (122U) have a larger diameter in a lower portion for engaging the lower, right-hand threaded portion (123ULR) and a smaller diameter at an upper portion for engaging the upper, left-hand threaded portion (123UUL).
In an embodiment of the invention, the upper plug (1U) is run into the well with its ratchet blocks (122U) engaged on the lower, right-hand threaded portion (123ULR) so as for the upper slips (14U) and upper packers (16U) to be locked in their un-engaging position, i.e. prevented from leaving their retracted positions. Thus one may rotate the drill pipe string (4) and the mandrel (11U) a number of right-hand (RH) turns in order to screw the lower, right-hand threaded portion (123ULR) down through the wider portion of the ratchet blocks (122U), until the intermediate, smooth, thread-free portion (123UIB) is allowed to slip-pass through the ratchet blocks (122U). This may be arranged to require 5 to 12 turns RH. From then, one may lay weight onto the drill pipe string (4) thus the mandrel (11U) with its upper, left hand (LH) threaded portion (123UUL) may ratchet downwardly for a distance into the ratchet blocks (122U). This will lead to engagement of the slips (14U) and the packers against the casing wall (0i).
In an embodiment of the invention, turning the mandrel (11U) left (LH) will further tighten the grip of the slips and the packer.
In an embodiment of the invention, the turning of the mandrel (11U) left-hand (LH) will close the ball valve (18U). The right-hand turning described for activating the slips and packer above will not affect the already open ball valve (18U).
Upper Ball Valve Section
In an embodiment of the invention, the upper ball valve (18U) is preferably open during running in of the upper plug (1U)/lower plug (1L). The upper ball valve section (18′U) is kept in a passive state when running in so as for the upper ball valve (18U) not to be inadvertently shut due to possible left hand (LH) rotation during running in. Further, the upper ball valve (18U) shall be arranged also not be affected while the lower plug (1L) is manipulated through axial movements and rotational movements made by the drill pipe string (4). In an embodiment of the invention, the upper stinger (2U1) connected and initially locked by the lock (5) in the connector (2U) and arranged on top of the upper ball valve section (18′U), i.e. the ball valve section of the upper plug (1U), is connected to an upper barrel (185UU) with a clutch (184U) to a lower barrel (185UL) which holds the upper ball valve element (18U), please see
In the embodiment of the invention, the upper ball valve section (18U) thus has have a delayed-activation mechanism which enables the ball valve (18U) to be left-hand (LH) rotated to a closing position in the main bore (19U) after the packer (16U) has been set. This mechanism involves an initial anti-rotation mechanism activated by a sleeve further activated by the axially contracted connection between the stinger (2U1) at the top of the ball valve section (18U′) and the upper connector sleeve (2U). In order to close the upper ball valve (18U), one must engage the upper ball valve (18U) mechanism, and turning left for a half turn will close the upper ball valve (18U). In order to open the upper ball valve (18U), one may turn the mandrel right-hand (RH), one half turn.
In an embodiment of the invention, the lower ball valve section (18′L), please see
Lower Bridge Plug:
In an embodiment of the invention the Lower plug (1L) is rather similar to the upper plug (1U) with the significant differences that it has no anti-rotation pins (55) preventing relative rotation of its mandrel (11L) relative to its drag block barrel (121L), no lock (5), no disabling clutch mechanism preventing shutting the lower ball valve element (18L) by left-hand rotation and axial load. The mechanism for enabling the lower plug's (1L) slips (14L), and its lower packers (16L) thus involves right hand (RH) rotation of the mandrel (11L) in the lower drag block (12L) barrel (121L) to activate the slips (14L), down weight to ratchet the mandrel (11L) downwardly in the barrel (121L) to engage and set the lower slips (14L) and lower packer (16L). Left-hand rotation will close lower ball valve element (18L), and right hand rotation of the mandrel (121L) to open lower ball valve (18L). Right hand (RH) rotation to release the lower slips (14L) and packer (16L) and then pull to ratchet the mandrel (11L) to its parked state and thus release the lower plug (1L) fully.
Ratchet Block/Ratchet Lock Mechanism
In an embodiment of the invention, internally, the drag block barrel (121U) has an inward facing annular pocket for holding spring-loaded ratchet blocks (122U) with threads arranged for running on a composite thread portion (123U) of the mandrel (11U), the composite thread portion comprising an upper, left-hand thread portion (123UUL), an intermediate blank section (123UIB), and a lower right-hand threaded portion (123ULR), please see
In an embodiment of the invention, the lower, right-hand threaded portion (123ULR) has a larger diameter than the upper, left-hand threaded portion (123UUL). Similarly, the ratchet blocks (122U) have a larger diameter in a lower portion for engaging the lower, right-hand threaded portion (123ULR) and a smaller diameter at an upper portion for engaging the upper, left-hand threaded portion (123UUL).
In an embodiment of the invention, the upper plug (1U) is run into the well with its ratchet blocks (122U) engaged on the lower, right-hand threaded portion (123ULR) so as for the upper slips (14U) and upper packers (16U) initially to be locked passive, i.e. prevented from leaving their retracted positions. Thus one may rotate the drill pipe string (4) and the mandrel (11U) a number of right-hand (RH) turns in order to screw the lower, right-hand threaded portion (123ULR) down through the wider portion of the ratchet blocks (122U), until the intermediate, smooth, thread-free portion (123UIB) is allowed to slip-pass through the ratchet blocks (122U). This may be arranged to require five to twelve turns RH. From then, one may lay weight onto the drill pipe string (4) thus the mandrel (11U) with its upper, left hand (LH) threaded portion (123UUL) may ratchet downwardly for a distance into the ratchet blocks (122U). This will lead to engagement of the slips (14U) and the packers against the casing wall (0i). Turning the mandrel (11U) left (LH) will further tighten the grip of the slips and the packer.
The Radial Aperture
A problem may arise upon reconnecting the drill pipe string (4) extending from topsides via the upper connector (2U) to the upper bridge plug (1U) in its closed state, if the upper bridge plug (1U) is connected to an intermediate drill pipe string (3) extending below the upper bridge plug (1U). Upon having reconnected to the upper plug (1U) the upper ball valve (18U) in the upper plug's (1U) bore (19U), one may test for the pressure below the upper plug (1U). Due to influx of fluids (liquids and gases), pressure may have built up in the intermediate zone below the upper plug (1U) and above the lower plug (1L) during the time when they both have been closed, a period which may have lasted for a few hours, but which may be a period of several months in some applications for which the present plug have been tested. Gas may have accumulated. Opening the upper ball valve (18U) will allow measuring the pressure below the upper plug (1U), and also be enabled to detect the presence of gas in the intermediate drill pipe string (3), but one will not know whether gas has accumulated in the annulus (3A) about the intermediate drill pipe string (3). Such undetected gas may incur problems when releasing the upper packer (16U) and releasing gas unnoticed up into the annulus about the drill pipe string (4), before and when releasing the upper plug (1U) slips (14U), said gas then migrating up past the upper packer (16U) which may create an undesired gas present in the casing of the upper part of the well.
The problem of possible annular gas below the upper packer (16U) and about the intermediate drill pipe string (3) is remedied in an embodiment of the invention wherein a radial aperture (17U) orthogonally into the axial bore (19U) of the upper mandrel (11U) of the upper plug (1U). Gas drained out through the drill pipe string (4) is easier to control. The radial aperture (17U) is initially covered by the drag block (18U) barrel (181U) when running the upper plug (1U) into the well, and an annular seal (17s) arranged internally and near the lower end of the drag block barrel (121U), seals the radial aperture (17U) when closed. When the upper plug's (1U) radial aperture (17U) shall be opened, the drill pipe string (4) rotates the mandrel (11U) a number of right hand (RH) turns within the threaded blocks ( ) of the drag block barrel (181U) until the radial aperture (17U) is uncovered below the seal (17S). The open radial aperture (17U) then allows communication between the annulus of the lower plug below the packer (16U) and the axial bore (19U). In this way, the radial aperture (17U) from the upper axial bore (19U) to its annulus is opened to allow gas present in the annulus to balance itself into the axial bore (19U) and the bore of the upper part of the intermediate drill pipe string (3), when the upper packer (16U) is set, and it will remain open as long as the upper packer (16U) is set.
Please notice that in the initial state, also the radial aperture (17U) of the mandrel (11U) is closed because the portion of the mandrel (11U) in which it is made, is initially retracted into the drag block barrel (121U), and will only be uncovered when a number of right hand (RH) turns are made using the drill pipe string (4). This closed radial aperture (17U) and the otherwise locked and disabled state of the upper plug (1U) means that to the surface operator, he may communicate via drill pipe string pressure with the lower tool (1L) in order to set using the drill pipe string (4, 3) and conduct a pressure test through the drill pipe string (4, 3) of the lower tool (1L) from below. It is undesirable to leave the radial aperture (17U) open after having re-connected the upper connector (2U) to the upper plug (1U) and released the upper plug (1U) and then connecting to the lower plug (1L), because then one could not conduct a re-entry pressure-from-below test of the lower plug (14 the radial aperture (17U) would have to be closed in order to have a through-drill pipe string connection through the lower, opened plug (1U).
Releasing the Upper Plug
In an embodiment of the invention, in order to open the upper ball valve (18U), one may turn the mandrel right-hand (RH), one half turn. In order to release the upper packer (18U) and upper slips (14U), one may make a required number of right hand (RH) turns in order to unscrew the LH threaded portion (123UUL) back up through the ratchet blocks, and, when free of the upper thread portion, pull up the drill pipe string (4) thus the mandrel (121U) to ratchet onto the lower set of right-hand threads (123ULR), thus preventing later undesired setting of the upper packer (18U) and upper slips (14U). The upper plug (1U) may then be pulled out of hole or pulled to another depth to be set.
In an embodiment of the invention, the length of the upper threaded portion of the ratchet blocks (122U) is a little bit shorter than the length of the blank portion (123UIB).
In an embodiment of the invention, the ratchet blocks' (122U) lower threaded portion has threads cut inclined to enable being ratched downwardly on the lower threaded portion (123ULR), but not upwardly. For the ratchet blocks' (122U) upper threads it is oppositely inclined cut so as for enable being ratched upwardly on the upper threaded portion (123UUL) of the mandrel (11U).
A big issue is how to set the lower bridge plug (1L) without setting or releasing the similarly operated upper bridge plug (1U), then release the upper bridge plug (1U) from the lower bridge plug (1L), and first now enabling the mechanism for initiating and conducting setting and release of the upper bridge plug (1U). In this way the tandem plugs (1L, 1U) may be set on one and the same run.
Lower Plug Repositioning Possible:
Before the upper plug (1U) is enabled, the lower plug (1L), if set improperly and a leakage is detected, it may be right-hand screwed and may be repositioned, then reset and tested, until its operational required slip holding force and sealing property is met. After the upper plug (1U) is enabled, the lower plug (1L) may thereafter in practice only be released and retrieved, together with the upper plug (1U). We therefore do not show the release sequence because it is understandable as an inverse sequence when the setting sequence herein is explained.
Initially Disabled Upper Plug:
The initially disabled upper bridge plug (1U) and its disconnectable connector (2U) are initially, before and during run-in and setting of the lower bridge plug (1L), temporarily disabled from being settable by any rotational and axial movements by the lock (5). In effect, except for the drag blocks (12) of the upper bridge plug (1U), it just forms another passive part of the drill pipe string (4) as seen from the lower bridge plug. Thus the deck crew may control the lower bridge plug (1U) as if it were the only bridge plug on the drill pipe string (4).
The upper ball seat sleeve (53) locks the spline sleeve (52) (mounted on the stinger (2U1)) and prevents the spline sleeve (53) and the outward facing spline dogs of the spline sleeve (52) from passing the restriction (2Ui) in the upper connector (2U), thus preventing the upper stinger (2U1) from being pushed upwardly into the upper connector (1U). Thus the J-slot mechanism, is rigid in its locked state, it may not be disconnected from the stinger, the ball valve (18U) mechanism may not be activated, the drag block barrel (121U) is not free to rotate relative to the mandrel (11U), and the upper plug (1U) is temporarily entirely disabled.
The problem of possible annular gas below the upper packer (16U) and about the intermediate drill pipe string (3) is remedied in an embodiment of the invention wherein a radial aperture (17U) in the axial bore (19U) upper stem (11U) belonging to the upper plug (1U) is covered by the drag block (18U) barrel (121U) and then being closed, and wherein the upper stem (11U) with the radial aperture (17U) is screwed downwardly when rotating the stem (11U) in the drag block barrel (121U). In this way, the radial aperture (17U) from the upper axial bore (19U) to its annulus is opened to allow gas present in the annulus to balance itself into the axial bore (19U) and the bore of the upper part of the intermediate drill pipe string (3).
Ball Seat Lock Details:
In an embodiment of the invention, the initial disabling of the upper bridge plug (1U) is made by a ball seat axial sleeve (52) arranged in a collet sleeve (53) constituting the lock (5) of the connector (2U), please see
Ball Catcher:
In an embodiment of the invention the ball (51) and the ball seat axial sleeve, hereafter called the first ball sleeve (52), may be transported by the pressure through the central bore and be caught in a ball catcher (31) at the lower end of the upper retrievable bridge plug (1U). It is undesirable that the ball and sleeve shall drop freely into the casing below the upper plug (1U) as it could interfere with the lower plug (1L) on attempting reconnecting for retrieval and also create other problems. The relative shear pressure of the first seat sleeve (52) is in an embodiment set to 69 Bar (1000 psi).
When the upper connector (2U) is enabled to be collapsed onto the stinger (2U1) of the upper plug (1U), an upper plug (1U) initiation and setting sequence may be activated.
Second Shear Seat, Anti-Rotation Pins:
In an embodiment of the invention the released downward running seat sleeve (52) will bring along with it a second shear sleeve (55), please see in the central bore (19U) between the drag block unit and the slip unit (14) in
Initially, for running into the well and before the lower plug (1L) is set and disconnected from the lower connector (2L), the upper drag block barrel (121U) is arranged non-rotatable relative to the mandrel (11U). In an embodiment of the invention, The anti-rotation lock is temporary and comprises spring-loaded pins (55P) which are held in engaged positions engaging the barrel (121U) with the mandrel (11U). The spring-loaded pins (55P) are held in the engaging position by a cylindrical sleeve (55) initially held by shear pins (55s) and which may be axially displaced downwardly by a ball or preferably by the above arranged cylindrical locking sleeve (5, 52) when that one is released by the ball (51) so as for releasing the anti-rotation pins (55P). Then the drag block (121U) barrel may be static, non-rotating in the surrounding casing due to the friction blocks (12U), while the mandrel (11U) is rotatable by the drill pipe string (4).
In an embodiment of the invention, after enabling the upper connector (2U), it is enabled for axially collapsing the upper connector (2U) and the upper stinger (2U1), please see
Intermediate Drill Pipe String:
In the above, the lower and upper plugs (2L, 2U) are connected and are separated by any distance, at minimum only separated by the lower connector (2L). In an embodiment of the invention, it is advantageous to use an intermediate drill pipe string (3) below the upper plug (1U) and the lower connector (2L) on the lower plug (1L). The length of the intermediate drill pipe string (3) should only be limited to an embodiment of the invention wherein it corresponds to have a length slightly less than the distance between the lower target depth (dL) for the lower plug (1L) and the upper target depth (dU) for the upper plug (2U). This in order for allowing disconnecting from the lower plug (1L) before placing and setting the upper plug (1U). If they were still mechanically connected one could not rotate and move the upper drill pipe string (4) from topsides without affecting the lower plug (1L). A significant advantage of having an intermediate string (3) length of almost the depth difference between lower and upper target depths (dL, dU) becomes evident if the target depth difference is large: Given a lower target depth (dL) of, say 5000 m, and upper target depth (dU) of 1000 m, one would then have to run in lower plug (1L), then 4000 m of intermediate string (3), then upper plug (1U), and 1000 m of drill pipe string (4), in order to reach lower target depth. It would then be an operational advantage that when lower plug (1L) is set, the lower disconnectable connector (2L) is released, then the upper plug (1U) is near below its upper target depth (dU) and is rapidly set upon pulling out a short distance, and then after testing one may pull out the relatively short, here 1000 m of drill pipe string (4) only. Thus the two purely setting operations are conducted consecutively. Those are embodiments of the invention and may be varied with respect to relative lengths.
Free Upper Plug:
In an embodiment of the invention, the upper plug (1U) with its below mounted intermediate drill pipe string (3) is released from the lower plug (1L), and the upper plug (1U) may be enabled, not earlier. After the upper plug is enabled and also released from the lower plug (1L), any drill pipe string manipulation with rotation or axial movement, will not affect the lower plug. The upper plug may now be set and pressure tested, and if necessary, released and repositioned for further testing until satisfactory, and then disconnected.
Ball Catcher:
In an embodiment of the invention, there is arranged a ball and seat catcher (31) below the upper plug (1U) and above the lower connector (2L).
Testing Lower Plug from Below:
In an embodiment of the invention, after setting and before shutting the lower plug (1U), setting its packer (16), and then conduct pressure integrity testing the sealing effect of the lower plug's (1L) packer (16) from below by pressurizing the drill pipe string (4) topsides.
Testing Lower Plug from Above:
In a further embodiment of the above, after shutting the lower plug (1L) and disconnecting from the lower plug, conducting pressure integrity testing the lower plug (1L) from above.
Testing Upper Plug from Below:
In an embodiment of the invention, one may test the upper plug from below by after setting, before shutting the upper plug (1U), setting its packer (16), and then conduct pressure integrity testing for verifying the sealing effect of the upper plug's (1U) packer (16) from the casing space below but above the lower plug (1L) by pressurizing the drill pipe string (4) topsides.
Testing Upper Plug from Above:
Similar to above, in a further embodiment of the invention, one may test the pressure integrity of the upper plug from above by, after shutting the upper plug (1U) and disconnecting the drill pipe string (4), pressure integrity testing the upper plug (1U) from above.
If the casing to be plugged is of even diameter the upper and lower plugs (1U, 1L) are of the same diameter. In an embodiment the lower plug (1L) may be of a lower diameter than the upper plug (1U), e.g. if the lower plug (1L) shall be set in a liner below a liner hanger in a casing.
The radial aperture (17U) is kept closed during run in of upper and lower plugs (1U, 1L), setting the lower plug (1L), and pressure testing the lower plug through the drill pipe string (4, 3) from below.
The radial aperture (17U) is opened through the right-hand rotations of the mandrel (11U) described above, before setting the slips and packer (14U, 16U) of the upper plug (1U), in order to balance accumulating gas between the intermediate drill pipe string (3) and its annulus when the packer (16U) is set.
The radial aperture (17U) is closed when releasing the slips and packer (14U, 16U) so as for enabling pressurizing the intermediate drill pipe string (3) after having reconnected to the lower plug (1L) thus pressurizing the lower plug's ball valve (18L) from above before opening it. This will also enable the operator to bleeding off gas accumulated below the lower plug (1L), bleeding off gas through the intermediate drill pipe string (3) and the drill pipe string (4), providing better well control. This will prevent gas accumulation in the annulus about the drill pipe string (4).
In the above, what is called “an upper plug (1U)” with all the features belonging to the upper plug as described above, may be used alone, or used with another tool hanging below it, such as a drill string with a drilling bit, or another tool. We may thus say that an alternative definition of the invention is:
a releasable bridge plug arranged for setting in a casing (0),
A first problem of setting two plugs in one run is thus solved by the invention. This reduces the setting time for two plugs by about 50%. Time is costly both from an economical and a safety view; a drilling rig and particularly a marine drilling platform has high day rates. Time may be costly from a safety point of view if the two plugs are to be set fast in order to remedy an undesired state of the well. The invention has several further significant advantages.
Another problem, of not being able to set two plugs during a safety disconnect operation is solved by the invention. First, if the lower plug is set with the hang-off drill string below, then the most imperative problem is solved, the well is plugged by one plug, and one may leave the well in an emergency. If time allows, one may quickly set the upper plug as a backup to reduce the risk of blow out, and then disconnect and prepare to leave the well.
A further problem of not being able to conduct a single run pressure testing for leak location in a casing string is solved.
A further advantage of the invention is that accumulated gas in the annulus below the upper packer (16U) is vented into the central bore of the upper plug before releasing the upper packer. This is particularly useful if an extensive string of intermediate drill pipe string sections (3) are arranged extending below the upper plug and extending down to the lower connector (2L); this gas would otherwise be vented out in the drill pipe string (4) annulus above the upper packer (4) when releasing the packer, which would be undesirable.
Number | Date | Country | Kind |
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20180368 | Mar 2018 | NO | national |
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WO 20140044843 | Mar 2014 | WO |
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20190284898 A1 | Sep 2019 | US |