US20260110230A1
SYSTEM FOR ANCHORING A DOWNHOLE TOOL TO A CASING WITH AN EXPANDABLE SPIRAL THREADED SLIP DEVICE
Publication
Application
Classifications
IPC Classifications
CPC Classifications
Applicants
CNPC USA Corporation, BEIJING HUAMEI, Inc., CHINA NATIONAL PETROLEUM CORPORATION
Inventors
Damon NETTLES, Kwami ROBERTS, Tito ZABALA, David ALGIEN, Perry BATSON, Jianpeng YUE, Peng CHENG
Abstract
The system for anchoring a downhole tool to a casing includes a spiral threaded engagement and a raised spiral threaded engagement between a barrel slip device and first and second cones. The first cone is moveable by a piston in a piston housing to be closer to the second cone within the slip device. The second cone is locked in axial position along the mandrel and locked from rotation around the mandrel by an end housing, such that the barrel slip device is forced to expand from an initial diameter in a run-in configuration to an extended diameter in a set configuration. The spiral threaded engagement of the first cone is in the opposite spiral direction to the spiral threaded engagement of the second cone. The invention includes both the method of assembling the system for deployment into the casing and the method of anchoring the system to the casing.
Figures
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001]The present application claims priority under 35 U.S.C. Section 120 from U.S. patent application Ser. No. 18/525,304, filed on 30 Nov. 2023, entitled “EXPANDABLE SPIRAL THREADED APPARATUS AND METHOD FOR ANCHORING A DOWNHOLE TOOL TO A CASING, AND METHOD FOR ASSEMBLING THE APPARATUS”.
[0002]See also Application Data Sheet.
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT
[0003]Not applicable.
THE NAMES OF PARTIES TO A JOINT RESEARCH AGREEMENT
[0004]Not applicable.
INCORPORATION-BY-REFERENCE OF MATERIAL SUBMITTED ON A COMPACT DISC OR AS A TEXT FILE VIA THE OFFICE ELECTRONIC FILING SYSTEM (EFS-WEB)
[0005]Not applicable.
STATEMENT REGARDING PRIOR DISCLOSURES BY THE INVENTOR OR A JOINT INVENTOR
[0006]Not applicable.
BACKGROUND OF THE INVENTION
1. Field of the Invention
[0007]The present invention relates to isolating zones in a wellbore. More particularly, the present invention relates an anchoring component of a downhole tool to a casing. The downhole tool, such as a plug or packer, isolates a zone in the wellbore. Even more particularly, the present invention relates to an expandable spiral threaded anchoring component in a system for anchoring the tool to the casing.
2. Description of Related Art Including Information Disclosed Under 37 CFR 1.97 and 37 CFR 1.98
[0008]A slip is a basic anchoring component to hold a downhole tool 1 at a desired location in the borehole, as shown in
[0009]A barrel slip 8 is a particular type of slip of an anchoring component that resists movement in both directions, as shown in
[0010]There are various patents and patent publications disclosing anchoring components of a downhole tool, including barrel slips.
[0011]U.S. Pat. No. 5,944,102, issued on 31 Aug. 1999 to Kilgore et al, U.S. Pat. No. 5,906,240, issued on 25 May 1999 to Kilgore et al, U.S. Pat. No. 6,378,606, issued on 30 Apr. 2002 to Swor et al, and U.S. Pat. No. 6,481,497, issued on 19 Nov. 2002 to Swor et al, all disclose the prior art straight threaded barrel slip with ratchet engagement to opposing straight threaded cones. The various locking features or shear points of this barrel slip are connectors that still break apart as the barrel slip expands. The assembling and disassembling both require the snap-fit engagement that risks damage and deformation to the tight tolerances between the multiple inclined surfaces of the ramps and threads.
[0012]U.S. Pat. No. 11,441,371, issued on 13 Sep. 2022 to Fripp et al, and US Publication No. 2017/0145780, published on 25 May 2017 for Castro et al, disclose barrel slips with different components, such as sleeves and rings, for expansion, instead of cones.
[0013]One problem with the current barrel slip is the assembling and dissembling of the barrel anchoring component. The convention assembling method requires a press to install the barrel slip onto the straight threaded cones. Furthermore, the barrel slip is at least partially expanded over the threaded cone ramps during assembly using the press. Thus, there is a risk of permanently deforming the barrel slip or damaging the barrel slip during the assembling with the press. Additionally, for disassembling from the expanded configuration, the current barrel slip is almost impossible to release from the casing or tubing for disassembling without destroying the barrel slip. If one cone is not installed correctly, the current barrel slip cannot be removed without damaging the current barrel slip itself. The assembling is difficult because the ratchet engagement between the barrel slip and the threaded cones is a force-fit relationship. The barrel slip or the cones are deformed or at least distended to even assemble the tool, so there is weakening during assembly.
[0014]Another problem with the current barrel slip is precision tolerance. The ramp and slope engagements of the multiple inclined surfaces on both the barrel slip and each of the threaded cones must be very close in order to hold the expanded position of the barrel slip. The current barrel slip is very difficult to machine due to the extremely tight tolerance requirement. Tight tolerancing of linear dimensions is necessary to ensure proper timing and engagement of the inclined surfaces of the barrel slip and threaded cones. That is, the corresponding ramp pairs need to all contact as close to the same time as possible to ensure that the load is evenly distributed around each thread of the cone and each respective ramp of the barrel slip. The barrel slip is easily unbalanced with chips and gaps between the inclined surfaces of the current barrel slip and threaded cones. In practice, this level of precision machining leads to high manufacturing costs and very high scrap rates due to deviations. It also is a burden to quality control and engineering groups to address and disposition non-conforming parts.
[0015]As a result of the ratchet engagement with tight tolerance of the current barrel slip, the load capacity of the anchoring component is limited. The distribution of the load in use is defined by the contact area between the barrel slip and threaded cones. In the straight threaded cones, the contact area remains constant around the mandrel.
[0016]There are also various patents and patent publications disclosing spiral threaded surfaces, instead of straight threaded surfaces. The prior art spiral threads are on various components of the downhole tool, although not on the anchoring component of the downhole tool. U.S. Pat. No. 8,002,045, issued on 23 Aug. 2011 to Ezell et al, shows another downhole tool with threaded surfaces for expanding slips. The ratchet or coaxial threads are disclosed as interchangeable with spiral or helical threads. U.S. Pat. No. 4,494,777, issued on 22 Jan. 1985 to Duret, describes spiral threaded pipe joints between tubular members in a drill string. US Publication No. 2019/0234177, published on 1 Aug. 2019 for Silva et al, shows other spiral or angular threaded surfaces in a downhole tool. The consequences of spiral threads for assembling and disassembling and the consequences of increased force needed to separate spiral threaded surfaces are known in the prior art.
[0017]Variations on the placement and orientation of spiral threads on different components of a downhole tool are also known. Chinese Patent No. CN109973043, published on 5 Jul. 2019 for Guo, Dajin et al, and U.S. Pat. No. 3,472,520, issued on 14 Oct. 1969 to Burns, disclose spiral threads in different orientations and on different components, not the anchoring components of the downhole tool. Ratchet engagement of straight threaded surfaces on non-anchoring components of the downhole tool are disclosed in U.S. Pat. No. 3,584,684, issued on 15 Jun. 1971 to Anderson et al, U.S. Pat. No. 4,156,460, issued on 29 May 1979 to Crow, and U.S. Pat. No. 5,101,897, issued on 7 Apr. 1992 to Leismer et al.
[0018]It is an object of the present invention to provide a system for anchoring a downhole tool to a casing or tubing within a borehole.
[0019]It is an object of the present invention to provide a spiral threaded barrel slip device for anchoring a downhole tool to a casing or tubing within a borehole.
[0020]It is an object of the present invention to provide a method for anchoring a downhole tool to a casing or tubing by expanding a spiral threaded barrel slip.
[0021]It is another object of the present invention to provide a system with a barrel slip with a spiral threaded inner slip surface and at least one cone with a spiral threaded outer cone surface for anchoring a downhole tool to a casing or tubing within a borehole.
[0022]It is still another object of the present invention to provide a system with barrel slip with spiral threaded inner slip surfaces in opposing spiral directions and cones with corresponding spiral threaded outer cone surfaces for each spiral direction to anchor a downhole tool to a casing or tubing.
[0023]It is yet another object of the present invention to provide a system with a barrel slip with spiral threaded inner slip surfaces in opposing spiral directions and cones with corresponding spiral threaded outer cone surfaces for each spiral direction locked in a run-in configuration until placed at the correction location in the casing or tubing.
[0024]It is yet another object of the present invention to provide a system with a barrel slip with spiral threaded inner slip surfaces in opposing spiral directions and cones with corresponding spiral threaded outer cone surfaces for each spiral direction locked in an expanded configuration.
[0025]It is an object of the present invention to provide a method of assembling a system with an expandable spiral threaded barrel slip device for anchoring a downhole tool to a casing or tubing with reduced risk of deformation and damage to the components.
[0026]It is an object of the present invention to provide a system with a spiral threaded barrel slip device for anchoring a downhole tool to a casing or tubing with greater precision tolerance between spiral threaded surfaces of the barrel slip and cones.
[0027]It is an object of the present invention to provide a system with a spiral threaded barrel slip device for anchoring a downhole tool to a casing or tubing with greater distribution of load capacity.
[0028]These and other objectives and advantages of the present invention will become apparent from a reading of the attached specification, drawings and claims.
BRIEF SUMMARY OF THE INVENTION
[0029]Embodiments of the present invention include a system for anchoring a downhole tool to a casing within a borehole, including a first cone, a second cone, and a slip device. The downhole tool can be a packer or plug or other tool that requires attachment to the casing, wellbore, or tubing in the borehole. The system for anchoring is only one component of the downhole tool, which may include other components, such as sealing members, support rings, ball seats, and others, according to the functionality of the particular type of downhole tool.
[0030]The system includes a mandrel, a piston being mounted around the mandrel, and a piston housing being mounted around the piston and the mandrel. The piston is between the mandrel and the piston housing. The mandrel, piston and piston housing can be coaxial. The system also includes a first cone being mounted on the mandrel and having a first spiral threaded outer cone surface. The first spiral threaded outer cone surface is threaded in a first spiral direction. The first cone is moveable along the mandrel according to movement of the piston housing. The system further includes second cone being mounted on the mandrel and having a second spiral threaded outer cone surface. The second spiral threaded outer cone surface is threaded in a second spiral direction, and the first spiral direction is opposite the second spiral direction.
[0031]Embodiments of the system further include a slip device having an outer slip surface and an inner slip surface. The slip device fits over the first cone and the second cone and the mandrel. The inner slip surface is comprised a first spiral threaded inner slip surface and a second spiral threaded inner slip surface. There is also an end housing affixed to the mandrel. The end housing is removably engaged to the second cone so as to prevent rotation of the second cone and to prevent movement of the second cone along the mandrel. The second cone has a secured axial and rotationally locked position on the mandrel by the end housing.
[0032]In the present invention, the slip device has a run-in configuration and a set configuration. The slip device starts in the run-in configuration and can be expanded into the set configuration. In the run-in configuration, the first spiral threaded inner slip surface is in spiral threaded engagement with the first spiral threaded outer cone surface and the second spiral threaded inner slip surface is in spiral threaded engagement with the second spiral threaded outer cone surface. The first cone is positioned closer to the second cone than the initial distance within the slip device in the set configuration. The first spiral threaded inner slip surface is now in raised spiral threaded engagement with the first spiral threaded outer cone surface and the second spiral threaded inner slip surface is now in raised spiral threaded engagement with the second spiral threaded outer cone surface in the set configuration.
[0033]Additional embodiments of the present invention include the slip device having a gripping means for the casing or borehole or being a barrel slip or both. The system can also add a key member to the second cone to further support the rotational locked engagement between the second cone and the slip device. The system can also add a locking ring to further support the one-directional axial movement of the first cone toward the second cone.
[0034]The present invention further includes a method for assembling the system for anchoring the downhole tool. The method includes positioning a slip device around the mandrel, mounting the first cone around the mandrel and into the slip device by rotating the first cone in the first spiral direction, and mounting the second cone around the mandrel and into the slip device by rotating the second cone in the second spiral direction. The end housing is affixed to place the second cone in the secured position axially and rotationally. The piston housing and piston are mounted on the mandrel to engage the first cone with the slip device in the run-in configuration. The method of assembly further including installing the supplement locking support components, such as the key member and locking ring.
[0035]Embodiments of the present invention further include the method of anchoring the system to the casing or borehole, after the steps of assembling the system. The downhole tool with the system is deployed with the slip device in the run-in configuration until being positioned at a desired location in the casing. Then, the method includes exerting an axial force on the piston housing and positioning the first cone closer to the second cone. The slip device is placed in a set configuration with an extended diameter greater than the initial diameter to hold the downhole tool at the desired location. The rotational force in the first spiral direction by the first cone is offset by a counter rotational force in the second spiral direction by the second cone. The end housing prevents rotation of the second cone and movement of the second cone along the mandrel.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS
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[0053]
DETAILED DESCRIPTION OF THE INVENTION
[0054]The conventional barrel slip is a prior art anchoring component for a downhole tool, such as a plug or packer. The conventional barrel slip has ratchet engagement between the slip device and the cones, according to the straight threaded surfaces between the slip device and the cones. The consequences of this ratchet engagement by straight threaded surfaces include limitation on the load capacity of the prior art anchoring component and precarious tight tolerances between the straight threaded surfaces. Furthermore, the assembling and disassembling of the prior art anchoring component is only possible by a force-fit relationship between the conventional barrel slip and cones, which deforms the conventional barrel slip and risks damage. The conventional barrel slip and cones can be damaged before the anchoring component is even used, and the tight tolerances between the straight threaded surfaces are already susceptible to even the slightest damage. The present invention is a system 10 with an expandable spiral threaded slip device 40 for anchoring to the casing with load capacity that is more evenly distributed and avoids the need for tight tolerances between surfaces. Additionally, the system 10 with the expandable spiral threaded slip device 40 can be assembled without deformation and with less risk of damage and with the possibility of disassembly without damage.
[0055]The present invention is a system 10 for anchoring a downhole tool to a casing within a borehole, including a mandrel 12, a piston 14, a piston housing, 16, an end housing 18, a first cone 20, a second cone 30, and a slip device 40, as shown in
[0056]Embodiments of the system 10 for anchoring a downhole tool to a casing, according to
[0057]
[0058]Embodiments of the system 10 further include the slip device 40 being mounted on the mandrel 12 between the first cone 20 and the second cone 30 and having an outer slip surface 42 and an inner slip surface 44. The slip device 40 fits over the first cone 20 and the second cone 30 and the mandrel 12. There is coaxial relationship of the slip device 40 and the mandrel 12 with the first cone 20 and the second cone 30 between the slip device 40 and the mandrel 12. The inner slip surface 44 is comprised a first spiral threaded inner slip surface 46 and a second spiral threaded inner slip surface 48. The first cone 20 faces toward the second cone 30 within the slip device 40.
[0059]
[0060]The present invention includes the slip device 40 having a run-in configuration and a set configuration. The run-in configuration corresponds to assembling the system 10 for deployment into the casing or wellbore. The set configuration corresponds to anchoring the tool with the system 10 at the desired location in the casing or wellbore. The slip device 40 starts in the run-in configuration and can be expanded into the set configuration. The slip device 40 in the run-in configuration has an initial diameter. This initial diameter would be the smallest diameter for maneuvering through the casing or wellbore. The first spiral threaded inner slip surface 46 is in spiral threaded engagement with the first spiral threaded outer cone surface 22 in the run-in configuration. The second spiral threaded inner slip surface 48 is in spiral threaded engagement with the second spiral threaded outer cone surface 32, also in the run-in configuration. The first cone 20 is positioned at an initial distance from the second cone 30 within the slip device in the run-in configuration, and the second cone 30 is positioned at the secured axial and rotationally locked position on the mandrel 12 by the end housing 18 and within the slip device 40 in the run-in configuration.
[0061]The slip device 40 in the set configuration has an extended diameter that allows the slip device 40 to anchor to the casing or walls of the borehole. The extended diameter is larger than the initial diameter. The first cone 20 is positioned closer to the second cone 30 than the initial distance within the slip device 40 along the mandrel 12 in the set configuration. The first spiral threaded inner slip surface 46 is now in raised spiral threaded engagement with the first spiral threaded outer cone surface 22 in the set configuration. The second spiral threaded inner slip surface 48 is now in raised spiral threaded engagement with the second spiral threaded outer cone surface 32 in the set configuration. The second cone 30 is still positioned at the secured axial and rotationally locked position on the mandrel 12 by the end housing 18 and within the slip device 40 in the set configuration. The first cone 20 has moved closer by the piston housing 16 and the piston 14.
[0062]
[0063]
[0064]
[0065]Embodiments of the system 10 for anchoring include the piston housing 16 in removable threaded engagement or removable friction fit engagement with the first cone 20, as in
[0066]
[0067]Further embodiments of the slip device 40 being comprised of the barrel body 50 includes a slip locking means 54 to maintain the slip device 40 in the run-in configuration. The slip locking means 54 holds the slip device 40 in the run-in configuration at the initial diameter. When the downhole tool reaches the desired location in the casing or tubing, a threshold amount of load is applied to release the slip locking means 54 to allow the slip device 40 to expand from the initial diameter to the extended diameter of the set configuration.
[0068]
[0069]For the related embodiment of the slip device 40 as a barrel body 50 being comprised of a plurality of ribs 52, as in
[0070]
[0071]
[0072]
[0073]The present invention does require the first cone 20 to be oriented towards the second cone 30.
[0074]The present invention further includes a method for assembling the system 10 for anchoring the downhole tool. The method for assembling includes the step of positioning a slip device 40 having an outer slip surface 42 and an inner slip surface 44 around a mandrel 12 having a first mandrel end 13 and a second mandrel end 15 opposite the first mandrel end. The inner slip surface 44 is comprised a first spiral threaded inner slip surface 46 and a second spiral threaded inner slip surface 48, as in
[0075]The method for assembling further includes the step of affixing an end housing 18 around the mandrel 12 from the second mandrel end 15 and engaging the second cone 30 so as to prevent rotation of the second cone 30 and to prevent movement of the second cone 30 along the mandrel 12. Next, the method includes mounting a piston housing 16 around the mandrel 12 from the first mandrel end 13 and engaging the first cone 20, and mounting a piston 14 around the mandrel 12 from the first mandrel end 13 and through the piston housing 16. The piston 14 is between the mandrel 12 and the piston housing 16 with the slip device 40 in the run-in configuration. The first cone 20 is moveable along the mandrel 12 toward the second mandrel end 15 according to movement of the piston housing 16 along the mandrel 12 and toward the second mandrel end 15 by the piston 14.
[0076]Embodiments of the method for assembling can also include the step of installing a key member 60 removably mounted on the second cone 30 and extending into the slip device 40 so as to further prevent rotation of the second cone 30 relative to the slip device 40. For the embodiment of the slip device 40 as a barrel slip, the slip device 40 is comprised of a barrel body 50, and the barrel body 50 is comprised of a plurality of ribs 52. Each rib 52 is connected to an adjacent rib 52. The key member 60 is positioned between a rib 52 and a corresponding adjacent rib 52 so as to further prevent rotation of the second spiral threaded inner slip surface 48 relative to the second spiral threaded outer cone surface 32.
[0077]Alternate embodiments of the method for assembling address the mandrel 12 having a ratchet threaded portion 17. In that embodiment of the method, a locking ring 70 is installed in ratchet engagement with the ratchet threaded portion 17 around the mandrel and between the piston housing 16 and the first cone 20. The locking ring 70 is in removable engagement to the first cone 20 so as to further prevent backward axial movement of the first cone 20 away from the second cone 30 along the mandrel.
[0078]The present invention further includes the method of anchoring the system 10 to the casing or borehole, as in
[0079]The method for anchoring further includes the steps of radially extending the outer slip surface 42 further from the first spiral outer cone surface 22 in a raised threaded engagement than in the run-in configuration, and radially extending the outer slip surface 42 further from the second spiral outer cone surface 32 in the raised threaded engagement than in the run-in configuration. The first spiral inner slip surface 46 is in raised threaded engagement with the first spiral outer cone surface 22 in the set configuration, and the second spiral inner slip surface 48 is in raised threaded engagement with the second spiral outer cone surface 32 in the set configuration. For the embodiments of the mandrel 12 having a ratchet threaded portion 17 and the system 10 having a locking ring 70 in ratchet engagement with the ratchet threaded portion 17 around the mandrel 12 and between the piston housing 16 and the first cone 20, the method further includes the step of engaging the first cone 20 with the locking ring 70 along the ratchet threaded portion 17 during the step of positioning the first cone 20 close to the second cone 30 so as to further prevent backward axial movement of the first cone 20 away from the second cone 30 along the mandrel 12.
[0080]The present invention may further include reversing the steps of assembling for a method of disassembling. Rotating the first cone 20 in the opposite direction will separate the first cone 20 from the slip device 40. If the first cone 20 was not set properly, then the first cone 20 can be unscrewed from the slip device 40, even if the second cone 30 has already been inserted into the slip device 40. Unlike the prior art, the slip device is not deformed by expansion in order to fit over the straight threads. The slip device does not need to be re-expanded and further damaged in order to replace a cone. The present invention has reduced the risk of damage during assembly, such that disassembly is possible and may result in reuse of the slip device with a different set of cones.
[0081]The present invention provides an apparatus for anchoring a downhole tool to a casing or tubing within a borehole, according a spiral threaded engagement and a raised spiral threaded engagement between a slip device and first and second cones. The first cone is moved closer to the second cone within the slip device to expand the slip device from an initial diameter in the run-in configuration to an extended diameter in the set configuration. The initial diameter corresponds to the spiral threaded engagement, and the extended diameter corresponds to the raised spiral threaded engagement.
[0082]The spiral threaded engagement can be between a barrel slip with a spiral threaded inner slip surface and cones with spiral threaded outer cone surfaces. The spiral threaded inner slip surface is divided into a first spiral threaded inner slip surface and a second spiral threaded inner slip surface. The spiral direction of the first spiral threaded inner slip surface and the second spiral threaded inner slip surface oppose each other and correspond to the spiral threaded outer cone surfaces of the respective cones. The cones are also facing each other and have a spiral direction opposite to each other.
[0083]Further modifications are required beyond the conversion of straight threads to spiral threads, and particularly, the opposing spiral threads. The present invention includes multiple locking systems to prevent premature expansion and unscrewing or reverse rotating the cones from the slip device. The load exerted against the slip device cannot be re-directed to rotate the cones in the opposite directions to release the cones from the slip device. The present invention includes locks for the initial distance between the first cone and the second cone. The present invention includes locks for the ribs of a barrel slip as the slip device. The present invention further includes a key member to further support rotation locking the second cone. The present invention further includes the locking ring to further support one directional axial movement of the first cone.
[0084]The present invention provides a method of assembling a spiral threaded apparatus for anchoring a downhole tool to a casing or tubing with reduced risk of deformation and damaging the slip device as a barrel slip. Instead of deforming the components to snap-fit over straight threads, the cones of the present invention are inserted by rotating along the spiral threads. The assembly by screwing further results in possible disassembly by unscrewing. The reverse rotation will remove the cones from the slip device. If the first cone is not set properly, the first cone can be unscrewed from the slip device, even after the second cone has been inserted. In the prior art, the barrel slip is expanded to fit over the cones, and there is no way to remove either cone without damage to the barrel slip, if the cones need to be re-set. There is less risk of damage during disassembly, so some components of the present invention may be reuseable. The barrel slip has not been expanded to snap fit over the cones, and the barrel slip does not have to be damaged to remove one of the cones. The prior art snap-fit engagement of straight threads generally damages components during removal or any disassembly and prevents reuse. Additionally, the spiral threaded engagement and raised spiral threaded engagement distributes load capacity along the slip device, instead of isolating load capacity at the edges of straight threads. With such dependence on these edges of the straight threads, the spiral threads of the present invention are more robust and relax the tight tolerances of the prior art threaded surfaces.
[0085]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.
Claims
We claim:
1. A system for anchoring a downhole tool to a casing, comprising:
a mandrel having a first mandrel end and a second mandrel end opposite said first mandrel end;
a piston being mounted around said mandrel and being moveable from said first mandrel end toward said second mandrel end;
a piston housing being mounted around said piston and said mandrel, said piston being between said mandrel and said piston housing;
a first cone being mounted on said mandrel and having a first spiral threaded outer cone surface, said first spiral threaded outer cone surface being threaded in a first spiral direction, said piston housing being between said first mandrel end and said first cone,
wherein said first cone is moveable along said mandrel toward said second mandrel end according to movement of said piston housing along said mandrel and toward said second mandrel end by said piston;
a second cone being mounted on said mandrel and having a second spiral threaded outer cone surface, said second spiral threaded outer cone surface being threaded in a second spiral direction, said first spiral direction being opposite said second spiral direction, said first cone being between said piston housing and said second cone; and
a slip device being mounted on said mandrel between said first cone and said second cone and having an outer slip surface and an inner slip surface,
wherein said inner slip surface is comprised a first spiral threaded inner slip surface and a second spiral threaded inner slip surface, and
wherein said first cone faces toward said second cone within said slip device; and
an end housing being affixed to said mandrel, said second cone being between said end housing and said first cone, said end housing being removably engaged to said second cone so as to prevent rotation of said second cone and to prevent movement of said second cone along said mandrel,
wherein said slip device has a run-in configuration with an initial diameter, said first spiral threaded inner slip surface being in spiral threaded engagement with said first spiral threaded outer cone surface in said run-in configuration, said second spiral threaded inner slip surface being in spiral threaded engagement with said second spiral threaded outer cone surface in said run-in configuration, said first cone being positioned at an initial distance from said second cone within said slip device in said run-in configuration, and said second cone being positioned at a secured axial and rotationally locked position on said mandrel by said end housing and within said slip device in said run-in configuration,
wherein said slip device has a set configuration with an extended diameter, said first cone being positioned closer to said second cone than said initial distance within said slip device along said mandrel in said set configuration, said first spiral threaded inner slip surface being in raised spiral threaded engagement with said first spiral threaded outer cone surface in said set configuration, said second spiral threaded inner slip surface being in raised spiral threaded engagement with said second spiral threaded outer cone surface in said set configuration, and said second cone being positioned at said secured axial and rotationally locked position on said mandrel by said end housing and within said slip device in said set configuration, and
wherein said extended diameter is greater than said initial diameter.
2. The system for anchoring, according to
3. The system for anchoring, according to
wherein said outer slip surface is spaced further from said second spiral threaded outer cone surface in said raised spiral threaded engagement than in said spiral threaded engagement.
4. The system for anchoring, according to
5. The system for anchoring, according to
6. The system for anchoring, according to
7. The system for anchoring, according to
8. The system for anchoring, according to
9. The system for anchoring, according to
a key member being removably mounted on said second cone by said end housing so as to prevent rotation of said second cone relative to said slip device.
10. The system for anchoring, according to
wherein said slip device is comprised of a barrel body, said barrel body being comprised of a plurality of ribs, each rib of said plurality of ribs being connected to an adjacent rib of said plurality of ribs,
wherein said key member is positioned between a rib of said plurality of ribs and a corresponding adjacent rib of said plurality of ribs so as to prevent rotation of said second spiral threaded inner slip surface relative to said second spiral threaded outer cone surface.
11. The system for anchoring, according to
12. The system for anchoring, according to
a locking ring in ratchet engagement around said mandrel and being positioned between said piston housing and said first cone,
wherein said locking ring in removable engagement to said first cone so as to prevent axial movement of said first cone away from said second cone along said mandrel.
13. A method for assembling a system for anchoring a downhole tool, comprising the steps of:
positioning a slip device having an outer slip surface and an inner slip surface around a mandrel having a first mandrel end and a second mandrel end opposite said first mandrel end,
wherein said inner slip surface is comprised a first spiral threaded inner slip surface and a second spiral threaded inner slip surface;
mounting a first cone around said mandrel from said first mandrel end and into said slip device, said first cone having a first spiral threaded outer cone surface being threaded in a first spiral direction, said first spiral threaded outer cone surface being rotated relative to said slip device so as to be in spiral threaded engagement in said first spiral direction with said first spiral threaded inner slip surface;
mounting a second cone around said mandrel from said second mandrel end and into said slip device opposite said first cone, said second cone having a second spiral threaded outer cone surface being threaded in a second spiral direction, said first spiral direction being opposite said second spiral direction, said second spiral threaded outer cone surface being rotated relative to said slip device so as to be in spiral threaded engagement in said second spiral direction with said second spiral threaded inner slip surface, said slip device being in a run-in configuration with an initial diameter;
affixing an end housing around said mandrel from said second mandrel end and engaging said second cone so as to prevent rotation of said second cone and to prevent movement of said second cone along said mandrel;
mounting a piston housing around said mandrel from said first mandrel end and engaging said first cone; and
mounting a piston around said mandrel from said first mandrel end and through said piston housing, said piston being between said mandrel and said piston housing,
wherein said first cone is moveable along said mandrel toward said second mandrel end according to movement of said piston housing along said mandrel and toward said second mandrel end by said piston.
14. The method for assembling, according to
installing a key member removably mounted on said second cone and extending into said slip device so as to prevent rotation of said second cone relative to said slip device.
15. The method for assembling, according to
wherein said slip device being comprised of a barrel body, said barrel body being comprised of a plurality of ribs, each rib of said plurality of ribs being connected to an adjacent rib of said plurality of ribs,
wherein said key member is positioned between a rib of said plurality of ribs and a corresponding adjacent rib of said plurality of ribs so as to prevent rotation of said second spiral threaded inner slip surface relative to said second spiral threaded outer cone surface.
16. The method for assembling, according to
installing a locking ring in ratchet engagement with said ratchet threaded portion around said mandrel and between said piston housing and said first cone,
wherein said locking ring in removable engagement to said first cone so as to prevent backward axial movement of said first cone away from said second cone along said mandrel.
17. A method of anchoring, the method comprising the steps of:
deploying a downhole tool with the system having said slip device in said run-in configuration, according to the method for assembling of
positioning the downhole tool at a desired location in the casing;
exerting an axial force on said piston housing along said mandrel by said piston; and
positioning said first cone closer to said second cone than said initial distance within said slip device so as to place said slip device in a set configuration with an extended diameter, said extended diameter being greater than said initial diameter and holding the downhole tool at said desired location,
wherein a rotational force in said first spiral direction by said first cone on said slip device is offset by a counter rotational force in said second spiral direction by said second cone on said slip device, said end housing preventing rotation of said second cone and movement of said second cone along said mandrel.
18. The method for anchoring, according to
19. The method for anchoring, according to
radially extending said outer slip surface further from said first spiral outer cone surface in said raised threaded engagement than in said run-in configuration; and
radially extending said outer slip surface further from said second spiral outer cone surface in said raised threaded engagement than in said run-in configuration.
20. The method for anchoring, according to
wherein said mandrel has a ratchet threaded portion, and
wherein the system further comprises a locking ring in ratchet engagement with said ratchet threaded portion around said mandrel and between said piston housing and said first cone, the method further comprising the step of:
engaging said first cone with said locking ring along said ratchet threaded portion during the step of positioning said first cone close to said second cone so as to prevent backward axial movement of said first cone away from said second cone along said mandrel.