In one aspect, the invention relates generally to the use of a progressive cavity pump (PC Pump) for pumping water downhole for disposal and more particularly to a bearing package for resisting reactive rotor loads of a PC Pump for pumping water downhole for disposal. In another aspect, the invention relates generally to complementary male/female profiled latch components which are applied in a variety of downhole operations to releasably couple components such as for coupling a pump rotor to a bearing package or drivably coupling a pump rotor to surface through a rod string.
It has been a long recognized problem that during production of hydrocarbons, particularly from gas wells, liquids, primarily water, accumulate in the wellbore. As the liquid builds at the bottom of the well, a hydrostatic pressure head is built which can become so great as to overcome the natural pressure of the formation or reservoir below, eventually “killing” the well.
A fluid effluent, including liquid and gas, flows from the formation and through perforations in the casing. Liquid accumulates as a result of condensation falling out of the upwardly flowing stream of gas or from seepage of liquids from the formation itself. To further complicate the process the formation pressure typically declines over time. Once the pressure has declined sufficiently so that production has been adversely affected, or stopped entirely, the well must either be abandoned or rehabilitated. Most often the choice becomes one of economics, wherein the well is only rehabilitated if the value of the unrecovered resource is greater than the costs to recover it.
Many techniques have been utilized to attempt to remove liquids which have accumulated in the wellbore. Of these many techniques some are focused on lifting liquids uphole to the surface, such as in gas or plunger lift systems. Other techniques have been focused on pumping water below the producing zone and into a lower portion of the formation that can act as a reservoir to accommodate the pumped water. These techniques are typified by arrangements that collect liquids below a conventional uphole-pumping pump, pump them slightly uphole and them route them back downhole through bypass tubing. These arrangements are subject to loss of head pumping failures in attempting to establish suction under low head conditions to pump uphole.
Described herein is a combination of novel elements which enable convenient and effective implementation of a system of direct pumping of liquid to a lower formation for disposal. In a preferred embodiment, a novel arrangement of a PC Pump is applied for pumping downhole through a packer, the rotor being rotatable yet axially restrained in a novel manner against uphole reactive loading and a novel latch being releasably coupled to the rotor.
In one aspect of the invention, a releasable coupling or latch is provided. While the disclosed embodiments are predominately downhole implementations, the latch can be used as surface as well, for instance, to drivably couple a top drive to a polish rod. Further, the latch has characteristics such as being preferably sufficiently compact to be insertable through the PC Pump's stator. In another downhole pumping situation, large PC Pumps can be suspended at the end of tubing. However, the corresponding and large rotors are too large to insert or remove through the tubing string. Accordingly, in this situation, there is a need for a torque-capable releasable coupling between the drive rod string and the uphole end of a rotor which remains in the stator of the PC Pump.
A qualifying releasable coupling for each of these scenarios is a telescopically coupled plunger and latch housing having complementation radial dogs and a track which implement downhole and uphole manipulation therebetween to effect an automatic, indexed relative rotation therebetween to alternately lock and release the coupling while further enabling the transmission of torque as desired. The tool is implemented in an alternating on/locked and off/released manner.
In one broad aspect of the invention apparatus for releasably coupling first and wellbore components, at least one of the first or second wellbore components being capable of rotation in response to applied rotational force, comprises a housing adapted for connection to the first wellbore component and having a bore with a first half of a dog and track arrangement formed thereto having at least one dog; and a plunger adapted for connection to the second wellbore component and being sized to fit telescopically axially into and out of the bore, the plunger having a second half of the dog and track arrangement formed thereto, the track of the dog and track arrangement having at least one entrance to and from a circumferential portion, the circumferential portion bounded by a discontinuous proximal cam, through which the at least one entrance extends, and a distal cam spaced from the proximal cam, so that
In another broad aspect, the apparatus enables practicing a novel method for releasably coupling a first wellbore component to a second wellbore component, comprising: telescoping the plunger into the housing for guiding the one or more dogs through corresponding entrances into the track and engaging the track to causing relative rotation between the housing and the plunger until engaging a first rotational stop in a first rotationally and axially coupled position out of alignment with the corresponding entrances, and telescoping the plunger out of the housing for engaging the track and causing relative rotation between the housing and the plunger until engaging a second rotational stop in a second rotationally and axially coupled position out of alignment with the corresponding entrances, and telescoping into the housing for engaging each dog with the track to causing relative rotation between the housing and the plunger until engaging a third rotational stop substantially aligned with the corresponding entrances, and telescoping the plunger out of the housing for guiding each dog through the corresponding entrances to release the plunger from the housing.
Preferably, the releasable coupling is located between the downhole end of a rotor of a PC Pump and an uphole end of a bearing assembly spaced below the PC Pump.
In another aspect of the invention, a PC Pump is used to pump liquid directly downhole for disposal. However, Applicant's recognize that the rotor of the pump must be held down into position in the stator during this operation.
In one broad aspect of the invention apparatus is located in the casing of a wellbore for injecting liquid to a lower formation with a PC Pump having a rotor and a stator, comprising: a packer set in the casing above the formation and adapted for pumping liquids, from uphole of the packer, downhole through the PC Pump and into the lower formation; and a bearing assembly positioned downhole of the PC Pump and spaced from the stator, a shaft connected to the rotor and bearings for rotatably supporting and axially restraining the rotor to the bearing assembly so that as the PC Pump rotor rotated to pump liquid through the stator from above the packer to the formation below the packer, uphole loads acting on the rotor are restrained through the bearing assembly.
The apparatus enables operation of a method for injecting liquid from a wellbore into a lower formation comprising anchoring the packer in the wellbore above the lower formation; rotating the rotor for pumping liquids from uphole of the packer downhole through the PC Pump and into the lower formation; and supporting the rotor with a bearing assembly positioned downhole of the PC Pump and spaced from the stator.
Accordingly, in another aspect of the invention, a bearing assembly is provided for restraining uphole movement of a PC Pump rotor while pumping water downhole for disposal. The bearing assembly comprising a shaft extending through a bore in a housing and having bearings rotatably supporting the shaft from the housing, an uphole seal for sealing between the rotatable shaft and the housing; and a downhole seal for sealing the bore of the housing so as to protectively sandwich the bearings therebetween. Preferably, the uphole seal further comprises a first seal face sealed and rotatable with the shaft and biased to rotatably seal against a second seal face supported by and sealed to the housing. The bearing assembly is preferably pressure equalized having a piston in the bore of the housing and having annular seals therebetween; and a spring biasing the piston downhole so that the piston is sealably slidable in the bore for equalizing pressure between the formation and the bore.
Further, the rotor is preferably removable for maintenance. There are a variety of mechanisms to releasably couple downhole components including collets and shear devices. Due to the inaccessibility of the downhole location and the need for gross movements to effect actuating movement at the point of coupling, there is a need for a reliable and simple coupling device. As set forth above, one downhole operation which is critically dependent on the ability to releasable couple two downhole wellbore components is a situation wherein a PC Pump rotor is restrained against uphole movement as opposed to the conventional restraint against downhole movement during uphole pumping activities.
a is a downhole end view of the bearing assembly housing according to
b is a cross-sectional view of the bearing assembly housing, latch housing and plunger according to
c is a cross-sectional view of the latch housing and plunger according to
a is an end view of a latch housing according to
b is a cross-sectional view of the latch housing according to
a is a downhole end view of a latch plunger adapted for connection to the rotor of a PC Pump, the plunger being adapted for latching with the latch housing and latch dogs according to
b is a cross-sectional view according to
c is a side view of the latch plunger according to
d is a cross-sectional view according to
e is a cross-sectional view according to
a is a perspective view of the latch plunger according to
b is a partial perspective view of an upper profiled track and a lower profiled track of the plunger assembly according to the cutaway E of
c is a side view of the upper profiled track according to cutaway F of
d is a partial side view of the lower profiled track according to the cutaway D of
a–c are partial side views illustrating the housing and plunger of another embodiment of the invention, operating according to the principles set forth in
a illustrates the latch plunger entering a bore of the latch housing,
b illustrates the latch plunger being pushed into the latch housing, rotating the latch housing to cause a latch dog to engage the upper latch track, and
c illustrates pulling the plunger uphole to cause the latch housing to rotate and the latch dog to lock into the lower profiled track;
a and 10b together illustrate a cross-sectional view of a wellbore casing according to an embodiment of the invention wherein a stator of a PC Pump is connected to a tubing string and wherein the rotor is installed through the tubing string and into the stator, the lower end of the rotor being latched into a lower bearing assembly for pumping liquid water downhole, the packer, an optional anchor and a one way valve being illustrated in schematic form only;
a and 11b together illustrate a cross-sectional view of a wellbore casing according to another embodiment of the invention wherein the rotor of a PC Pump, anchored downhole, is lowered into the stator using co-rod, coiled tubing or the like, and is latched into a lower bearing assembly for pumping liquid water downhole;
With reference to the schematic of
Each of the bearing assembly 14, the disposal system 10 and the coupling means 15 are discussed herein.
Generally, with reference to schematic
The bearing assembly 14 is spaced and supported from the stator 16 via the pup-joint connection 22 for resisting the loads placed thereon by the rotor. The stator 16 is typically supported in the casing 19 with the packer 12. Use of a convention anchor is optional in conjunction with the packer 12 or if the packer 12 is not rotationally supporting the stator 16.
Similarly in the embodiment of
The packer 12, preferably a hydraulic packer, is set adjacent a bottom of the well above the lower formation 30 into which water can be disposed. The operation of the system is described in greater detail below.
As shown in
Water Disposal
For implementing an embodiment of the disposal invention, as shown in
The rotor 12 is lowered into and through the stator 16 until the plunger 61 engages the latch housing 60 and the rotor 12 is locked into position in the bearing assembly 14. Pumping can then begin.
In a second embodiment of the invention, as shown in
Bearing Assembly
With reference to
As shown in FIGS. 1,10b, the bearing assembly 14 does not impede the casing 19 so that disposed liquid 20 can pass thereby. A bypass of the bearing assembly can be through the assembly itself (not shown) or, as shown, can be around the assembly through an annular passage 32 formed between the assembly 14 and the casing 19.
As shown in
A latch housing 60 is connected at an uphole end of the inner shaft 42 and is adapted for latching to a plunger 61 adapted for connection to the rotor 13 of the PC Pump 11. The inner shaft 42 is supported for rotation and against reactive axial loading. One or more lower thrust bearings 43 are positioned adjacent a lower end of the shaft 42. One or more upper radial bearings 44 are fit adjacent an upper end of the inner shaft 42. While preferably the upper bearings 44 support radial loading, they may also support axial thrust. Similarly, why it is preferred that the lower bearings 43 primarily support thrust, they may also be specified to support radial loading as well. The lower and upper bearings 43,44 are isolated from well liquids 20 with a sealing system.
The lower thrust bearings 43, such as angular contact ball bearings, are fit to an annular space 45 created between the inner shaft 42 and the non-rotating outer housing 40. A nut and washer assembly 46 secure the lower end of the inner shaft 42 to the lower thrust bearings 43 which are rotationally supported through a shoulder 47 formed in the outer housing 40. The annular space 45 is sealed from the wellbore environment by upper seals 50a,50b and a lower seal 51. The lower seal 51 is formed between a spring-biased lower piston 52 between the lower bearings 43 and the outer housing 40. The lower seal 51 is a non-rotating seal sealably and slidably fit to the non-rotating outer housing 40. The lower piston 52 is spaced downhole of the lower end of the inner shaft 42 creating a reservoir for clean lubricating fluid in fluid communication with the annular space 45 for lubricating the bearings 43,44.
The inner shaft 42 is further supported against lateral and radial loading by the upper radial bearings 44 such needle bearings positioned in the annular space 45 adjacent an upper seal housing 53 positioned between the upper seal 50 and the outer housing 40. The upper seal housing 53 is located above the upper bearings 44. The upper seals 50a,50b seal despite relative rotation between the inner shaft 42 and the housing 40.
The upper seals 50a,50b preferably comprise opposing, mirrored tungsten or silica carbide seal faces. A first rotating upper seal 50b is connected to the inner shaft 42 by the upper seal housing 53 and a second static upper seal 50a is connected to the outer housing 40 below the first rotating upper seal 50b. The first rotating upper seal 50b is biased towards and rotates upon the second static seal face 50a in a sealed relationship so as to substantially prevent the loss of lubricant from the annular space 45.
The lower seal's lower piston 52 acts to equalize pressure within the annular space 45 to be substantially that in the wellbore. Further, the lower piston 52 has a preload spring 54 which allows it to react to small losses of lubricant from the bearing assembly annular space.
As shown in
Latch
In greater detail and with reference to
As shown in
As shown in
With reference to
In the illustrated embodiment of
With reference to
The track 80 is adapted to sequentially accept the one or more dogs 70 through the entrances 64; guide and lock the dogs therein and then release the dogs. Each entrance 64 leads to a track's circumferential portion 80c bounded with a uphole cam 67, proximal the entrances 64, and a downhole cam 69 spaced from the entrances 64 and from the uphole cam profile 67. The uphole cam is discontinuous, interrupted circumferentially by entrances 64.
The uphole and downhole orientations are for reference only, pertinent for this embodiment, and could be inverted in other embodiments.
Angled downhole faces 66 of the segments 63 guide the dogs 70 into their respective entrances 64. Uphole faces of the segments form a discontinuous downhole cam 67, interrupted by the entrances 64. Spaced uphole from the downhole cam 67 is a shoulder 68 forming an uphole cam 69. The uphole and downhole cams 69,67 are spaced sufficiently apart to permit circumferential and stepwise movement of the dogs 70 therebetween.
The downhole cam 67 guides each dog's trailing edge 72 and the uphole cam guides each dogs' leading edge 71 through the track's circumferential portion 80c. The track 80 enables alternating the plunger 61 between a coupled position and a released position. The uphole and downhole cams are formed with angled faces complementary to each dog's leading and trailing edges respectively.
The plunger and latch housing are in a coupled position occurs in at least one instance when the plunger 61 is being pulled axially way from the latch housing 60 wherein each dog's trailing edge 72 engages the downhole cam 67 (tensile forces acting between the plunger 61 and the latch housing 60). The plunger and latch housing can be locked in a second instance when the plunger 61 is engaged fully into the latch housing 60 and each dog's leading edge 71 engages the uphole cam 69 (compressive forces acting between the plunger 61 and the latch housing 60).
More specifically, and with reference to the rolled-out view of the plunger 61 and latch housing in
As shown at A, in a first action, the plunger 61 is stabbed into the housing (FIGS. 8,9a). Downhole force applied to the plunger 61 results in engagement of each dog's leading edge 71 with each segment's angled downhole face 66 causing relative rotation of the latch housing 60 and plunger 61, typically causing the latch housing 60 to rotate sufficiently to permit the dogs 70 to align with and pass axially through each entrance 64, at B, and into the circumferential portion 80c between the uphole and downhole cams 69,67.
With reference to
With reference to
In
In a third action from D to E, as shown further in the general case of
In a fourth action, at F, uphole movement of the plunger 61 aligns each dog 70 once again with each entrance 64 for release of each dog from the track 80 wherein each dog 70 and the plunger 61 telescope out of the latch housing 60 to be released at G.
Turning to
With reference to
This application claims the benefits under 35 U.S.C. §119(e) of the U.S. Provisional Application Ser. Nos. 60/406,338, filed Aug. 28, 2002, and 60/452,942, filed Mar. 10, 2003, each of which is incorporated fully herein by reference.
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Number | Date | Country | |
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20040129430 A1 | Jul 2004 | US |
Number | Date | Country | |
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60452942 | Mar 2003 | US | |
60406338 | Aug 2002 | US |