The present invention relates to progressing cavity devices, and more particularly to stators of progressing cavity devices that can pass fluids containing solids.
Progressing cavity pumps are frequently used in applications to handle highly viscous fluids and fluids containing solids. Depending on the size and shape of the solids, the pump can frequently pass the solids through the pump if the solid is smaller than the cavity volume within the pump. If the solids are larger than the cavity then the solids can get jammed between the rotor and stator and cause the pump to lock up.
Power sections are used on directional drilling motors to provide the rotary motion to the drill bit as drilling mud is pumped through the power section. The usual failure mechanism for the power section stator is chunking of the rubber as it fatigues due to cyclic loading. The chunking usually commences at the end of the stator where the rotor is connected to the bearing assembly of the motor due to the sideload from the constant velocity joint or flex shaft. The chunking mechanism results in pieces of rubber breaking off of the rubber power section stator profile. These pieces of rubber can travel through the drilling motor and into the drill bit where they can plug the bit nozzles. If the bit nozzles become plugged then the drilling mud can no longer be pumped through the motor and the drilling operation has to stop resulting in costly downtime.
The following detailed description refers to the accompanying drawings. The same reference numbers in different drawings may identify the same or similar elements.
Existing progressing cavity pumps and power sections do not have any mechanisms to break up solids that may need to pass through. In a progressing cavity pump, solids (such as rocks and debris) may be sucked into the pump and become jammed between the rotor and stator. Conversely in a power section, solids (such as rubber chunks from a section of a stator) may pass through an outlet of the stator and block nozzles or other downstream components.
According to an implementation described herein, cutting surfaces are included at an inlet of a progressing cavity pump. The cutting surfaces are included within a section of a stator made from multiple cutter disks to break up the solids into smaller pieces so they easily pass through the pump. The cutting action is created by the pump rotor orbiting within the cutter disks. Cutter disks may also be included at the outlet of the pump to further break up the solids for easier passage through the rest of a system after the pump.
According to another implementation, cutting surfaces are included at an outlet of a power section. The cutting surfaces are included within a section of a stator made from multiple cutter disks to break up any rubber chunks into smaller pieces so they can pass through the drill bit nozzles without plugging the drill bit. The cutting action is created by the power section rotor orbiting within the cutter disks. Cutter disks may also be included at the inlet of the power section to further break up any solids that may be in the drilling mud system to aid the solids passing through the power section, motor and drill bit.
Stator 12 includes at least one working stator section 20 and at least one cutting stator section 30 housed within a cylindrical outer housing or stator casing 26. In the example of FIG. 1A, a cutting stator section 30 is shown on both sides of the working stator section 20. Working stator section 20 and cutting stator sections 30 may be axially aligned within stator casing 26.
Working stator section 20 may include multiple helical lobes that generally conform to a profile of rotor 14. In one implementation, working stator section 20 includes an elastically deformable elastomeric material, such as rubber, with an even or smooth profile. When using the elastically deformable elastomeric material, working stator section 20 may be dimensioned so that the helical lobes of working stator section 20 form an interference fit, relative to rotor 14, under expected operating conditions. Stator 12 and rotor 14 thereby form continuous seals along their matching contact points which define the progressing cavities 18. As shown in
Cutting stator section 30 includes multiple like-shaped lobed cutter disks 32. As can best be seen in
As shown in
Cutter disks 32 may be placed into the helical configuration of cutting stator section 30 by stacking cutter disks 32 onto an alignment assembly via means for stacking, including an alignment mandrel/core with a profile that catches lobes 33 of the disks with its profile cut in a helical pattern in the alignment core. Cutter disks 32 may also be aligned with an alignment assembly including a jig which interacts with disk features other than the inner profile or through features built into the disks (e.g., apertures through the disk lobes) that rotate each disk slightly (e.g., approximately 15°) relative to neighboring disks.
Each of cutter disks 32 may include a forward edge 35a and a rearward edge 35b (referred to collectively as “edges 35” or generically as “edge 35”) extending along a perimeter of opening 34. Each of cutter disks 32 may have a thickness, T, which also defines a depth of the opening 34 through each cutter disk 32. A surface 36 along the interior of opening 34 extends in the convoluted shape for the thickness T when measured in a direction parallel to the common centerline.
The thickness of the disks determines the size of the step between edges 35 as they are aligned into the desired helical formation—the thicker the disk, the larger the step. As shown, for example, in
Forward edge 35a is formed at the intersection of interior surface 36 and a side surface 37a (also referred to as a front surface), while rearward edge 35b is formed at the intersection of interior surface 36 and an opposite side surface 37b (also referred to as a rear surface). In one implementation, side surface 37a and side surface 37b may define parallel planes, with interior surface 36 being perpendicular to each of side surface 37a and side surface 37b along the entire perimeter of opening 34. The slight rotation of cutter disks 32, relative to each other, around the centerline within the helical configuration of cutting stator section 30 exposes different portions of edges 35. The exposed edges 35 may function as cutting edges. For example, in the cross-sectional portion of
Cutter disks 32 may be manufactured in a variety of ways, with preferred methods including machining via laser, water jet, electrical discharge machining (EDM), milling etc. or a stamping/punching process. They may also be made to shape originally by casting, powder metallurgy or any similar process. In one implementation, cutter disks 32 may be formed from metal, such as a hardened tool steel from one of the American Iron and Steel Institute (AISI) grades of tool steel. In other implementations, a different material may be used to form disks 32. Cutter disks 32, and particularly edges 35, may be sufficiently hard to engage and break up particulates forced between edges 35 and rotor 14. A driving force behind the method of disk manufacture is the disk material and the cost of manufacture for that material. For example stamping is cost effective for some disks made of metals but unfeasible for disks made of ceramics.
In some cases it is necessary to tighten the alignment of cutter disks 32 in cutting stator section 30 by the application of force to the outer diameter of the stack by, for example, swaging, v-blocking or hammering in either a static or rotating condition. Cutting stator section 30 is set by fixing the rigid cutter disks 32 together with a bond provided by, for example, welding, fusing, soldering, brazing, sintering, diffusion bonding, mechanical fastening, or via an adhesive bond. The stator casing 26, which preferably is made of metal, may be straightened, chamfered, machined, cleaned and heated as required. Stator casing 26 is another bonding member that may then be slid over cutting stator section 30 and bonded together (e.g., welding, fusing, soldering, brazing, sintering, diffusion bonding, mechanical fastening, adhesive) to further fix the rigid cutter disks 32 together. The alignment assembly may then be removed from the disk stack 30. Depending on the disk stack alignment methodology, it may be required or preferred to insert the disk stack 30 into stator casing 26 without the alignment tooling entering stator casing 26 as well.
Cutting stator section 30 includes multiple like-shaped lobed cutter disks 82. As can best be seen in
As shown in
Similar to cutter disks 32 described above, cutter disks 82 may be placed into the helical configuration of cutting stator section 30 by stacking cutter disks 82 onto an alignment assembly. Each of cutter disks 82 may include a forward edge 35a and a rearward edge 35b extending along a perimeter of opening 84. Each of cutter disks 82 may have a thickness, T, which also defines a depth of the opening 84 through each cutter disk 82. A surface 86 along the interior of opening 84 extends in the convoluted shape of opening 84 for the thickness T. Forward edge 35a is formed at the intersection of interior surface 86 and a side surface 37a, while rearward edge 35b is formed at the intersection of interior surface 86 and opposite side surface 37b (not visible in figures). The slight rotation of cutter disks 82, relative to each other, around the centerline within the helical configuration of cutting stator section 30 exposes different portions of edges 35. The exposed edges 35 may function as cutting edges.
In implementations described herein, a stator for a helical gear device includes a first (or “working”) section having first helically convoluted chamber with a set of radially inwardly extending lobes and a second (or “cutting”) section adjacent to, and axially aligned with, the first section. The second section includes a stack of cutter disks. Each of the cutter disks includes a front surface, a rear surface, an interior surface defining a central opening extending from the front surface to the rear surface, a first cutting edge along the front surface and the interior surface (also referred to as the forward edge), and a second cutting edge along the rear surface and the interior surface (also referred to as the rearward edge). The interior surface forms a same number of lobes for the central opening as the set of radially inwardly extending lobes in the first section. Each of the cutter disks is aligned along a common centerline, and each of the cutter disks is rotated slightly relative to each other such that the stack of cutter disks forms a second helically convoluted chamber with a same pitch as the first helically convoluted chamber. The second helically convoluted chamber in the stack of the cutter disks exposes, to materials passing through the second helically convoluted chamber, portions of the first cutting edge or the second cutting edge of each of the cutter disks.
The foregoing description of exemplary implementations provides illustration and description, but is not intended to be exhaustive or to limit the embodiments described herein to the precise form disclosed. Modifications and variations are possible in light of the above teachings or may be acquired from practice of the embodiments.
Although the invention has been described in detail above, it is expressly understood that it will be apparent to persons skilled in the relevant art that the invention may be modified without departing from the spirit of the invention. Various changes of form, design, or arrangement may be made to the invention without departing from the scope of the invention. Different combinations illustrated above may be combined in a single embodiment. For example, any of the arrangements or types of working section 20 shown in connection with progressing cavity pump section 10 (e.g.,
No element, act, or instruction used in the description of the present application should be construed as critical or essential to the invention unless explicitly described as such. Also, as used herein, the article “a” is intended to include one or more items. Further, the phrase “based on” is intended to mean “based, at least in part, on” unless explicitly stated otherwise.
This application is a continuation of U.S. patent application Ser. No. 15/724,362, filed Oct. 4, 2017, which claims priority from claims priority under 35 U.S.C. § 119, based on U.S. Provisional Patent Application No. 62/414,874 filed Oct. 31, 2016, the disclosures of which are incorporated by reference herein.
Number | Name | Date | Kind |
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3975121 | Tschirky | Aug 1976 | A |
4144001 | Streicher | Mar 1979 | A |
5832604 | Johnson | Nov 1998 | A |
7396220 | Delpassand | Jul 2008 | B2 |
Number | Date | Country | |
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20200284262 A1 | Sep 2020 | US |
Number | Date | Country | |
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62414874 | Oct 2016 | US |
Number | Date | Country | |
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Parent | 15724362 | Oct 2017 | US |
Child | 16881753 | US |