See Application Data Sheet.
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The present invention relates to isolating zones in a wellbore. More particularly, the present invention relates a downhole tool for isolating zones in a wellbore. Even more particularly, the present invention relates to a plug assembly with additional support for a sealing ring.
Within a wellbore, the hydrocarbons are located at particular depths within a rock formation. These depths can be organized into production zones so that the delivery of production fluids can be targeted to the location of the hydrocarbons. The production fluids facilitate the recovery of the hydrocarbons from the wellbore. Other depth levels do not contain hydrocarbons, which can be called “non-productive zones”. There is no need to waste production fluids on non-productive zones without hydrocarbons. Thus, the productive zones are isolated from the non-productive zones for the recovery of hydrocarbons from the wellbore.
There are known downhole tools to separate a production zone from a non-productive zone. The production fluids can be delivered to the production zone and not the non-productive zone. An isolation valve creates a barrier between the two different zones. A ball member in the valve can be actuated to seal between the zones. A frac plug also creates a barrier between the two different zones. The frac plug has slips to dig into the walls of a wellbore, and a ball seat in an annular wedge. A frac ball is dropped into the wellbore to be placed in the ball seat in a sealing engagement to isolate the production zone and non-productive zone. There are specialized frac plugs, such as bridge plugs, with different components and corresponding different methods for installing the plugs in the wellbore.
The general mechanism for installing in a wellbore is disclosed in various patents and patent publications. U.S. Pat. No. 8,579,024, issued on 12 Nov. 2013, to Mailand et al., shows the basic cone and slip components to grip the walls of the wellbore. U.S. Pat. No. 8,695,714, issued on 15 Apr. 2014 to Xu et al, also describes an invention related to these basic components. US Publication No. 2016/0305215, published on 20 Oct. 2016 for Harris et al., (and granted as USP 100000991 on 19 Jun. 2018) discloses another frac plug as a simplified wedge/cone and slip.
The plug assemblies with fewer components are generally faster and easier to install and less expensive to manufacture. In contrast with prior art downhole tools, including bridge plugs disclosed by the Applicant in U.S. Pat. Nos. 9,121,253 and 9,121,254, there are no longer the redundancies to attach and seal against the wall of the wellbore. The plug assemblies with only basic components must incorporate on modifications to achieve the same reliability as the more complex prior art downhole tools.
It is an object of the present invention to provide a plug assembly for separating zones in a wellbore.
It is an object of the present invention to provide a plug assembly with sealing engagement to the wellbore by a sealing ring and support lugs for the sealing ring.
It is an object of the present invention to provide a plug assembly without extrusion of the sealing ring into the slip device.
It is another object of the present invention to provide a plug assembly without extrusion into spaces between individual slips or blades of the slip device.
It is another object of the present invention to provide a plug assembly with a radially extending support lugs for a sealing ring.
These and other objectives and advantages of the present invention will become apparent from a reading of the attached specification.
The plug assembly isolates production zones from non-productive zones in a wellbore drilled into a rock formation. The sealing engagement to the wellbore must be reliable, and several plug systems have a mandrel, a sealing member, ring members to back up the sealing member, multiple cone assemblies, and multiple slip device. A plug assembly with fewer components has fewer redundancies to ensure the required reliability. Embodiments of the present invention include a plug assembly with only one cone assembly, one sealing ring, and one slip device. There is a plurality of support lugs to back up the sealing ring and a setting ring for installation of the plug device. These embodiments provide a simpler and cost-effective downhole tool with reliability required for performing oil and gas operations in the wellbore.
The embodiment of the cone assembly has a first cone end with a first cone diameter, a second cone end with a second cone diameter, and a conical outer surface being between the first cone end and the second cone end and having an assembly axis. The cone assembly is an annular wedge or cone aligned along the assembly axis. The first cone diameter is smaller than the second cone diameter so that the conical outer surface is tapered from the second cone end to the first cone end. The sealing ring is mounted around the cone assembly. The sealing ring is oriented coaxially along the assembly axis 26A and radially expands relative to the assembly axis.
Embodiments of the slip device include a slip device being comprised of a plurality of blades radially arranged around the conical outer surface and also oriented along the assembly axis. Each blade radially expands relative to the assembly axis, and a plurality of spaces is defined by the plurality of blades. Each space is defined by the area or slot between corresponding adjacent blades of the plurality of blades. The spaces radially expand relative to the assembly axis in coordination with the blades.
Embodiments of the present invention further include a plurality of support lugs being positioned between the slip device and the sealing ring. Each support lug can be comprised of an abutment portion and a gap portion. Each abutment portion is placed between the sealing ring and a corresponding blade, while each gap portion is placed between the sealing ring and a corresponding space defined by the corresponding blade.
The invention also includes a setting ring axially aligned with the slip device, the sealing ring, and the cone assembly on the assembly axis. The slip device is positioned between the setting ring and the plurality of support lugs. In some embodiments, the setting ring has a first setting ring end and a second setting ring end. The first setting ring end is in radial sliding engagement with corresponding blades relative to the assembly axis. The blades remain in abutment to the setting ring, even as the blades radially expand relative to the assembly axis. Each gap portion of a support lug separates a corresponding space from the sealing ring to prevent extrusion of the sealing ring into the space. Thus, reliability of the sealing ring in the sealing engagement to the wellbore is supported by the support lugs.
Embodiments of the present invention include the blades having cavities and inserts for a roughened outer surface for improved gripping of the walls of the wellbore.
Alternative embodiments of the support lugs include each support lug being comprised of the abutment portion, the gap portion and another abutment portion. Each support lug may be symmetrical with abutment portions on both sides of the gap portion, such as a triangular wedge. The another abutment portion is between the sealing ring and a corresponding adjacent blade. In other embodiments, the support lug is asymmetrical, and the another abutment portion is a flange that is between the sealing ring and the corresponding adjacent blade. In further embodiments, the another abutment portion is between the sealing ring and the abutment portion of an adjacent support lug as an interlock. The support lugs can overlap an adjacent support lug and an adjacent blade for this interlocked embodiment.
The method for installation in a wellbore is another embodiment of the present invention. The installation of the plug assembly describes the method of using the plug assembly. The plug assembly is prepared placing the setting ring in a first setting position. All components are at radial distances relative to the assembly axis with the setting ring in the first setting position. The plug assembly is deployed to the downhole location. The setting ring is moved from the first setting position to a second setting position, radially expanding the sealing ring, the support lugs, the blades of the slip device, and the spaces defined by the blades. The plug assembly is locked at the downhole location with the blade embedded or anchored in the walls of the wellbore at a second blade position related to a greater radial expansion relative to the assembly axis. Embodiments of the method include sealing each space with the corresponding support lug concurrent with the step of moving the setting ring.
Oil and gas operations include delivering drilling fluids to the wellbore and extracting the hydrocarbons from the wellbore. Isolation of the production zones within a rock formation allow the delivery or injection of drilling fluids to only those production zones and the pumping of the hydrocarbons out of those production zones only. The efficiency and reliability of the isolation and separation of the zones depend upon the sealing engagement of downhole tools to the wellbore. These downhole tools must be deployed into the wellbore and accurately installed at a downhole location. Prior art downhole tools, such as bridge plugs are comprised of a mandrel, a sealing member, ring members to back up the sealing member, multiple cone assemblies, and multiple slip device. Additionally, a proper setting tool to actuate and trigger all of those components must be able to reach the downhole location, perform the work to install the downhole tool, and leave the downhole location with the downhole tool in place. When a plug assembly with fewer components is used to isolate zones, the plug assembly is a simpler and less expensive downhole tool, and typically, a simpler setting tool can be deployed into the wellbore to install that simpler plug assembly. There are fewer redundancies to ensure the required reliability of the installation and sealing engagement to the wellbore for these types of plug assemblies.
Referring to
Embodiments of the cone assembly 20 have a first cone end 22 with a first cone diameter 22A, a second cone end 24 with a second cone diameter 24A and a conical outer surface 26 being between the first cone end and the second cone end. The cone assembly 20 can have an annular wedge or cone shape with an assembly axis 26A. The assembly axis 26A is the centered axis through the cone assembly 20 that defines the flow path through the plug assembly 10. The flow path aligned on the assembly axis 26A is also the flow path to be blocked or sealed for isolation of zones.
The slip device 40 of the present invention can be comprised of a plurality of blades 42 radially arranged around the conical outer surface 26 and along the assembly axis 26A defined by the cone assembly 20.
Each angled inner blade surface 42C is in sliding engagement with the conical outer surface 26. As the cone assembly 20 moves closer, the conical outer surface 26A spreads the blades 42 further and further apart radially from the assembly axis 26A. Each blade 42 radially expands relative to the assembly axis 26A so that each blade 42 is further apart from adjacent blades 42.
In the present invention, the plurality of blades 42 define a plurality of spaces 44. Each space 44 is positioned between corresponding adjacent blades 42 of the plurality of blades 42. Each space 42 is also radially expandable relative to the assembly axis 26A. Each space 42 grows larger as corresponding blades 42 radially expand relative to the assembly axis 26A.
The sealing ring 30 has relationships to the cone assembly 20 to enable the separation of the sealing ring 30 from the spaces 44 defined by the blades 42 of the slip device 40. The sealing ring 30 is radially expandable.
In
Similarly, the blades 42 of the slip device 40 are radially expandable in coordination with the support lugs 50 and the sealing ring 30. Each blade 42 has a first blade radius 48A relative to the assembly axis 26A at a first blade position and a second blade radius 48B relative to the assembly axis 26A at a second blade position. Each first blade position is radially closer to an adjacent blade 42 than a corresponding second blade position. The second blade radius 48B is larger or further away from the assembly axis 26A than the first blade radius 48A.
In terms of the spaces 44 defined by the blades 42 of the slip device 40, the spaces are radially expandable as well. In particular, each space 44 has a first slot distance 44A relative to a corresponding adjacent blade 42 in the first blade position and a second slot distance 44B relative to the corresponding adjacent blade 42 in a respective second blade position. Each second slot distance 44B is also greater than a corresponding first slot distance 44A. Just as the blades 42 are further from each other and the assembly axis 26A, the spaces 44 are further from the assembly axis 26A and larger.
In some embodiments, the cone assembly 20 includes an inner cone passage 28. The inner cone passage 28 can fit a ball or a ball seat to create the barrier between zones. A barrier in the cone assembly 20 prevents fluid flow through the plug assembly 10, and the zones on each side of the plug assembly 10 are isolated. In some variations, the inner cone passage 28 is tapered itself so as to function as a ball seat. At least a portion of the inner cone passage 28 holds a means to form a barrier. The sealing ring 30, support lugs 50, and the blades 42 create the barrier around the plug assembly 10 in the wellbore, and the inner cone passage 28 can form the barrier through the plug assembly 10. Depending upon the complexity of the barrier for desired control of the tightness of the seal and the duration of the seal, different means to form a barrier are known in the prior art.
The present invention also includes the method of using the plug assembly 10, in particular, a method for installing the plug assembly 10 to isolate zones in a wellbore.
Additionally, the method includes radially expanding each space 44 from a first slot distance 44A relative to a corresponding adjacent blade 42 in the first blade position to a second slot distance 44B relative to the corresponding adjacent blade 44 in a respective second blade position. The second slot distance 44B is greater than the first slot distance 44A so that the spaces 44 match the radial expanding of the blades 42 and sealing ring 30. The spaces 44 remain sealed from the sealing ring 30 by the support lugs 50 so that the radial expansion of the sealing ring 30 does not result in extrusion through the blades 42 of the slip device 40. Embodiments of the method also include the step of locking the plug assembly 10 at the downhole location with the slip device 40 having blades 2 in the second blade position. The widest radial expansion corresponds to the blades 42 attaching to the walls of the wellbore. That widest radial expansion is the second blade radius 48B with each blade 42. After locking the sealing ring 30 forms the liquid tight seal around the plug assembly 10, and the only fluid flow through the plug assembly is through the cone assembly 20 and other components aligned on the assembly axis 26. The plug assembly 10 is now installed and ready for oil and gas operations. The plug assembly 10 can be opened or closed to fluid flow through the plug assembly 10.
Embodiments of the method can further include deploying a setting tool to the downhole location and completing the step of moving the setting ring 60 with the setting tool. Setting tools must be compatible with being transported through the wellbore and can have varying degrees of complexity. In the present invention, a simpler setting tool can be used.
The present invention can include the step of sealing the sealing ring 30 from the space 44 with the support lug 50 concurrent with the step of moving the setting ring 60. The support lugs 50 block the sealing ring 30 from extruding into the spaces 44 so that the sealing ring 30 reliable seals to the wellbore. The support lugs 50 seal the spaces 44 to the sealing ring 30. Even during the steps of radially expanding the sealing ring 30, the support lugs 50, the blades 42 of the slip device 40, and the spaces 44 between adjacent blades 42, the support lugs 50 prevent the extrusion of the sealing ring 30.
The downhole location is comprised of a wellbore having a wellbore wall. The second setting distance 68 and the second setting position are determined by the blades 42 in the second blade position in fixed engagement with the wellbore wall. The wellbore wall determines the amount of radial expansions.
The present invention provides a plug assembly for separating zones in a wellbore. There is a seal between the plug assembly and the wellbore by the sealing ring. This seal enables fluid flow to be controlled through the plug assembly. This seal around the plug assembly is now supported by the support lugs as a quick and efficient back up to the sealing ring. Without the sealing member and rings members on both sides off the sealing member of the prior art, the present invention prevents extrusion of the sealing ring into the slip device with fewer components in more strategic arrangements in the plug assembly. The spaces between the blades are dynamic. The spaces change, so another sealing ring or just another sealing ring will have the same problems of extrusion as the original sealing ring. The present invention provides a structural component that interacts differently with the spaces, even when the spaces change. Embodiments of the present invention include overlapping, symmetrical, asymmetrical, and interlocking support lugs with the same interactions between the spaces and the sealing ring. The radial expansion of the sealing ring and the radial expansion of the support lugs reliably prevent extrusion and strengthen the seal of the sealing ring to the wellbore.
The foregoing disclosure and description of the invention is illustrative and explanatory thereof. Various changes in the details of the illustrated structures, construction and method can be made without departing from the true spirit of the invention.
Number | Name | Date | Kind |
---|---|---|---|
6712153 | Turley et al. | Mar 2004 | B2 |
6769491 | Zimmerman et al. | Aug 2004 | B2 |
7424909 | Roberts et al. | Sep 2008 | B2 |
8069918 | Zimmerman et al. | Dec 2011 | B2 |
8596347 | Valencia et al. | Dec 2013 | B2 |
8695714 | Xu et al. | Apr 2014 | B2 |
9810035 | Carr | Nov 2017 | B1 |
9845658 | Nish | Dec 2017 | B1 |
20180004501 | Thornton et al. | Feb 2018 | A1 |
20180038191 | Davies | Feb 2018 | A1 |
20190006317 | Frazier | Feb 2019 | A1 |
20200048981 | Coon | Feb 2020 | A1 |
Number | Date | Country |
---|---|---|
WO-2019032682 | Feb 2019 | WO |
Number | Date | Country | |
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20210002973 A1 | Jan 2021 | US |