Embodiments disclosed herein relate generally to downhole motors used in drilling the bore of a subterranean well. More particularly, embodiments disclosed herein relate to improving motor efficiency using one or more devices to provide corrective forces to the rotor or to constrain the position of a rotor relative to a stator in a mud motor.
Downhole motor assemblies, such as mud motors, are used to supplement drilling operations by turning fluid power into mechanical torque and applying this torque to a drill bit. The drilling fluid or drilling mud is used to cool and lubricate the drill bit, carry away drilling debris, and provide a mud cake on the walls of the annulus to prevent the hole from sloughing in upon itself or from caving in all together.
One example of a drilling assembly using a mud motor is illustrated in
The downhole assembly has a longitudinal axis 35 that coincides with the longitudinal axis of motor 11. The lower end of rotor 21 will orbit eccentrically relative to axis 35, as indicated by the numeral 37. The amount of lateral deviation from the axis 35 may be on the order of about 3.1 mm to about 6.4 mm (about ⅛ to ¼ inch), for example. Rotor 21 is connected to a connector shaft 39 by a rotor coupling 41. Rotor coupling 41 forms a rigid connection which causes the upper end of connector shaft 39 to orbit in unison with the lower end of rotor 21. The lower end of connector shaft 39 connects to a drive shaft coupling 43, which is also a rigid coupling. Drive shaft coupling 43 rotates concentrically on the longitudinal axis 35. Connector shaft 39 will flex along its length because of the orbiting movement of its upper end. The drive shaft coupling 43 is then connected via a drive shaft 45, directly or indirectly, to the drill bit.
In operation, the motor assembly will be assembled and lowered into a well on a string of tubing. Once in place, drilling mud is supplied to motor 11, causing rotor 21 to rotate eccentrically. This causes connector shaft 39 to rotate, which in turn rotates drive shaft 45 and the drill bit (not shown). Motor 11 will discharge the fluid out the lower end and thence to the drill bit for cooling of the drill bit and removal of drill cuttings, where it flows to the surface.
Drilling motors or mud motors, such as illustrated in
In one aspect, embodiments disclosed herein relate to a mud motor assembly, comprising: a top sub comprising a shoulder having a first inner diameter proximate a distal end of the top sub; a power section comprising a progressive cavity motor comprising a stator and a rotor configured to rotate eccentrically when a drilling fluid is passed through the motor, the stator and rotor each having a proximal end and a distal end, wherein a proximal end of the power section is coupled to the distal end of the top sub; a rotor catch comprising a shaft having a proximal end and a distal end, and rotating eccentrically via transmission of the eccentric rotor motion; wherein the distal end of the shaft is coupled directly or indirectly to a proximal end of the rotor; wherein the shaft extends from the distal end of the rotor catch into the top sub a distance past the shoulder, wherein at least the portion of the shaft extending past the shoulder has an outer diameter less than the first inner diameter of the shoulder; wherein the proximal end of the shaft has an effective outer diameter greater than the first inner diameter and/or is coupled to a rotor catch assembly comprising one or more components having an effective outer diameter greater than the first inner diameter; at least one apparatus disposed intermediate the proximal and distal end of the rotor catch shaft, the at least one apparatus configured to constrain the radial and/or tangential movement of the rotor catch shaft and by transmission via the shaft to constrain the radial and/or tangential movement of the rotor.
In another aspect, embodiments disclosed herein relate to a drilling assembly, comprising: a mud motor assembly comprising a top sub and a power section; the top sub comprising a shoulder having a first inner diameter proximate a distal end of the top sub; the power section comprising a progressive cavity motor comprising a stator and a rotor configured to rotate eccentrically when a drilling fluid is passed through the motor, the stator and rotor each having a proximal end and a distal end, wherein the proximal end of the stator is coupled to the distal end of the top sub; a rotor catch comprising a shaft having a proximal end and a distal end, and rotating eccentrically via transmission of the eccentric rotor motion; wherein the distal end of the shaft is coupled directly or indirectly to a proximal end of the rotor; wherein the shaft extends from the distal end of the rotor catch into the top sub a distance past the shoulder, wherein at least the portion of the shaft extending past the shoulder has an outer diameter less than the first inner diameter of the shoulder; wherein the proximal end of the shaft has an effective outer diameter greater than the first inner diameter and/or is coupled to a rotor catch assembly comprising one or more components having an effective outer diameter greater than the first inner diameter; at least one apparatus disposed intermediate the proximal and distal end of the rotor catch shaft, the at least one apparatus configured to constrain the radial and/or tangential movement of the rotor catch shaft and by transmission via the shaft to constrain the radial and/or tangential movement of the rotor; a motor output shaft directly or indirectly coupled to the distal end of the rotor; and a drill bit directly or indirectly coupled to a distal end of the motor output shaft.
In another aspect, embodiments disclosed herein relate to a method of drilling a wellbore through a subterranean formation, the method comprising: passing a drilling fluid through a mud motor assembly or a drilling assembly according to embodiments disclosed herein, and drilling the formation using a drill bit directly or indirectly coupled to the rotor.
Other aspects and advantages will be apparent from the following description and the appended claims.
It has been found that the forces imposed on the rotor during operation may result in flow gaps (loss of differential pressure driving force) along the length of the motor. These flow gaps resulting from improper sealing of the stator/rotor pair may reduce the rotary speed and limit the developed torque.
Forces imposed on the rotor during operation include those due to the pressure differential across the motor from inlet end to outlet end. The pressure differential may result in a pitching moment. There is also a downward force exerted on the drill string, commonly referred to as “thrust” or “weight on bit,” where this force is necessarily transmitted through the rotor-drive shaft-drill bit couplings. The orbital-axial relationship of the drive shaft coupling may also result in angular and/or radial forces being applied to the rotor. Rotation of the rotor also results in tangential forces.
Each of these forces may have an impact on the manner in which the rotor interacts with the stator, such as the compressive forces generating seals along the edges of the resulting cavities, sliding, drag, or frictional forces between the rotor and the stator as the rotor rotates, etc. As a result, a flow gap may form along the length of the motor, reducing motor efficiency. Additionally, the impact of these forces may be different proximate inlet end and outlet end of the motor.
It has also been found that motor catch devices result in a significant amount of overhanging mass. This, in turn, may result in significant changes in the centrifugal forces at the top of the rotor as compared to design bases, further impacting the generation of flow gaps that reduce motor efficiency.
Embodiments disclosed herein relate to use of apparatus disposed on or operative with a rotor catch device for imparting corrective radial forces to the rotor. This radially inward force counteracts the centrifugal forces and hydraulic pressure loading on the rotor, constraining the movement of the rotor relative to the stator, thereby limiting, minimizing, or eliminating the formation of flow gaps along the length of the motor. Movement of a rotor relative to a stator is generally limited by the inherent resilience of the materials used to form the rotor and stator (e.g., deflection/compression of the rubber lining of the stator, etc.). As used herein, constraining the movement of the rotor relative to the stator refers to restricting or limiting the movement during use to a greater extent than would otherwise result or be permitted by the inherent resilience of the materials used to form the rotor and stator.
The improved sealing between the stator/rotor pair, resulting from the use of apparatus disposed on or operative with a rotor catch device for imparting corrective radial forces to the rotor, may thus result in an increase in one or more of rotary speed, developed torque, and pressure drop as compared to an unconstrained stator/rotor pair of similar size and configuration (i.e., lobe count, diameter, materials of construction, length, helix angle, etc.) For example, constraining the movement of the rotor relative to the stator according to some embodiments disclosed herein may result in the developed torque and/or rotary speed being increased by at least 5% over a motor of similar configuration without a constraining apparatus; developed torque and/or rotary speed may be increased by at least 10% in other embodiments; by at least 15% in other embodiments; by at least 20% in other embodiments; and by at least 25% in yet other embodiments. The resulting increase in torque and/or rotary speed may, for example, allow for a greater force to be applied to the drill bit or for the drill bit to be rotated at a greater rotary speed, both of which may individually or collectively result in improved drilling performance (less time to drill a given depth, etc.). Alternatively, the resulting increase in torque and/or rotary speed may allow for a reduction in the length of the motor (rotor/stator pair length) to achieve the same desired performance.
Referring now to
Power section 102 includes a progressive cavity motor 103 having a stator 106 and a rotor 108. Rotor 108 is configured to rotate eccentrically when a drilling fluid is passed through the progressive cavity motor 103 from inlet 110 to outlet 112. A surface of the rotor 108, the stator 106, or both, is made of a flexible material to permit a seal to form between the contacting surfaces of the rotor 108 and stator 106.
The distal end of rotor 108 may be coupled, directly or indirectly, to a transmission or drive shaft (not shown), which in turn may be coupled to bearings, a bearing mandrel, a bit box, and ultimately to a drill bit for drilling through a subterranean formation.
Input (proximal) end 114 of rotor 108 is coupled to a distal end 116 of a rotor catch device 118. Although illustrated as coupled directly, rotor 108 may alternatively be indirectly coupled to rotor catch device 118. Rotor catch device 118, via coupling with rotor 108, also rotates eccentrically (i.e., in operation, rotor 108 transmits the eccentric rotor motion to the rotor catch device 118), and thus has a centerline 132 offset from the centerline 134 of the motor.
Rotor catch device 118 may include, for example, an elongated shaft 120 of constant or varying outer diameter between distal end 116 and proximal end 122 of rotor catch device 118. Shaft 120 extends from distal end 116 of rotor catch device 118 into top sub 104 a distance past shoulder 105. Although shoulder 205 is shown as being integral to top sub 204, it is understood that it may alternatively be constructed from one or more separate components and attached to top sub 204 by various means, including but not limited to threading. The section of shaft 120 extending through shoulder 105 has an outer diameter D2 less than the inner diameter D1 of shoulder 105. Proximal end 122 includes a portion 124 that has an effective outer diameter D3 greater than the inner diameter D1 of shoulder 105. In this manner, if any part of the external body of the motor assembly 100 or the drill string breaks or fails below top sub 104, the enlarged portion 124 will not be able to pass shoulder 105, allowing for rotor 108 and the rest of the motor 100 to be pulled out of the wellbore. Enlarged portion 124 may be integral with shaft 120, or may include one or more components (a rotor catch assembly) coupled to proximal end 122 of shaft 120.
Referring now to
Due to coupling of the components, corrective forces imparted to rotor catch device 118 by constraining apparatus 130 may be transmitted via shaft 120 to rotor 108. In this manner, the forces constraining the radial and/or tangential movement of the rotor catch shaft may also constrain the radial and/or tangential movements of the rotor. As a result, the forces may counteract the centrifugal forces and hydraulic pressure loading on the rotor, limiting, minimizing, or eliminating the formation of flow gaps along the length of the rotor/stator pair.
Apparatus 130 may include a bearing assembly, a wheel assembly, a fixed insert, a rotatable insert, a precession device, or other means for controlling or limiting the movement of shaft 120 (and thereby controlling or limiting the movement of the rotor within the stator).
In some embodiments, the bearing wheel 226 may slide or roll in direct contact with the interior surface 224 of top sub 104 or power section 102. In other embodiments, the bearing wheel 226 may slide or roll in contact with a coating placed on the interior surface of the stator cylinder. During manufacture of some stators, the interior surface of a cylinder, such as a pipe or tube, is machined or coated, such as by pouring, spraying, or injecting a coating material onto the interior surface of the cylinder. However, due to the complexity of the stator manufacturing process, concentricity of the resulting stator with the stator cylinder itself cannot be guaranteed. Thus, during manufacture, the resulting stator liner or coating 90 may be offset from the centerline 92 of the stator cylinder 94, such as illustrated in
As noted above, the difference in the radius of the bearing wheel 226 and the inside surface 224 defines the maximum offset of the rotor axis from the stator axis. Additionally, for proper function, the bearing wheel 226 must maintain a sliding and/or rolling relationship with the inner surface of the stator so as to constrain the rotor through the entire rotation, i.e., maintaining contact over 360°. Due to the eccentric rotation of the rotor, the relative diameter of the bearing wheel 226 to that of the interior surface of 224 is an important variable, where an improper ratio may result in irregular contact of the bearing wheel with the inner surface 224, i.e., a non-rolling or non-sliding relationship.
In addition to diameter, the length of the bearing wheel 226 must also be sufficient to maintain the side loads imparted due to the wobble of the rotor and rotor catch shaft. Bearing wheel 226 should be of sufficient axial dimensions to address the structural considerations. The length of bearing wheel 226 may thus depend upon the number of lobes, motor/pump torque, and other variables readily recognizable to one skilled in the art, and may also be limited by the available space between the rotor and the drive shaft.
The bearing wheel 226, via transmission from the rotor catch shaft to the rotor, limits the extent of the wobble imparted by the eccentric motion of the rotor. This, in turn, may limit the formation of flow gaps along the length of the motor/pump by limiting the compression or deflection in the stator lining, such as a rubber or other elastic material. In some embodiments, the bearing wheel may limit the deflection of the stator lining by less than 0.64 mm (0.025 inches); by less than 0.5 mm (0.02 inches) in other embodiments; and by less than 0.38 mm (0.015 inches) in yet other embodiments.
Bearing wheel (26), as described above, radially constrains the position of the rotor, keeping the rotor in contact with the stator (i.e., providing an offset contact force without preventing the generation of torque). The resulting reduced normal force at the point of contact between the rotor and stator may reduce the drag forces, improving compression at the contact points, minimizing leakage paths. By limiting the formation of flow gaps (leakage paths) along the length of the rotor, pressure losses may be decreased, increasing the power output of the motor. Additionally, constraining the position of the rotor may reduce stator wear, especially proximate the top of the lobes, where tangential velocities are the highest.
Referring now to
Referring now to
Similar design considerations regarding concentricity of operative areas as discussed above with respect to
As described above, the embodiments illustrated in and described with respect to
In addition to the relatively circular means for constraining radial movement as illustrated in
Precession apparatus 70 controls the rotor catch shaft 74 and via transmission the rotor 74 such that rotor 74 will move on a prescribed path and with a prescribed rotation relative to stator 78. This type of restraint may effectively lock the rotation of the rotor to its orbit position. The lobed wheel 72 engages with lobed track 76 such that the relative profiles of the lobed wheel 72 and track 76 fix the path and rotation of the rotor 74 to prescribed values.
The lobed wheel 72 is connected to the rotor catch shaft 75 in a substantially fixed way. The ratio of the number of lobes on the wheel 72 to the number of lobes on the track 76 is limited to the same ratio as the number of lobes on the rotor 74 to the number of lobes on the stator 78. The profiles of the lobes on the wheel 72 and on the track 76 will determine the extent to which the rotor 74 can deform the sealing surface of the stator 78 and therefore limits the opening of gaps between them.
To allow some rotational compliance, the surface of the lobed wheel 72 or the track 76 may have a flexible layer added of, for example, rubber. The lobed wheel 72 and track 76 could have parallel sides or incorporate a helix angle to allow for some small axial movement and accommodate manufacturing tolerances.
The profile and composition (material of construction, compressibility, etc.) of lobed wheel 72 may be designed such that the deformation of the rubber in stator 78 is limited. In other embodiments, the profile and composition of lobed wheel 72 may be designed such that the deformation of the rubber in stator 78 is maintained to a fixed value. In this manner, the interaction between the rotor 74 and the rubber in stator 78 is used to maintain sealing, with the torque being generated largely on lobed wheel 72. This not only allows pressure loading up to the point where the seal would fail (a very high pressure) but it also ensures that the contact forces in the rubber can be kept substantially independent of pressure magnitude. This should reduce wear and fatigue failure in the rubber as well as improve motor/pump efficiency.
As described above, various apparatus may be used to constrain the motion of the rotor catch device, and via transmission via the rotor catch shaft may constrain the motion of the rotor relative to the stator. Constraining apparatus according to embodiments disclosed herein may thus constrain the orbital path of the rotor relative to the stator, fix the orbital path of the rotor relative to the stator, and/or limit the movement of a geometric centre of the rotor to a predetermined path.
As noted above, the forces imposed on the rotor may be different proximate the inlet end (proximal end) of the power section than those proximate the outlet end (distal end) of the power section, resulting in different radii of orbits for the rotor center at the inlet and outlet ends. The constraining apparatus disposed on or operative with the rotor catch as described above may thus, in some embodiments, be sufficient for imparting the desired corrective forces on the proximal end of the rotor, but insufficient for imparting the desired corrective forces on the distal end of the rotor. In such instances, it may be desirable for mud motor assemblies to include constraining apparatus disposed on or operative with the distal end of the rotor, such as illustrated in
The above described mud motor assemblies may be used in a drilling assembly for drilling a wellbore through a subterranean formation. The drilling assembly may include, for example, a mud motor assembly as described in any of the above embodiments, including among other components: a top sub, a power section including a progressive cavity motor having a stator and a rotor configured to rotate eccentrically when a drilling fluid is passed through the motor, a rotor catch device, and a device for constraining the motion of the rotor catch device. The drilling assembly may also include a motor output shaft configured to rotate concentrically, a first end of which is directly or indirectly coupled to a distal end of the rotor, and a second end of which is coupled, indirectly or directly, to a drill bit.
In operation, a drilling fluid is passed through the mud motor assembly, eccentrically rotating the rotor as the drilling fluid passes through the progressive cavity motor. The motor output shaft transmits the eccentric rotor motion (and torque) to the concentrically rotating drill bit to drill the formation. The device for constraining the motion of the rotor catch device imparts corrective forces to the rotor, constraining the movement of the rotor relative to the stator, improving the overall performance of the mud motor and the drilling assembly as a whole by counteracting the centrifugal forces and hydraulic pressure loading on the rotor, limiting, minimizing, or eliminating the formation of flow gaps along the length of the motor.
The improved sealing between the stator/rotor pair resulting from the use of constraining apparatus disclosed herein may thus result in an increase in one or more of rotary speed, developed torque, and pressure drop as compared to a stator/rotor pair of similar size and configuration (i.e., lobe count, diameter, materials of construction, length, helix angle, etc.) without such a constraining device The resulting increase in torque and/or rotary speed may, for example, allow for a greater force to be applied to the drill bit or for the drill bit to be rotated at a greater rotary speed, both of which may individually or collectively result in improved drilling performance (less time to drill a given depth, etc.). Alternatively, the resulting increase in torque and/or rotary speed may allow for a reduction in the length of the motor (rotor/stator pair length) to achieve the same desired performance.
Improvements in motor efficiency, such as sealing improvements and higher power output per length, as noted above, may be used, in some embodiments, to shorten the overall length of the motor while attaining a desired power output. A shortened power section may have numerous benefits and applications, as discussed below.
The limited overall axial length of the power section may allow for flow of solids, such a drilling mud including solid materials, through the motor without issue, even where both the rotor and stator have contact surfaces formed from rigid materials. The limited overall axial length may also provide flexibility in materials of construction that would otherwise be cost prohibitive.
In some embodiments, the rotor and/or the stator may be formed from a metal, composite, ceramic, PDC/diamond, hard plastic, or stiff rubber structural material. For example, both the rotor and stator may be formed from a metal, providing metal-to-metal contact along the length of the power section.
In other embodiments, the rotor and/or stator may be formed with a resilient layer (such as NBR rubber) and a hard layer, such as a hard rubber or plastic, ceramic, composite, or metal coating disposed as the contact surface on top of the resilient inner layer. For example, the rotor may be a metal, similar to currently produced rotors, and the stator may be a metal-coated rubber, where the metal layer is the layer contacting the rotor during operation of the motor. Similarly, a hard rubber or reinforced rubber layer may be provided as the innermost layer contacting the rotor. Typical “layered” stators disclosed in the prior art provide for a hard or reinforced inner elastomeric layer, opposite that of the present embodiments, to provide for the desired compression and sealing properties of the outer layer. However, due to the decreased axial length of the power sections, use of a rigid contact layer may be possible, improving wear properties of the motor (rotor, stator, or both) while providing the desired power output. While exemplified with a multi-layered stator, multi-layered rotors may also be used, such as a rotor having a metal core to provide torque capacity, an elastomeric material disposed on the core, and a metal shell. These embodiments are illustrated in
Where the corresponding contacting portions of the rotor and stator(s) are both rigid, such as a metal, hard plastic, composite, or ceramic, for example, it may be desirable to limit the friction, wear, and other undesirable interactions between the rotor and stator that may cause premature failure or seizure of the rotating component. The contact surfaces of the insert and/or the rotor may be coated or treated to reduce at least one of friction and wear. Treatments may include chroming, HVOF or HVAF coating, and diffusing during sintering, among others. Metal-to-metal (rigid-to-rigid) power sections may also provide sufficient clearance to be tolerant of debris, but tight enough to constrain the rotor motion close to ideal, achieving the above-noted benefits, without use of constraining devices.
Similarly, the relatively short contact length between the constraining devices and the rotor or stator may provide for flexibility in materials, and similar combinations of hard materials or hard-coated materials may be used for the constraining devices.
Alternatively, a resilient elastomer may be used as the contact surface on both the rotor and stator. The reduction in the otherwise high frictional loads attained by the constraining devices may provide for use of elastomeric stators and rotors in combination to attain a desired pump performance (power output, wear properties, etc.).
The benefits from use of constraining devices may also provide for alternative stator designs. For example, as illustrated in
One potential benefit of a constrained motor may be a reduction in vibrations associated with the mud motor. Constrained lateral forces may result in less wobble or a narrower orbital path as compared to an un-constrained motor. As a result of reduced vibrations, drilling may be improved, such as by resulting in one or more of a better hole quality, an even-gage hole, and improved steering.
A reduction in the axial length of the motor may also provide the ability to modify the drill string components to incorporate a motor. For example, an adjustable bend housing typically includes a transmission shaft to transmit torque generated from the power section of the drilling motor to a bearing section of the drilling motor. Due to the potential reduction in size of the motor due to the constraining devices disclosed herein, it may be possible to incorporate a motor into the bent housing along with the transmission shaft. Similarly, motors according to embodiments herein may advantageously be incorporated into a stabilizer, a steering head, or other various portions of the bottom hole assembly (BHA).
The decreased axial length may also facilitate disposal of wire through the motor and provide space for additional downhole instrumentation, such as instrumentation to monitor the motor and/or components below the motor. Instrumentation may beneficially monitor motor RPM, pressure drop, and other factors, possibly avoiding stalls and allowing operation of the motor at high efficiency or peak efficiency, each of which may result in improved drilling performance (increased rate of penetration, less downtime due to stalled motors, etc.).
While the disclosure includes a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that other embodiments may be devised which do not depart from the scope of the present disclosure. Accordingly, the scope should be limited only by the attached claims.
This application is a continuation of U.S. patent application Ser. No. 14/358,944, filed May 16, 2014, which is the National Stage Entry of PCT/US2012/065416, filed Nov. 16, 2012, which claims priority to provisional application 61/651,313 filed on May 24, 2012 and provisional application 61/561,704 filed on Nov. 18, 2011, which are herein incorporated by reference in their entirety
Number | Date | Country | |
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61561704 | Nov 2011 | US | |
61651313 | May 2012 | US |
Number | Date | Country | |
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Parent | 14358944 | May 2014 | US |
Child | 15342924 | US |