The term “positive displacement motor” (or “PDM”) is used interchangeably in this disclosure with the term “PDM power section” for short form convenience unless stated otherwise. A PDM power section conventionally comprises a PDM stator and associated rotor, as is well known in the art. Positive displacement motors (PDMs) are conventionally placed above the bit in subterranean oil and gas drilling. Drilling operations (both conventional and directed) gain advantage when PDMs can deliver high power output. Stiff, high modulus elastomers deployed in the stators assist in high power delivery. Such elastomers (rubbers) form tight pressure pockets in helical progressing cavities where the rotor lobes are in interference fits with the stator lobes.
High power PDMs derive and build desirable high torque from high fluid pressure drops across the length of the PDM. High power PDMs are advantageously designed to be “inefficient” or “leaky” at the rotor lobe/stator lobe interference fits across the entire length of the PDM to enable a high pressure drop from inlet to outlet. Ideally, the fluid pressure drops linearly from max at inlet to zero at outlet. As a result, all stages of the PDM become available to build torque. Ideally, an overall fluid pressure drop above 180 psi per stage will produce acceptable high power drilling efficiency (although this example is non-limiting and offered for illustration only).
“Leaky” interference fits nonetheless lead to stress concentrations in the stator rubber, especially at points of contact between rotor lobes and stator lobes. This effect is magnified when the stator rubber is a stiff, high modulus material. “Leaky” interference fits can also contribute to or be associated with PDM performance issues, one of which is rotor tilt.
“Rotor tilt” refers to displacement of the rotor off its expected eccentric orbital rotation path by imbalanced forces that arise across the rotor. Rotor tilt may sometimes be referred to in this disclosure as “rotor deflection”. Rotor tilt is a common problem seen in high power PDMs designed to be “inefficient” or “leaky” in order to promote high torque generation. Rotor tilt is particularly problematic in the final region near the outlet end of such PDMs.
Rotor tilt is initially caused by high fluid pressure at the inlet end bearing upon a larger rotor surface area on the non-eccentric side of orbital rotation than on the eccentric side. The resulting net force causes to the rotor to displace (tilt) eccentrically, such that the rotor lobe on the eccentric side “digs” into the stator valley as it rolls over the stator valley. The rotor's eccentric displacement causes the interference fits between rotor and stator lobes on the non-eccentric side to separate, causing additional leakiness. This rotor tilt effect continues along the length of the PDM towards the outlet until a critical point is reached. This critical point is typically located at about 10% PDM length to about 50% PDM length from the outlet. The imbalanced force kinetics change at this point. In the final region near the outlet, lower overall ambient fluid pressure and leaky interference fits reduce the local pocket pressures on the non-eccentric side of the rotor. As the outlet approaches, these local pressures cap tend towards zero. Meanwhile, ambient fluid pressure continues to exist on the eccentric side of the rotor where there is no leakiness. The resulting net force across the rotor causes the rotor now to displace (tilt) non-eccentrically, such that the rotor lobes on the non-eccentric side (either side of open pockets) “dig” into stator lobes. This causes high stress concentrations on the stator lobes. High rubber strains are required to enable the rotor lobes to pass over the stator lobes as the rotor rotates. Many rubbers, and especially high modulus rubbers, lack the elongation to permit the strain, causing rupture and tearing of the stator lobes. Moreover, stall (or near stall) events can occur as leaky interference fits make local pocket pressures on the non-eccentric side of the rotor tend towards zero.
The foregoing general description of rotor tilt is illustrated schematically on
Stator 11L, 11M and 11R;
Rotor 12L, 12M and 12R;
Rolling contact 13L, 13M and 13R;
Interference fits 14L, 14M and 14R;
Directions of rotor rotation 151, 15M and 15R;
Nominal (design) orbits of rotation of rotor centers 16L, 16M and 16R; and
Actual orbits of rotation of rotor centers 17L, 17M and 17R.
Power section view 10B on
Power section view 10A on
Power section view 10C on
The prior art does not appear to have addressed the problem of rotor tilt as seen in high power PDMs. Certain references have addressed remediation of stator rubber stress concentrations due to other performance issues such as thermal expansion and PDM bending in deviated wells. Some references speak directly to thermal expansion remediation in progressing cavity pumps (PCPs). These references are not germane to the design considerations set forth herein for addressing rotor tilt in PDMs. It is well understood that ambient fluid pressures drop in a PDM as the fluid travels from the inlet end (near the surface) to the outlet end (near the bit). This is opposite to PCPs, in which ambient fluid pressure is lowest at the inlet end, and increases as the fluid is lifted towards the outlet. Indeed, conventional PCP technology such as described in U.S. Pat. No. 5,722,820 (“Wild”) and S. B. Narayanan, Fluid Dynamic and Performance Behavior of Multiphase Progressive Cavity Pumps (Thesis submitted to the Office of Graduate Studies of Texas A&M University, August 2011) do not acknowledge or address rotor tilt as an effect. As noted, these references are concerned exclusively with remediating rubber friction due to thermal expansion and multiphase fluid volume changes. Moreover, the PCPs disclosed in Wild have low rotor eccentricity at the inlet and high rotor eccentricity at the outlet, which, as further described herein, is the opposite result of the effect of rotor tilt in a PDM.
U.S. Pat. No. 9,869,126 (“Evans”) discloses a variety of high-level solutions to elastomer stress issues in both PCPs and PDMs. Problems sought to be addressed in Evans include wear of the elastomer from (a) elevated temperature, (b) solids in the drilling fluid, (c) corrosive drilling fluid, (d) swelling, (e) misalignment of mechanical parts, and (I) bending of the PCP/PDM in deviated wells. Rotor tilt is not acknowledged or addressed. Evans is thus also not germane to the design considerations set forth herein for addressing rotor tilt in PDMs.
U.S. Published Patent Application 2019/0145374 (“Parhar”) discusses pressure distributions in PDM power sections, but does not address rotor tilt. Paragraph 0079 of Parhar states that the effects of angular deflection of the rotor may be considered negligible for the purpose of Parhar's disclosure. Parhar's disclosure further does not contemplate rubber damage issues near the outlet end and/or stall events.
Parhar thus does not address the rubber stress concentrations, particularly at the outlet end, that are characteristic of PDMs susceptible to rotor tilt. Parhar does not address the stall events, torque loss and stator damage caused by rotor tilt. Parhar is therefore not germane to the design considerations for addressing rotor tilt in PDMs as set forth in this disclosure.
It should be noted that rotor tilt is essentially independent of the number of stages that a particular PDM may provide, and thus is indifferent to such configurations. Observation and remediation of rotor tilt is based on the entire length of the PDM from inlet to outlet. PDMs typically see the adverse effects of rotor tilt take the form of significant elastomer stress in a region from zero to 25%-50% of the PDM's overall length measured from the outlet. As noted, rotor tilt moves the rotor off its normal orbital rotation, which causes increased friction at points of contact between rotor and stator. As rotor tilt increases, stall and near-stall loading events may cause more serious stator damage, and even failure. Elastomeric linings may deflect as much as 40% strain when rotor tilt is creating stall conditions, whereupon all fluid may bypass rotor/stator interfaces, sending the rotor output RPM to zero.
Higher modulus rubbers tend to call for higher fluid pressures at stall, although the strain required to stall the motor does not change significantly. The increase in pressure gradient in higher modulus rubber deployments has the effect instead of creating a more pronounced rotor tilt over the PDM's length than might be seen with lower modulus materials. In addition, higher modulus materials typically have a reduced elongation at break than lower modulus materials, suggesting that rotor tilt is more likely to cause stator lobe tear and breakoff in higher modulus deployments.
For example, power section designs using elastomer compositions with 100% modulus greater than 800 psi are optimal to increase drilling efficiencies. However, the elongation at break for such stiffer and harder rubbers is reduced from over 300% (as seen in softer rubbers) to less than 270% and as low as 80%. The required elongation to survive a stalling event is at least approximately 35% to 50% strain. This approximate strain range is the deflection required to cause the motor to bypass 100% of the fluid and bring the output rpm to zero (stall). This strain range is further substantially independent of stiffness. The potential for stiff and hard rubbers to exceed the elongation at break (tensile strength) during rotor tilt, and thereby tear the elastomer, becomes much higher.
Further, the rotor may become so tilted, and the local fluid pressure drop from leaky interference fits may become so great that too much torque is lost to sustain rotor rotation. The rotor stalls. This can be a catastrophic event. The bit stops. However, the borehole assembly components above the PDM may continue to rotate. The rotor responds by oscillating and “thrashing about” in an uncontrolled orbital rotation. This uncontrolled rotor motion may cause extensive local damage to the stator, transmission and other components.
There is therefore a need in the art for design technology directed exclusively to remediating the adverse effects of rotor tilt in PDMs.
This disclosure describes embodiments of tapered stator designs that are engineered to reduce the stress concentration at the lower end of the power section in the presence of rotor tilt. The disclosed technology is particularly advantageous in high modulus rubber deployments, although the scope of this disclosure is not limited to high modulus rubber materials. A contoured stress relief (i.e. a taper) is provided in the stator to compensate for rotor tilt, where the taper is preferably more aggressive at the lower end of the stator near the bit. Preferably, the taper is engineered into the minor diameter of the stator profile and thus modifies the stator lobe height only. The scope of this disclosure is not limited, however, to tapers on the minor diameter of the stator. Minor diameter taper embodiments on the stator allow the rotor to remain unmodified. This in turn allows the full design cross section of the rotor to be maintained. This is advantageous, since tapering the rotor (and thereby reducing cross section) might otherwise diminish the rotor's overall strength. Further, removing material from the rotor might destabilize the rotor at high rpm. Tapering the stator instead, preferably on the minor diameter of the stator, enables rubber stress concentrations to be reduced. By reducing the rubber stress concentrations from rotor tilting, the ratio of stall stress to elongation at break is significantly improved.
As noted, this disclosure describes tapered power sections to remediate rotor tilt, preferably providing aggressive tapers near the bottom end of the PDM near the bit (although the scope of this disclosure is not limited in this regard). As highlighted in the “Background” section above, the prior art does not even acknowledge this problem, let alone try to solve it. Instead, the PCP prior art discloses gently tapered power sections to solve thermal expansion problems so as to distribute power more evenly across multiple PDM stages. Evans discloses use of tapered power sections to remediate a number of problems other than rotor tilt, including fluid leakage (and power loss) when the bottom of the PDM is bent while drilling a deviated well. In each case, the prior art seeks to deploy stators whose gentle tapers relieve thermal stress (or accommodate bending) while still maintaining rotor/stator contact (albeit a relaxed contact) by virtue of the gentle taper on the rotor. The tapered stator designs described in this disclosure go in the opposite direction. Aggressive tapers are provided, particularly near the outlet end, and are engineered to intentionally separate local rotor lobes from stator lobes and thereby reduce the potential for high friction contact and rubber damage due to rotor tilt. The rotor is thus stabilized. Local rubber stress concentrations are relieved. It is acknowledged that in some deployments with aggressive tapers, a drop in power may result by opening up progressing cavities to reduce frictional contact between rotor lobes and stator lobes. Experimental data has shown that such a drop in power does not occur in all deployments. When a drop in power does occur, however, such a drop is considered an acceptable trade-off in view of the corresponding beneficial results of: (1) stabilizing the rotor, (2) reducing local rubber stresses, and (3) maintaining torque.
The foregoing has rather broadly outlined some features and technical advantages of the disclosed PDM power section technology, in order that the following detailed description may be better understood. Additional features and advantages of the disclosed technology may be described. It should be appreciated by those skilled in the art that the conception and the specific embodiments disclosed may be readily utilized as a basis for modifying or designing other structures for carrying out the same inventive purposes of the disclosed technology, and that these equivalent constructions do not depart from the spirit and scope of the technology as described.
For a more complete understanding of embodiments described in detail below, and the advantages thereof, reference is now made to the following drawings, in which:
The following description of embodiments provides non-limiting representative examples using Figures, diagrams, graphs, plots, schematics, flow charts, etc. with part numbers and other notation to describe features and teachings of different aspects of the disclosed technology in more detail. The embodiments described should be recognized as capable of implementation separately, or in combination, with other embodiments from the description of the embodiments. A person of ordinary skill in the art reviewing the description of embodiments will be capable of learning and understanding the different described aspects of the technology. The description of embodiments should facilitate understanding of the technology to such an extent that other implementations and embodiments, although not specifically covered but within the understanding of a person of skill in the art having read the description of embodiments, would be understood to be consistent with an application of the disclosed technology.
Reference is now made to
Plot 130 on
Each of
Rotor 41, 51;
Stator 42, 52;
Nominal rotor centerline 43, 53;
Nominal rotor orbit of rotation 44, 54;
Nominal rotor eccentricity 45, 55; and
Plane of last fully-sealed stage 46, 56.
Referring first to
In contrast to stator 42 on
It will be understood that the various embodiments set forth in this disclosure are exemplary only, and do not limit the full scope of this disclosure. As noted above, this disclosure addresses the rotor tilt problem by providing a tapered stator that preferably includes an aggressive taper near the outlet end of the PDM. Contrary to some of the teachings of the prior art, this disclosure seeks to remediate rotor tilt generally with a tapered stator whose tapered geometry is selected to intentionally separate the rotor from the stator to relieve contact pressure (and associated friction and tear stress) between rotor and stator. This disclosure particularly seeks to intentionally taper the stator aggressively in a region near the outlet where the rotor tilt is particularly problematic. In some embodiments, the taper near the outlet provides a clearance fit rather than an interference fit with the rotor. In preferred embodiments, the clearance fit is much larger than seen or expected in the prior art.
It is acknowledged that this solution will likely sacrifice power output of the PDM by creating intentional leaks at the rotor/stator contact. However, the rotor remains stable in its rotation. Rubber stress concentrations are relieved. Power transfer and rotor stability is optimized in hard rubber stator embodiments, especially at high fluid pressure.
As noted, this disclosure describes tapers designed to offer clearance fits where rotor tilt is expected. In particular, this disclosure favors aggressive tapers with high clearance fits at the outlet end of the PDM where rotor tilt forces are also expected to be especially high. These designs are not suggested by the prior art. The prior art is primarily concerned with thermal expansion. The prior art discusses gentle tapers that will loosen interference fit but will nonetheless keep leakage to a minimum in order to maintain power. Some prior art references teach keeping rotor/stator contact with looser fits to accommodate thermal expansion. In direct contrast, this disclosure describes solutions for rotor tilt in which the stator is intentionally separated from contact with the rotor in order to controllably stabilize local fluid pressure and normalize rotor/stator contact pressure.
Preferred embodiments of tapered stators per this disclosure provide a 2-stage taper to remediate rotor tilt. The scope of this disclosure is not limited to 2-stage tapers, however.
The rotor is shown in a neutral position on
Tapers T1 and T2 on
In some embodiments, about 50% of the PDM's initial length from the inlet is untapered. The first taper stage of the 2-stage taper begins at about the halfway point of the PDM's length from the inlet towards the outlet. “About halfway” is selected in these embodiments because the maximum power output of a multistage power section can best be obtained by utilizing a single inference fit for at least 50% of the inlet side. A transition between the untapered portion and the first taper stage is desirable.
The first taper stage may transition into the second taper stage at a point anywhere up to about 90% of the PDM's length from inlet to outlet. The second (and more aggressive) taper stage preferably begins at a point along the PDM's length in a range from about 10% length to about 50% length from the outlet. A taper fit of about 102% to about 120% of paradigm design eccentricity is desirable at the outlet. Stated differently, and with reference to description of
Stator minor diameter+[about (0.05×eccentricity of design) to about (0.2×eccentricity of design)]
“Eccentricity of design” refers to the radius of the expected (design) orbital pathway of the center of the rotor absent any rotor tilt and in an untapered stator. The first and second tapers may be engineered back from such taper fit at the outlet. A transition between the first taper stage and the second taper stage is desirable.
In other embodiments, rotor tilt may be remediated according to this disclosure by a power section whose stator minor diameter at outlet is larger than the nominal inlet diameter and is tapered back to the nominal (inlet) minor diameter over a length spanning the outlet to about the midpoint of the power section. In some embodiments, the stator minor diameter at outlet may be larger than the nominal inlet diameter by at least about 5% of the eccentricity (0.5×stator lobe height). In some embodiments, the stator minor diameter at outlet is larger than the nominal inlet diameter and is tapered back to the nominal (inlet) minor diameter over a length spanning the outlet to about 25% of power section length back from outlet. In some embodiments, the stator minor diameter at outlet is larger than the nominal inlet diameter and is tapered back to the nominal (inlet) minor diameter over a length spanning the outlet to about 10% of power section length back from outlet. In some embodiments, the stator minor diameter at outlet is larger than the nominal inlet diameter and is tapered back to the nominal (inlet) with more than one taper where the most aggressive taper occurs in about the last 5% of PDM length measured from outlet, or alternatively in about the last 10% of PDM length measured from outlet, or alternatively in about the last 25% of PDM length measured from outlet, or alternatively in about the last 50% of PDM length measured from outlet.
In other embodiments, stator tapers may be further compensated for expected thermal expansion in a conventional cylindrical fit. In such embodiments, tapers may be first designed to remediate rotor tilt, and then adjusted further for expected thermal expansion by removing additional material from stator lobes. In some such embodiments, at least an additional 0.015 inches of stator lobe material may preferably be removed in popular sized PDMs.
A further exemplary embodiment of a 2-stage tapered stator within the scope of this disclosure may be derived with reference to
In some embodiments, the stator taper may be deployed based on an average of major and minor diameters. Conventional stator geometry and nomenclature acknowledges that a conventional stator has a length L between stator inlet and stator outlet, wherein Zn represents a stator position along L. The conventional stator further provides an internal surface with lobes formed in the internal surface, wherein the lobes define helical pathways in the stator internal surface. Zeniths of the lobes at stator position Zn define a stator internal minor diameter DMINn, and nadirs of the pathways at stator position Zn define a stator internal major diameter DMAJn, wherein (DMINn+DMAJn)/2 further defines a stator average diameter DAVEn at Zn. In embodiments deploying the taper based on an average of major and minor diameters, the taper may commence at stator position Z1 at about 0.67 L measured from the stator inlet, and the taper may end at stator position Z3 at 1.0 L measured from the stator inlet, in which DAVE3≥DAVE1+(0.03×(DMAJ1−DMIN1)/2). In other embodiments deploying the taper based on an average of major and minor diameters, the taper may provide a transition between stator position Z1 and stator position Z2, in which Z2 is at about 0.77 L as measured from the stator inlet, and in which DAVE2≥DAVE1+(0.015×(DMAJ1−DMIN1)/2)).
Preferred embodiments within the scope of this disclosure deploy the taper on the minor diameter of the stator. The minor diameter taper is contrary to the teachings of the prior art. The prior art is concerned with thermal expansion and/or bending in power sections, where a minor diameter taper would likely not be suitable to maintain a desired but relaxed rotor/stator contact.
Exemplary embodiments according to
Preferred—Exit diameter 83≥Minor diameter 82+about (0.05×eccentricity of design)
More preferred—Exit diameter 83≥Minor diameter 82+about (0.1×eccentricity of design)
Preferred for aggressive drilling—Exit diameter 83≥Minor diameter 82+about (0.15×eccentricity of design)
Preferred—First relief length 89≥about 0.1×Stator pitch length, but≤about 2.0×Stator pitch length
More preferred—First relief length 89≥about 0.2×Stator pitch length, but≤about 1.5×Stator pitch length
Most preferred—First relief length 89≥about 0.5×Stator pitch length, but≤about 1.0×Stator pitch length
The term “eccentricity of design” as used above refers to the radius of the expected (design) orbital pathway of the center of the rotor absent any rotor tilt and in an untapered stator.
Exemplary embodiments according to
Preferred—Exit diameter 92C≥Minor diameter 92A+about (0.05×eccentricity of design) AND Second diameter 92B≤Minor diameter 92A+about (0.025×eccentricity of design)
More preferred—Exit diameter 92C≥Minor diameter 92A+about (0.1×eccentricity of design) AND Second diameter 92B≤Minor diameter 92A+about (0.05×eccentricity of design)
Preferred—First relief length 99≥about 0.1×Stator pitch length, but≤about 2.0×Stator pitch length, AND Second relief length 98A≥about 1.0×First relief length 99, but≤about 2.0×First relief length 99
More preferred—First relief length 99≥about 0.2×Stator pitch length, but≤about 1.5×Stator pitch length, AND Second relief length 98A≥about 1.0×First relief length 99, but≤about 2.0×First relief length 99
Most preferred—First relief length 99≥about 0.5×Stator pitch length, but≤about 1.0×Stator pitch length, AND Second relief length 98A≥about 1.0×First relief length 99, but≤about 2.0× First relief length 99
As noted above, the term “eccentricity of design” as used above refers to the radius of the expected (design) orbital pathway of the center of the rotor absent any rotor tilt and in an untapered stator.
Rotor 61, 71;
Stator tube 62, 72;
Stator elastomer 63, 73; and
Nominal rotational orbit of rotor center 64, 74.
Referring first to
FIGURE SB illustrates power section 70 in a near stall condition. Arrow 75 denotes that the centripetal force urging rotor 71 outwards tends towards zero as a stall condition approaches. At this point, arrow 76 denotes that the forces from fluid pressure become most effective at or near stall conditions to lift rotor 71 off stator material 73 and to push rotor 71 off its nominal rotational orbit 74 and into opposing lobes in stator elastomer 73. Stress concentrations will result in the opposing stator lobes as a result of the rotor tilt. Note the opposing lobes are at a stator minor diameter. Arrow 77 denotes that tapering at the stator minor diameter would thus be beneficial to reduce stress concentrations in stator lobe due to the rotor tilt.
In summary, therefore,
Reducing stator lobe height via minor diameter tapering also addresses the potential for stator lobe tearing during stall (or near stall) events. It was noted above that in some embodiments, the required rubber elongation to survive a stalling event is at least approximately 35% to 50% strain. Thus, in order for the power section to obtain sufficient service life and reliability in the presence of rotor tilt, a stress relieving feature (taper) is needed near the exit of the power section to obtain a factor of safety that reduces the strain to a level less than about 35% during stall conditions. This may be obtained by reducing the lobe height of the stator elastomer via minor diameter tapering starting from the outlet and extending to about 10%-50% PDM length from the outlet.
In some embodiments, the minor diameter taper near the outlet may enlarge the stator diameter at the outlet by at least 10% greater than the eccentricity (½ lobe height) of the stator profile. Such embodiments will reduce rubber strain at or near the outlet, especially in cases of heavy rotor tilt.
Preferred embodiments may thus deploy the taper based on measurements of major diameter only, being indifferent to minor diameter (which may be constant). Referring back now to the conventional stator geometry and nomenclature set forth above, taper embodiments based on major diameter only may commence at stator position Z1 at about 0.67 L measured from the stator inlet and end at stator position Z3 at 1.0 L measured from the stator inlet, in which DMAJ3≥DMAJ1+(0.03×(DMAJ3−DMAJ1)/2). In other embodiments deploying the taper based on major diameter only, the taper may provide a transition between stator position Z1 and stator position Z2, in which Z2 is at about 0.77 L as measured from the stator inlet, and in which DMAJ2=DMAJ1+(0.015×(DMAJ2−DMAJ1)/2)).
In a similar manner, stator material with higher modulus such as hard rubber, plastic or metal can have a factor of safety calculated for the exit area of the power section where high rotor tilt is experienced. In the case of these high modulus materials, it is more appropriate to consider failure as the point where galling pressures are exceeded. For hard materials, galling and rapid material overheating/removal are the mechanisms for failure. In this case, an oversized stator minor diameter can be calculated based on a minor stator diameter modification that allows the rotor to bend and minimize stress concentrations a region spanning about 10%-50% PDM length from the outlet.
Note also that although preferred embodiments of the disclosed designs favor hard rubber throughout for power output, the scope of this disclosure is not limited in this regard.
In some embodiments of power sections including stators with tapers configured to remediate rotor tilt consistent with this disclosure, the tapered stator may include an elastomer liner having: (1) a 25% tensile modulus in a range between about 250 psi and about 1000 psi; (2) a 50% tensile modulus in a range between about 400 psi and about 1200 psi; and (3) a 100% tensile modulus in a range between about 500 psi and about 1600 psi. The scope of this disclosure is not limited in these elastomer liner modulus regards, however.
High modulus materials need not be limited to hard elastomers. Plastic, metal and hybrid stators are also within the scope of this disclosure. Aggressive tapers near the outlet of the PDM are also needed when using plastic or metal materials. In hybrid material arrangements, the highest modulus material of the stator profile is used at the exit end of the power section. Many of the high modulus materials have very low thermal expansions and so tapers addressing rotor tilt may not require further fit adjustment for thermal expansion.
When utilizing other high modulus material such as plastic or metal as the interface with a metal rotor, the galling pressure is a critical parameter that advantageously should not be exceeded. When driving the power section at high pressure or under stall conditions, a tapered exit contour is advantageous to relieve the interface pressure between the deflected rotor and minor diameter stator lobes.
In some embodiments of power sections including stators with tapers configured to remediate rotor tilt consistent with this disclosure, the power section preferably has a pressure drop capability represented by ΔP, wherein ΔP is preferably at least 180 psi/stage, and more preferably at least about 200 psi/stage. As used in this disclosure, pressure drop capability (ΔP) is a performance specification for the power section, and is functionally derived from a combination measurement of the stator lobe stiffness and the design rotor/stator fit (i.e. interference fit) for the power section. The stator lobe stiffness is functionally derived from a combination measurement of the stator elastomer's Modulus and the “reinforcement” behind the elastomer portion of the stator (e.g. the evenwall position or the overall rubber thickness to the outer tube). As used in this disclosure, pressure drop capability (ΔP) is defined as a fluid pressure drop per stage that will cause a 25% loss in rotor RPM at 1% squeeze. “Squeeze” is defined as the reduction in stator lobe height caused by the stator lobe interference fit with the rotor lobe under normal design conditions. AP capability also bears on the “power section rating”: Length of power section/stage length no. of stages; and power section rating=No. of stages×ΔP capability.
As further shown on
Raw rotor positional data from transducers 109, 110 at each of linear position transducer assemblies 107, 108 were converted to polar coordinates that provided eccentricity values at instantaneous points in time as each end of the rotor as it rotated within the stator. Data was recorded at a frequency of 2000 Hz in order to obtain rotor positional data with high granularity through a range of rotor operating speeds and other test parameters.
Two separate power sections A and B were tested separately to record rotor tilt. Power section A was a conventional power section, nominal 5″ diameter, with a 5/6 rotor/stator lobe configuration and 6.0 effective stages. Power section A further provided a stator whose elastomer was Abaco's HPW product, a hard rubber with fiber reinforcement, whose 25% tensile modulus may be in a range between about 250 psi and about 1000 psi. Power section B was identical to power section A, except that the bottom (downhole) end of the stator on power section B was adapted with a taper configured to remediate rotor tilt. The taper in power section B's stator was consistent with tapered stator embodiments described in this disclosure whose bottom-end tapers are specified herein for remediating rotor tilt.
Three test runs were performed on each of power section A and B, at 150, 250 and 350 gallons per minute drilling fluid flow rate. At each flow rate on each test run, the torque applied by the motor to the dynamometer was increased in incremental steps to create a range of differential pressures and pressure drops across the power section. The dynamometer monitored and recorded fluid pressure, flow rate, motor torque and motor speed continuously for all test runs. Rotor eccentricity was monitored and recorded continuously by linear position transducer assemblies 107, 108 for all test runs per description above with reference to
Lines 181, 182, 183 on plot 180 on
In contrast, the bottom orbital rotor path per dark-shaded solid lines 181 on plot 180 on
The same is true for top end eccentricity range 176 for power section B on
Different behavior is observed on
The data described and compared above with reference to
Tapered fit varies by length from outlet by a nonlinear function that starts with aggressive slope and then shallows. Nonlinear function may be selected from a geometric function (e.g. square function), a logarithmic function or a spline function
Tapered fit varies by length from outlet by a linear function or step function in multiple pieces.
Aggressive tapering near outlet combined with a shallow taper fit for thermal expansion fit only. Examples:
1. Inlet, 50% shallow taper, 25% straight (untapered), 25% aggressive taper, outlet.
2. Inlet, 75% shallow taper, 25% aggressive taper, outlet.
Note also manufacturing considerations—have to be able to remove and disassemble injection mold ends.
Although the inventive material in this disclosure has been described in detail along with some of its technical advantages, it will be understood that various changes, substitutions and alternations may be made to the detailed embodiments without departing from the broader spirit and scope of such inventive material.
This application claims the benefit of and priority to commonly-owned and commonly-invented U.S. Provisional Patent Application Ser. No. 63/004,263 filed Apr. 2, 2020. The entire disclosure of 63/004,263 is incorporated herein by reference as if fully set forth herein.
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63004263 | Apr 2020 | US |