POSITIVE DISPLACEMENT DUMP BAILER
A system and method for injecting bailer content utilizing a dump bailer having an elongated, flexible bailer receptacle secured between a head assembly and an injection assembly. Disposed within the dump bailer are first and second piston assemblies, each of which includes a piston having a central fluid passage with a pressure actuated flow control mechanism in the form of a rupture disk disposed along the fluid passage of the piston. An electric, positive displacement pump within the head assembly draws wellbore fluid into the dump bailer assembly to drive the first piston assembly towards the second piston assembly so as to release bailer content into a wellbore. The elongated flexible bailer receptacle may be a hose stored on a bailer receptacle reel, which hose may be paid out by the reel to a length that corresponds with a volume of bailer content to be released into the wellbore.
This invention relates, in general, to equipment utilized in conjunction with operations performed in a subterranean well and, in particular, to a positive displacement dump bailer and a method of operating the positive displacement dump bailer.
BACKGROUND OF THE INVENTIONA dump bailer is a wellbore tool use to deposit bailer content in the form of a fluid or material, typically cement slurry, in a wellbore. Dump bailers are typically lowered into the wellbore on a conveyance vehicle such as wireline, a slickline, coiled tubing or the like. For example, a dump bailer can be used to deposit cement slurry onto a mechanical plug or packer in the wellbore. More specifically, a dump bailer can be utilized to isolate pressure between two regions in a well by deploying a cement plug. In certain installations, this is accomplished by first installing a mechanical plug, packer or bridge plug in a well at the desired location of the cement plug base and then lowering a dump bailer carrying a cement slurry into the casing on a conveyance vehicle.
Once the dump bailer is positioned in the desired location proximate the mechanical plug, the dump bailer is actuated to release the cement slurry. The cement slurry is deposited on a platform formed by the mechanical plug and is supported by this plug during curing. Other means of temporary cement plug support can also be applied.
In one type of dump bailer, gravity is used to dispense the cement slurry from the dump bailer. The bailer may be spring loaded. In another type of dump bailer, explosive components are used to generate pressure to urge the cement slurry from the dump bailer. In a further type of dump bailer, a drive motor rotates a screw to dispense the cement slurry from the dump bailer.
Current dump bailers either have a limitation on maximum practical length or they rely on free fall of the bailer content into the wellbore below. This may limit the volume of content that can be released in one run. Moreover, this can render the effectiveness of the bailer sensitive to gel strength and viscosity, such that a dump bailer may not properly drain all of its content, particularly if the wellbore is oriented at a high inclination. Further, in such dump bailers, there is no control of the drain rate recognizing that too rapid of a drain rate causes turbulence and intermixing with brine or water in the wellbore, which can impact the properties of the bailer content due to dilution and loss of viscosity. In this regard, currently, long cement plugs require multiple dumps, extending the time of the overall cementing operation and creating new dilution potential for each dump such that the final cement plug is not homogenous since the cement of each dump may have different curing times.
For a more complete understanding of the features and advantages of the present invention, reference is now made to the detailed description of the invention along with the accompanying figures in which corresponding numerals in the different figures refer to corresponding parts and in which:
Disclosed herein is a dump bailer for releasing fluids into a wellbore. The dump bailer includes a tool body having a first end, a second end and an exterior surface. Formed within the tool body is an elongated bailer receptacle having a cavity formed therein and extending from a first cavity end to a second cavity end. A piston assembly having a first piston with a first surface and an opposing second surface and an outer perimeter may be slidably disposable within the cavity and movable between the first cavity end and the second cavity end. Bailer content, such as a liquid or slurry, is disposed in the cavity between the first piston and the second cavity end. In one or more embodiments, an electric pump is carried by the tool body and is disposed along a fluid passage extending from the exterior surface of the tool body to the first cavity end, thereby permitting wellbore fluid to be pumped to the into the cavity to pressurize the first side of the piston and drive the piston from the first cavity end to the second cavity end so as to release the bailer content from the cavity. In one or more embodiments, the first piston includes a piston fluid passage extending between the first and second piston surfaces with a rupture disk disposed along the piston fluid passage. In one or more embodiments, the piston assembly also includes a second piston disposed in the cavity between the first piston and the second cavity end. The second piston may include a piston fluid passage and a rupture disk similar to the first piston. In these embodiments, the second piston rupture disk may have a lower rupture pressure than the first piston rupture disk. In one or more embodiments, the dump bailer may include a vibrator carried by the tool body. The vibrator may be positioned adjacent the first end or the second end of the cavity to improve release of the bailer content, and improve placement of the bailer content into the potentially complex geometry of the wellbore. The vibrator may be electric or hydraulic. In one or more embodiments, the tool body may include a head assembly at the first end of the tool body and an injection assembly at the second end of the tool body. The elongated bailer receptacle may be bendable. The cavity formed within the bendable receptacle fluidically connects the head assembly and the injection assembly. The head assembly and the injection assembly may each be formed of a rigid mandrel and the bendable elongated bailer receptacle may be formed of a flexible hose, bendable tubing or the like. In these embodiments, a hose reel and hose feeder may be provided as a deployment system for transportation and/or feeding the bendable receptacle of the bailer into the wellbore. In one or more embodiments, an engagement mechanism may be provided at the second end of the tool body and disposed to engage a sealing assembly disposed within the wellbore. In one or more embodiments, two flow passages may be provided at the second end of the tool body, each flow passage extending from the second end of the tool body and in fluid communication with the cavity, where one flow passage has a one-way valve permitting flow from the second end of the tool body into the cavity and one flow passage has a one-way valve permitting flow from the cavity to the second end of the tool body. Centralizers, potentially equipped with friction reducing devices such as rollers, or friction reducing devices such as rollers without centralizers may be carried along the exterior surface of the tool body to facilitate deployment in wellbores of high inclination. Likewise, a pressure collar may be provided along the exterior surface of the tool body to permit pump down of the dump bailer in the wellbore.
Referring initially to
A tubing string 30 extends from wellhead 32 into casing 24 to provide a conduit for production fluids to travel to the surface. A sealing assembly 34, such as a packer, provides a fluid seal between tubing string 30 and casing 24 and directs the flow of production fluids from formation 14 to the interior of tubing string 30. A through tubing bridge plug 36 has been previously installed in casing 24 below tubing string 30 as a first step in plugging wellbore 22. Extending from the surface within tubing string 30 is a conveyance mechanism 38, such as a slickline, wireline, cable, coiled tubing or the like, used to convey a dump bailer assembly 40 into wellbore 22.
The dump bailer assembly 40 is generally formed of a tool body 42 which includes a bailer receptacle 44 into which bailer content (not shown) can be charged for release into wellbore 22. Without limiting the disclosure, such bailer content may include fluids, such as cement slurries or treatment chemicals, or solids, such as sand. For purposes of illustration, the bailer content will be described as a cement slurry. In any event, in one or more embodiments, an electric pump 46 is also carried by the tool body 42. As will be described in more detail below, the electric pump 46 is utilized to pump fluid from wellbore 22 into receptacle 44 in order to displace the bailer content carried in receptacle 44. Where the bailer content is cement slurry, the energized electric pump 46 draws wellbore fluid into the dump bailer assembly 40 and introduces the wellbore fluid into the receptacle 44 under sufficient pressure to drive the cement slurry out of dump bailer assembly 40 and into casing 24. Even though dump bailer assembly 40 is described as dispensing a cement slurry into casing 24, it is to be understood by those skilled in the art that dump bailer assembly 40 could be alternatively be used to dispense other wellbore agents including, but not limited to, acids, sands or the like.
Power may be supplied to electric pump 46 either locally by a battery or similar power storage device (not shown), or by an electrical cable forming part of conveyance mechanism 38 extending from rig 12.
Although pump 46 has been described as an electric pump, in other embodiments, pump 46 may be actuated hydraulically or by other drive mechanisms. For example, where pump 46 is a hydraulic pump, a hydraulic line (not shown) may extend from rig 12. Likewise, pump 46 is not limited to a particular type, but may include positive displacement pumps as well as dynamic pumps. Pump 46 may also be reversible.
Even though
One embodiment of dump bailer assembly 40 of
In the illustrated embodiment, the conveyance mechanism 80 for deployment of dump bailer assembly 60 is shown as a wireline attached to a conveyance adapter 82 attached to tool body 62 adjacent the first end 64. In another embodiment, conveyance mechanism may be a slickline, coiled tubing or other type of cable.
In one or more embodiments, a piston assembly 84 may be slidably disposable within the cavity 72 and movable between the first cavity end 74 and the second cavity end 76. The piston assembly 84 may include a piston 86 with a first surface 88 and an opposing second surface 90 and an outer perimeter 92. A piston flow passage 94 extends through piston 86 between the first surface 88 and the second surface 90. A flow control mechanism 96 is disposed along the piston flow passage 94. In one or more embodiments, flow control mechanism 96 is a rupture disk disposed to rupture at a first activation pressure P1. In other embodiments, flow control mechanisms 96 may be a valve disposed to open above the first activation pressure P1 and close below the first activation pressure P1. Piston assembly 84 may be initially carried within the head assembly 65 during deployment of dump bailer assembly 60. One or more seals 98 may be disposed around the outer perimeter 92 of the piston 86. In one or more embodiments, seal 98 may be a wiper. In this regard, in one or more embodiments, piston assembly 84 may be a wiper plug. In other embodiments, piston 86 may be rubber, metal, plastic, polymer or foamed version of said elements. Moreover, although piston 86 has been described as generally disk shaped, having opposing surfaces 88, 90 and an outer perimeter 92, in other embodiments, piston 86 may have other shapes, including without limitation, a plug, a ball, or a cylinder.
In one or more embodiments, head assembly 65 may include a valve 97 such as a relief valve or equalizing check valve, to permit pressure within the head assembly 65 to be equalized with pressure at the exterior surface 68 of tool body 62 in the case that the external pressure exceeds the cavity pressure, for example when the bailer assembly is lowered into the wellbore at increasing hydrostatic pressure. Check valve 97 may be utilized to ensure external pressure cannot significantly exceed internal pressure, such as for example in cases where injection assembly 67 does not have a equalizing valve (see valve 132b of
In one or more embodiments, injection assembly 67 may include a valve 95 such as a relief valve or equalizing check valve, often referred to as float valve, to permit wellbore fluid to enter into the cavity 72 under the piston 84 when the dump bailer assembly 60 is first lowered into the wellbore 22.
In one or more embodiments, injection assembly 67 may include an exit port 99 with a flow control mechanism 100 disposed to control flow through the exit port 99. In one embodiment, flow control mechanism 100 is a rupture disk disposed to rupture at a second activation pressure P2 selected to be less than the first activation pressure P1 of flow control mechanism 96 of piston assembly 84, such that flow control mechanism 100 actuates at a lower pressure than flow control mechanism 96. In other embodiments, flow control mechanisms 96 may be a valve disposed to open at a second activation pressure P2 less than the first activation pressure P1.
Injection assembly may also include an internal shoulder 102 on which the piston assembly 84 may land after traversing cavity 72. In one or more embodiments, the dump bailer assembly 60 may include a vibrator 104 carried by the tool body 62. Although the disclosure is not limited by the positioning in of vibrator 104, in one or more embodiments, vibrator 104 may be positioned adjacent the first end 64 or the second end 66 of tool body 62 to facilitate release of bailer content from bailer receptacle 70 and improve placement of the bailer content into the potentially complex geometry of the wellbore 22. In the illustrated embodiment, vibrator 104 is shown as part of head assembly 65. In other embodiments, vibrator 104 may be part of injection assembly 67. In such embodiments, vibrator 104 may be positioned adjacent flow control mechanism 100. Vibrator 104 is not limited to a particular type of vibrator so long as vibrator 104 can used energy waves to enhance flow of bailer content through or from dump bailer assembly 60. Thus, in one or more embodiments, vibrator 104 may be electric or hydraulic or sonic.
In one or more embodiments, the dump bailer assembly 60 may include a locator mechanism 106, such as a casing collar locator (“CCL”), carried by tool body 62. Although not limited to a particular position along tool body 62, in the illustrated embodiment, locator mechanism 106 is positioned adjacent the first end 64 of tool body 62 and forms part of head assembly 65. In any event, locator mechanism 106 is not limited to a particular device. In some embodiments, locator mechanism 106 may be an electric logging tool that detects the magnetic anomaly caused by the relatively high mass of the casing collar or other known casing features deployed at known measured depths along wellbore 22. As described below, in one or more embodiments, dump bailer assembly 60 may have a bailer receptacle 70 that makes if difficult to provide electric or hydraulic control to the injection assembly 67, such as where bailer receptacle 70 is a hose. Thus, in some embodiments, only head assembly 65 may include electric or hydraulically actuated components, such as an electric locator mechanism 106, an electrically actuated vibrator 104 or electric pump 78. In such case electric power (or hydraulic fluid, as the case may be), is provided to head assembly 65 by conveyance mechanism 80, which may include an electric cable and/or hydraulic line.
In one or more embodiments, bailer receptacle 70 may be formed of one or more lengths 108 of rigid cylindrical tube or pipe, which lengths may be interconnected at joints 109 (see
In
In either case, cavity 72 is charged with bailer content in the form a cement slurry between the piston 86 and the second cavity end 76 of cavity 72. To commence operation, pump 78 is actuated to pump wellbore fluid 61 from wellbore 22 into dump bailer assembly 60 and apply an internal bailer fluid pressure PIB to the first surface 88 of piston 86. As the fluid pressure PIB at first surface 88 continues to increase, the fluid pressure PIB of the pumped wellbore fluid 61 will push piston 86 towards second cavity end 76, such as is shown in
In any event, with flow control mechanism 100 actuated, the downward movement of the piston 86 urges the cement slurry out of dump bailer assembly 60 and dispenses the cement slurry into wellbore 22 and onto bridge plug 36 to form a cement plug 103. Cement plug 103 is allowed to cure on bridge plug 36. Following operation, dump bailer assembly 60 can be retrieved to the surface.
In some embodiments, the electrical signal to pump 78 can be adjusted to alter the flowrate of pump 78, which in turn can be used to control the flow rate of bailer content discharged from dump bailer assembly 60 through valve 100. This allows greater control over the injection flowrate of bailer content over prior art dump bailer assemblies.
Another embodiment of dump bailer assembly 40 of
Also positioned adjacent the first end 64 of the tool body 62, between the wireline adapter 82 and the pump 78 is a fluid head 112 in which is defined a fluid passage 114 extending from one or more ports 116 in the exterior surface 68 of the tool body 62 to a fill chamber 122 defined within a tubular portion 120 of head assembly 65. Pump 78 is positioned along fluid passage 114 and is disposed to draw wellbore fluid (see
In the illustrated embodiment, piston assembly 84a is shown carried in a tubular portion 120 of the head assembly 65. In particular, fluid passage 114 is in fluid communication with internal bore 69 of head assembly 65 which extends within tubular portion 120. Piston assembly 84a is positioned within internal bore 69. In this regard, the inner diameter D1 of internal bore 69 is selected to allow piston 86a of piston assembly 84a to translate along internal bore 69. In other embodiments, piston assembly 84a may be positioned in or adjacent the first cavity end 74 in bailer receptacle 70. In any event, piston assembly 84a is slidably disposed to translate from fill chamber 122, through cavity 72 between the first cavity end 74 and the second cavity end 76 to injection assembly 67. Thus, as with the inner diameter D1 of internal bore 69, the inner diameter D3 of cavity 72 is selected to allow piston 86a of piston assembly 84a to translate along cavity 72. As described above, piston assembly 84a may include a piston 86a with a first surface 88 and an opposing second surface 90 and an outer perimeter 92. In the illustrated embodiment of
In some embodiment, such as is illustrated in
As shown, first and second piston assemblies 84a, 84b are spaced apart from one another within tubular portion 120 of the head assembly 65 to define fill chamber 122 for initial receipt of bailer content (not shown). To facilitate filling, a fill port 123 that can selectively be opened and closed may be provided in tubular portion 120. In one or more embodiments, tubular portion 120 is a rigid mandrel forming part of head assembly 65. Tubular portion 120 is further characterized as having a first end 127 closest to adapter 82 and a second end 128 adjacent bailer receptacle 70, and, in some embodiments, may include an attachment mechanism 129 adjacent the second end 128 for securing bailer receptacle 70 to head assembly 65. In one or more embodiments, attachment mechanism 129 may be a collar. Second end 128 may also include a gripping area 131 for engagement by a dog collar or similar device (not shown) for temporarily securing dump bailer assembly 60 during preparation for deployment into wellbore 22, particularly where bailer receptacle 70 is a hose as described below. As such, it will be appreciated that gripping areas 131, and thus, the second end 128 of tubular portion 120, may be reinforced or have a greater wall thickness.
In one or more embodiments, injection assembly 67 shown in
Injection assembly 67 shown in
Internal bore 71 of injection assembly 67 is in fluid communication with a fluid passage 130 extending through injection assembly 67 to exit port 99 at second end 66 of tool body 62. A flow control valve 132 may be positioned along fluid passage 130 to control flow of bailer material out of cavity 72. Flow control valve 132 may be pressure actuated. Thus, unlike gravity type dump bailers of the prior art, the flow of bailer material out of dump bailer assembly 60 can be controlled. In many instances, it is desirable to meter the bailer material out at a flow rate that does not create turbulence with wellbore fluid in wellbore 22, which could negatively impact the injection operation. For example, turbulence that might be experience with an uncontrolled release of cement slurry into wellbore 22, such as is often the case with gravity type dump bailer assemblies of the prior art, can cause wellbore fluid to mix with the cement slurry and weaken a cement plug once cured or cause segregation due to insufficient viscosity or gel strength. In one or more embodiments, fluid passage 130 may include a first fluid passage 130a communicating with a first exit port 99a and a second fluid passage 130b communicating with a second exit port 99b. In these embodiments, first fluid passage 130a may include a one-way flow control valve 132a permitting flow from the cavity 72 to the second end 66 of the tool body 62, and second fluid passage 130b may include a one-way flow control valve 132b permitting flow from the second end 66 of the tool body 62 to cavity 72. In either case, as stated above, one-way flow control valve 132a, 132b may be pressure actuated such that the valve does not open until the fluid constrained by the valve reaches a threshold actuation pressure. In some embodiments where pump 78 is reversible, pump 78 may be utilized to purge wellbore fluid from cavity 72 between piston assembly 84 and the first cavity end 74, thereby creating a lower fluid pressure PIB on the first surface 88 of piston 86a. Wellbore fluid entering second fluid passage 130b though one-way flow control valve 132b can then drive piston assembly 84a from adjacent the second cavity end 76 back towards the first cavity end 74 of cavity 72. In one or more other embodiments, valve 132b may be utilized to release wellbore fluid into the lower end 76 of cavity 72 to purge wellbore fluid from the upper end 74 of cavity 72.
In one or more embodiments, injection assembly 67 shown in
Turning to
In
In
In embodiments of dump bailer assembly 110 having a filter assembly 118, such as is shown in
While dump bailer assembly 110 as described above may be deployed in a wellbore 22 and utilized to deliver bailer content 142 at any desired location within the well, in some embodiments, dump bailer assembly 110 may be disposed for engagement with a sealing assembly 154 disposed at a select location within wellbore 22, or any other suitable geometry present, thereby forming a dump bailer system 153 for injection of bailer content 142, such as cement slurry, into wellbore 22. In this regard, as mentioned above, in some embodiments, injection assembly 67 may include a stinger at exterior surface 126 (see
Likewise, sealing assembly 154 is not limited to a particular type of sealing assembly but may be any sealing assembly known to persons of ordinary skill in the art for sealing cased or uncased wellbores. In one or more embodiments, sealing assembly 154 is elastomeric and engages the walls 22′ of wellbore 22. In one or more embodiments, sealing assembly 154 is a packer. In one or more embodiments, sealing assembly 154 is a plug. In one or more embodiments, sealing assembly 154 includes a bore 158 formed therein. In any event, in one or more embodiments, a portion of injection assembly 67 seats within bore 158 of sealing assembly 154, allowing engagement mechanism 150 of dump bailer assembly 110 to engage engagement mechanism 152 of sealing assembly 154. In these embodiments, as dump bailer assembly 110 begins to release bailer content 142 into wellbore 22, the bailer content 142 is contained within a desired section 167 of wellbore 22 by sealing assembly 154. This may prevent wellbore fluid 61 outside of the desired section 167, such as the wellbore fluid 61 shown in
In
Also shown in this embodiment, guides 134 may be utilized to align injection assembly 67 as it seats within interior bore 158 of sealing assembly 154. Thus, as described above, in addition to assisting in moving dump bailer assembly 110 through wellbore 22 to a desired location, guides 134 may also function as part of dump bailer system 153 to direct dump bailer assembly into sealing engagement with sealing assembly 154.
In
In
In one or more embodiments, each port 116 may include a valve 170 that may be actuated to open and close its respective port 116 as desired to control flow of wellbore fluid 61 into dump bailer assembly 110. In one or more embodiments, valve 170 may be electric. In one or more embodiments, valve 170 may be actuated by pressure. In this regard, valve 170 may be a burst disk or similar rupture mechanism that ruptures when wellbore pressure Pw reaches a certain threshold. In such embodiments, dump bailer assembly 110 may be installed as described above and then the pressure Pw of wellbore fluid 61 may be raised above a threshold activation pressure, activating valve 170 so as to open ports 116 and permitting wellbore fluid 61 to flow into dump bailer assembly 110. It will be appreciated that because dump bailer assembly 110 is seated on sealing assembly 154, and engagement mechanisms 150 and 152 are engaged, sealing contact is established between sealing assembly 154 and dump bailer assembly 110. Thus, the wellbore fluid pressure Pw of wellbore fluid 61 can be raised as desired without impacting injection zone 168. It will be appreciated that a sealing mechanism (not shown) is typically provided adjacent the wellhead 32 (see
In other embodiments, engagement mechanism 150 is disposed along a different part of tool body 62. Thus, engagement mechanism 150 may be disposed adjacent head assembly 65. As such, during deployment, dump bailer assembly 110 is passed through interior bore 158 of sealing assembly 154 until engagement mechanism 150 engages engagement mechanism 152, to form a seal therebetween. Again, guides 134 may be used to facilitate alignment of dump bailer assembly 110 with interior bore 158 to assist in engaging engagement mechanism 150 and engagement mechanism 152. This arrangement is particularly desirable where receptacle 4470 may be flexible or bendable as described below. In such instance, increasing pressure Pw of wellbore fluid 61 in order to activate dump bailer assembly 110 will not affect receptacle 70.
The arrangement of dump bailer system 153 in
In one or more embodiments, bailer receptacle 70 of tool body 62 is elongated and bendable or flexible. In such case, the head assembly 65 and the injection assembly 67 may each be formed of a rigid mandrel and the elongated bailer receptacle 70 may be formed bendable or semi-rigid material such as flexible hose, bendable tubing, coiled tubing or the like. As such, elongated bailer receptacle 70 may be continuous or semi-continuous with long bendable or semi-rigid jointed sections. For example, such long, semi-continuous, bendable or semi-rigid sections may be 50 meters or more in length. Likewise, elongated bailer receptacle 70 may be jointless. In any case, the cavity 72 formed in such elongated, semi-rigid or bendable bailer receptacle 44 is similarly elongated and bendable. In one or more embodiments, elongated bailer receptacle 70 is a flexible hose formed of one or more outer layers of woven fabric with an inner layer of rubber, allowing the hose to be readily rolled for storage. Such construction is commonly used, for example, in fire hoses wherein the inner rubber layer is sufficiently thin to substantially flatten under the weight of the hose, and the outer woven fabric layers are sufficient to restrain high pressure fluid within the hose. In one or more embodiments, elongated bailer receptacle 70 is non-metal. In one or more embodiments, elongated bailer receptacle 70 is formed of reinforced plastic.
An example of such a hose is illustrated in
Turning to
In
In other embodiments, rather than paying out bailer receptacle 70 from a reel 182, bailer receptacle may be stored in the form of pre-made lengths that are made up via connections while being run to the desired length L, much in the same way that lengths of fire hoses may be join together to form a long length of fire hose. These pre-made lengths may be flat rolled or folded and stored for transport and handling. They may be picked up with crane a or the derrick (not shown), made up as would lengths of rigid pipe, and lowered into the well in sections.
With reference back to
In other embodiments, a length L of flexible bailer receptacle 70 may be cut at the surface exposing both free ends 185, 187, and the injection assembly 67 and head assembly 65 may be attached to their respective free ends 185, 187 prior to lowering injection assembly 67 into wellbore 22.
In any event, bailer content 142 may be charged into tubular portion 120 though fill port 123. In the illustrated embodiment, a bailer content source 176 is shown at the surface 183 of wellbore 22. Utilizing a pump 178, bailer content 142 is pumped from source 176 into bailer receptacle 70 via tubular portion 120. It will be appreciated that as bailer content 142 is charged into tubular portion 120, second piston assembly 84b will begin to move towards second end 66 of tool body 62 (see
In one or more embodiments, wireline, slickline or other cable 80 may be utilized to lower a fully assembled dump bailer assembly 60 into wellbore 22 as described above. In such case, a cable reel 190 may also be positioned at the surface 183 of wellbore 22, as shown.
In other embodiments, dump bailer assembly 60 may be lowered on coiled tubing into wellbore 22. In such embodiments, it will be appreciated that in such embodiments, fluid to drive one or both piston assemblies 84 may be pumped from the surface instead of an integrated pump as described.
One benefit of embodiments of the foregoing dump bailer assembly is that there is no limitation on the bailer receptacle length, particularly where an integral pump is utilized. Thus, the volume of the bailer content is not limited as it would be in prior art dump bailer assemblies. Moreover, the foregoing dump bailer assembly while still having the advantage of a long, high capacity bailer is that it is quick to run and quick to fill as compared to prior art dump bailers assembled of pipe lengths. An additional benefit of the foregoing dump bailer assembly is that for smaller diameter wellbores, the diameter of the bailer receptacle can be reduced without sacrificing a loss of volume since the length of the bailer receptacle can be increased to compensate for a smaller diameter, all of which is made possible by the presence of the integrated pump.
As stated above, the bailer content need not be limited to cement slurry, but can be any fluid for release into the wellbore.
Thus, various embodiments of a dump bailer system for releasing fluids into a wellbore have been described. A dump bailer system may generally include a tool body having a first end, a second end and an exterior; an elongated bailer receptacle, carried by the tool body and having a cavity formed within the receptacle, the cavity having a first end and a second end; a piston slidably disposable within the cavity and movable between the first end and the second end of the cavity; and a pump carried by the tool body and in fluid communication with the first end of the cavity. In other embodiments, a dump bailer system may generally include a tool body having a first end, a second end and an exterior; an elongated bailer receptacle, carried by the tool body and having a cavity formed within the receptacle, the cavity having a first end and a second end; and a piston assembly slidably movable between the first end and the second end of the cavity; wherein the piston assembly comprises a first piston having a first side and a second side and an exterior surface, with a piston fluid passage extending between the first and second sides; and a rupture disk disposed along the fluid passage. In other embodiments, a dump bailer system may generally include a tool body having a first end, a second end and an exterior; an elongated bailer receptacle, carried by the tool body and having a cavity formed within the receptacle, the cavity having a first end and a second end; and a piston slidably disposable within the cavity and movable between the first end and the second end of the cavity; and a vibrator carried by the tool body. In yet other embodiments, a dump bailer system may generally include a head assembly having a flow passage therethrough; an injection assembly having a flow passage therethrough; a jointless, bendable elongated bailer receptacle having a cavity formed within the receptacle, the cavity having a first end in fluid communication with the flow passage of the head assembly and a second end in fluid communication with the flow passage of the injection assembly; and a piston slidably disposable within the cavity and movable between the first end and the second end of the cavity. In yet other embodiments, a dump bailer system may generally include a rigid head assembly having a flow passage therethrough; a rigid injection assembly having a flow passage therethrough; and a flexible bailer receptacle having an elongated cavity formed therein and in fluid communication with the flow passage of the rigid head assembly and the flow passage of the rigid injection assembly. In other embodiments, a dump bailer system may generally include a head assembly having a head assembly flow passage therethrough; an injection assembly having a first end and a second end, an exterior, a main flow bore extending from the first end of the injection assembly, and a first injection flow passage extending from the second end of the injection assembly and in fluid communication with the main flow bore; an elongated bailer receptacle having a first end and a second end with a cavity formed within the receptacle and extending between the first end and the second end of the receptacle, wherein the head assembly is attached to the first end of the elongated bailer receptacle with the head assembly flow passage in fluid communication with the cavity, wherein the injection assembly is attached to the second end of the elongated bailer receptacle with the main flow bore in fluid communication with the cavity; a piston slidably disposable within the cavity and movable between the first end and the second end of the cavity; and an engagement mechanism adjacent the second end of the injection assembly. In yet other embodiments, a dump bailer system may generally include a head assembly having a flow passage therethrough; an injection assembly having a flow passage therethrough; a jointless, bendable elongated bailer receptacle having a cavity formed within the receptacle, the cavity having a first end in fluid communication with the flow passage of the head assembly and a second end in fluid communication with the flow passage of the injection assembly, wherein the jointless, bendable elongated bailer receptacle is a hose; a piston slidably disposable within the cavity and movable between the first end and the second end of the cavity; a hose reel on which the hose is spooled; and a hose feeder. In yet other embodiments, a dump bailer system may generally include an elongated dump bailer body having a head assembly and an injection assembly; a rigid conveyance mechanism attached to the head assembly; and a plurality of centralizers disposed along at least a portion of the length of elongated body, wherein the centralizers are rollers.
For any of the foregoing embodiments, the dump bailer system may include any one of the following elements, alone or in combination with each other:
A pump carried by the tool body and in fluid communication with the first end of the cavity.
The pump is a positive displacement pump.
The pump is an electric pump.
The pump is in fluid communication with the exterior of the tool body.
The rigid conveyance mechanism is coiled tubing.
The head assembly comprises a wellbore sealing assembly.
The wellbore sealing assembly is an inflatable packer disposed about an exterior surface of the head assembly.
A fluid passage formed within the tool body and extending from the exterior of the tool body to the first end of the cavity, wherein the positive displacement pump is disposed along the fluid passage.
A fluid filter disposed along the fluid passage between the exterior of the tool body and the first end of the cavity.
A wireline adapter unit adjacent the first end of the tool body.
The dump bailer system further comprises an integral vibrator.
The dump bailer system further comprises an integral pump.
The positive displacement pump is positioned adjacent the first end of the tool body and a check valve positioned adjacent the second end of the tool body, the check valve being in fluid communication with the second end of the cavity.
The cavity is a bore.
The cavity is an elongated, axially extending cavity.
The receptacle is a tube.
The receptacle is a flexible hose.
The receptacle is a semi-rigid.
The receptacle is bendable.
The receptacle is coiled tubing.
The receptacle is a rigid cylindrical pipe.
The elongated bailer receptacle is jointless.
The elongated bailer receptacle is non-metal.
The elongated bailer receptacle comprises a plurality of interconnected pipe sections.
The receptacle comprises a single, continuous flexible joint.
A seal disposed about the exterior surface of the piston and sealingly engaging the receptacle.
The piston assembly comprises a first piston having a first side and a second side and an exterior surface, with a piston fluid passage extending between the first and second sides; and a rupture disk disposed along the fluid passage.
The piston is a wiper plug.
The piston assembly further comprises a second piston having a first side and a second side and an exterior surface, with a piston fluid passage extending between the first and second sides of the second piston and a rupture disk disposed along the fluid passage of the second piston.
The tool body comprises a tubular filling chamber extending from a first end to a second end of the tubular filling chamber, with the second end of the of the tubular filling chamber attached to the elongated bailer receptacle adjacent the first end of the cavity, the tubular filling chamber having a first piston receiving zone defined adjacent the first end of the filling chamber, a second piston receiving zone defined adjacent the second end of the filling chamber, and a fluid filling port disposed in the tubular filling chamber between the first and second piston receiving zones.
A tubular landing chamber having a first end and a second end with an inner bore extending between the first end and the second end and a piston landing shoulder defined along the inner bore.
The inner bore having a first diameter adjacent the first end of the landing chamber and sized to receive a piston and a second diameter adjacent the second end of the landing chamber and smaller than the first diameter, the shoulder formed along the inner bore where the bore diameter changes.
A vibrator carried by the tool body.
The vibrator is electric.
The vibrator is positioned adjacent the second end of the cavity.
The vibrator is positioned adjacent the first end of the tool body.
A jointless, bendable elongated bailer receptacle having a cavity formed within the receptacle, the cavity having a first end in fluid communication with the flow passage of the head assembly and a second end in fluid communication with the flow passage of the injection assembly
The head assembly comprises a rigid pipe.
The head assembly comprises an upper tool body.
The injection assembly comprises a lower tool body.
An upper end of the jointless, bendable elongated bailer receptacle is attached to the head assembly and a lower end of the jointless, bendable elongated bailer receptacle is attached to the injection assembly.
The head assembly is rigid.
The injection assembly is rigid.
The head assembly comprises a positive displacement pump carried by the head assembly.
The pump is in fluid communication with an exterior of the upper head assembly.
A fluid passage formed within the tool body and extending from the exterior of the tool body to the first end of the cavity, wherein the positive displacement pump is disposed along the fluid passage.
The injection assembly comprises a check valve positioned along the flow passage of the injection assembly.
The bendable elongated bailer receptacle is a hose.
The hose comprises one or more outer layers of woven fabric with an inner layer of rubber.
The hose comprises at least one flexible outer layer and an inner flexible layer.
The outer flexible layer is selected from a group consisting of woven material, woven fabric, reinforced material, rubber, cloth, metal mesh.
A hose reel on which the hose is spooled; and a hose feeder.
A bailer receptacle reel on which the bailer receptacle is spooled, and a bailer receptacle feeder.
A bailer receptacle guide adjacent the bailer receptacle feeder.
The bailer receptacle guide positioned above the bailer receptacle feeder.
A cable reel on which is mounted a cable.
The cable is wireline.
The cable is slickline.
The cable is a coiled hose.
A wellhead, wherein the hose feeder is positioned above the wellhead.
The engagement mechanism is a latch assembly.
The latch assembly is mechanically actuated latch.
The latch assembly is an electrically actuated latch.
The latch assembly comprises a latch housing
A first flow valve disposed along the first flow passage.
The first is a one-way flow valve to permit fluid flow through the first flow passage from the main flow bore to the second end of the injection assembly.
The first flow valve is a pressure activated flow valve.
The injection assembly further comprising a second flow passage extending from the second end of the injection assembly and in fluid communication with the main flow bore, the second flow passage spaced apart from the first flow passage; a first flow valve disposed along the first flow passage to permit fluid flow through the first flow passage from the main flow bore to the second end of the injection assembly; and a second flow valve disposed along the second flow passage to permit fluid flow from the second end of the injection assembly to the main flow bore.
The first and second flow valves are each one-way valves.
A centralizer carried on the exterior of the injection assembly.
The centralizer is adjacent the second end of the injection assembly.
The centralizer comprises one or more rollers.
A first centralizer adjacent the first end of the injection assembly and a second centralizer adjacent the second end of the injection assembly.
A plurality of centralizers spaced apart from one another on each of the head assembly and injection assembly.
A sealing assembly disposed within the wellbore, wherein the sealing assembly comprises a seal tube having a bore formed therein, and a sealing element disposed about the seal tube.
The sealing assembly is a packer.
The sealing assembly is a plug.
The sealing assembly is a component in the wellbore tubular.
The sealing element is elastomeric.
The seal tube is a smooth bore tube.
Although various embodiments have been shown and described, the disclosure is not limited to such embodiments and will be understood to include all modifications and variations as would be apparent to one skilled in the art. Therefore, it should be understood that the disclosure is not intended to be limited to the particular forms disclosed; rather, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the disclosure as defined by the appended claims.
Claims
1. A dump bailer system comprising
- a tool body having a first end, a second end and an exterior;
- an elongated bailer receptacle, carried by the tool body and having a cavity formed within the receptacle, the cavity having a first end and a second end,
- a piston assembly slidably disposable within the cavity and movable between the first end and the second end of the cavity; and
- a pump carried by the tool body and in fluid communication with the first end of the cavity.
2. The dump bailer system of claim 1, wherein the pump is an electric, positive displacement pump.
3. The dump bailer system of claim 2, wherein the pump is reversible.
4. The dump bailer system of claim 1, wherein the tool body comprises a head assembly attached to the elongated bailer receptacle adjacent the first end of the cavity and an injection assembly attached to the elongated bailer receptacle adjacent the second end of the cavity, wherein the head assembly comprises the pump.
5. The dump bailer system of claim 4, wherein head assembly further comprises a fluid passage formed within the tool body and extending from the exterior of the tool body to the first end of the cavity, wherein the positive displacement pump is disposed along the fluid passage.
6. The dump bailer system of claim 5, wherein the head assembly further comprises a fluid filter disposed along the fluid passage between the exterior of the tool body and the first end of the cavity.
7. The dump bailer system of claim 1, wherein the piston assembly comprises a first piston having a first side and a second side and an exterior surface, with a piston fluid passage extending between the first and second sides; and a rupture disk disposed along the fluid passage.
8. The dump bailer system of claim 7, further comprising a second piston assembly having a second piston with a first side and a second side and an exterior surface, with a piston fluid passage extending between the first and second sides of the second piston; and a rupture disk disposed along the fluid passage of the second piston.
9. The dump bailer system of claim 8, wherein the head assembly further comprises a tubular filling chamber having a first end and a second end, with the second end of the of the tubular filling chamber attached to the elongated bailer receptacle adjacent the first end of the cavity, the tubular filling chamber having a first piston assembly disposed adjacent the first end of the filling chamber, a second piston assembly disposed adjacent the second end of the filling chamber, and a fluid filling port disposed in the tubular filling chamber between the first and second piston assemblies.
10. The dump bailer system of claim 1, further comprising an integral vibrator.
11. The dump bailer system of claim 1, wherein the elongated bailer receptacle is a rigid receptacle.
12. The dump bailer system of claim 1, wherein the elongated bailer receptacle is flexible.
13. A dump bailer system comprising
- a tool body having a first end, a second end and an exterior, wherein the tool body comprises a head assembly with a fluid passage formed within the tool body and extending from the exterior of the tool body through the head assembly;
- a flexible, elongated bailer receptacle, carried by the tool body and having a cavity formed within the receptacle, the cavity having a first end and a second end, wherein the head assembly is attached to the elongated bailer receptacle adjacent the first end of the cavity, and the fluid passage formed within the tool body extends from the exterior of the tool body to the first end of the cavity, and wherein the flexible, elongated bailer receptacle is a hose;
- a piston assembly slidably disposable within the cavity and movable between the first end and the second end of the cavity, wherein the piston assembly comprises a first piston having a first side and a second side and an exterior surface, with a piston fluid passage extending between the first and second sides; and pressure actuated flow control mechanism disposed along the fluid passage of the piston; and
- an electric, positive displacement pump carried by the tool body and in fluid communication with the first end of the cavity, wherein the positive displacement pump is disposed along the fluid passage.
14. The dump bailer system of claim 13, wherein the hose comprises at least one woven outer flexible layer and at least one rubber inner flexible layer.
15. The dump bailer system of claim 13, wherein the pump is reversible.
16. A method for injecting bailer content into a wellbore, the method comprising: charging bailer content into an elongated dump bailer assembly; deploying the dump bailer assembly into a wellbore; and operating a pump carried by the dump bailer assembly to drive the bailer content from the dump bailer assembly.
17. The method of claim 16, wherein operating the pump comprises pumping wellbore fluid from around the dump bailer assembly to drive a piston within the dump bailer assembly towards a downhole end of the dump bailer assembly; and utilizing the driven piston to urge the bailer content from the dump bailer assembly.
18. The method of claim 17, wherein the step of pumping the wellbore fluid comprises pumping the wellbore fluid at a first pressure to drive the piston; and utilizing the driven piston to increase the fluid pressure of the bailer content; and utilizing the increased fluid pressure of the bailer content to actuate a flow control mechanism to inject the bailer content into the wellbore.
19. The method of claim 18, wherein the step of pumping the wellbore fluid further comprises pumping the wellbore fluid at a second pressure greater than the first wellbore fluid pressure; utilizing the second pressure to actuate a flow control mechanism disposed within the piston; and pumping the wellbore fluid through the flow control mechanism of the piston to flush the bump bailer assembly.
20. The method of claim 19, wherein the step of pumping the wellbore fluid further comprises reversing direction of the pumped wellbore fluid to create a low pressure on the piston; and driving the piston towards an uphole end of the dump bailer assembly.
Type: Application
Filed: Jun 2, 2020
Publication Date: Dec 2, 2021
Inventors: Gunnar Lende (Sola), Torleik Hervik Kleppa (Stavanger)
Application Number: 16/890,718