The present application relates generally to hydraulic fracturing in oil and gas wells, and in particular to a hydraulic fracturing pump power end strengthened with torsion tubes.
It is difficult to economically produce hydrocarbons from low-permeability reservoir rocks. Oil and gas production rates are often boosted by hydraulic fracturing, a technique that increases rock permeability by opening channels through which hydrocarbons can flow to recovery wells. Hydraulic fracturing has been used for decades to stimulate production from conventional oil and gas wells. The practice consists of pumping fluid into a wellbore at high-pressure (sometimes as high as 50,000 PSI). Inside the wellbore, large quantities of proppants are carried in suspension by the fracture fluid into the fractures. When the fluid enters the formation, it fractures, or creates fissures, in the formation. Water, as well as other fluids, and some solid proppants, are then pumped into the fissures to stimulate the release of oil and gas from the formation. When the pressure is released, the fractures partially close on the proppants, leaving channels for oil and gas to flow.
Fracturing rock in a formation requires that the fracture fluid be pumped into the wellbore at very high-pressure. This pumping is typically performed by high-pressure, hydraulic fracturing pumps, with a diesel engine used to power operation of the pump to deliver fracture fluids at sufficiently high flow rates and pressures to complete a hydraulic fracturing procedure or “frac job.” These pumps are generally comprised of a power end and a fluid end. The fluid end of such a pump is utilized to pressurize a working fluid and may include a fluid suction manifold, a fluid discharge manifold, a fluid cylinder and a plunger. The power end of such a pump may include a crankcase in which a crankshaft is rotated in order to drive a plurality of piston arms. The piston arms in turn reciprocate crossheads. These crossheads are attached to the plunger(s) of the fluid end to drive the plunger(s) within the fluid cylinder. In some configurations, a power source, such as a diesel engine, is utilized to drive the crankshaft directly, while in other configurations, the power source may drive a pinion which in turn drives the crankshaft via a gearset. In any event, the hydraulic fracturing pumps are able to pump fracturing fluid into a wellbore at a high enough pressure to crack the formation. Typically, these hydraulic fracturing pumps operate for long periods of time and at high rates of speed to achieve the desired fluid pressure and formation fracturing. As a result, these pumps are subject to significant stresses. In particular, the power end of the hydraulic pumps experiences stress in the crankshaft housing in part from the many different moving pump components, such as the crankshaft, pinion, gearset and cross-heads, all of which may be operating along different axis of motion.
For a more complete understanding of the present disclosure and its features and advantages, reference is now made to the following description, taken in conjunction with the accompanying drawings, in which:
Generally, the power end of a hydraulic fracturing pump is provided. The power end includes a crankshaft housing through which a crankshaft extends along a crankshaft axis. Rotation of the crankshaft drives a plurality of piston arms which in turn cause reciprocation of a plurality of crossheads mounted in the crankshaft housing. Each crosshead has a crosshead axis along which the crosshead reciprocates. Each crosshead axis is generally perpendicular to the crankshaft axis. A plurality of spaced apart ribs are formed within the crankshaft housing and are also perpendicular to the crankshaft axis. At least one, and in some embodiments, a plurality of torsion tubes extend within the crankcase housing generally parallel with the crankcase axis so as to perpendicularly intersect the ribs. Each torsion tube is attached to at least two, and in some embodiments, a plurality of ribs. In some embodiments, the torsion tubes are welded to each rib the torsion tubes intersect. The power end may include a pinion shaft and gear extending through the crankcase housing so as to be generally parallel with the crankshaft axis. The pinion gear may be coupled the crankshaft through a gearset. In one or more embodiments, the plurality of torsion tubes are positioned within the crankcase housing so as to be angularly spaced apart from the pinion shaft about the crankshaft axis. The angular spacing may be at least 90 degrees. In one or more embodiments, at least one torsion tube is hollow, includes a plurality of apertures formed along the length of the torsion tube and is in fluid communication with an oil source so as to supply oil to interior of the crankcase housing.
In
In one or more embodiments, power end 10 may include a pinion gear assembly 30 having a pinion axis 32 and generally extending at least partially between the first side 20 and the second side 22 of crankcase housing 14. It will be appreciated that pinion gear assembly 30 may be coupled to a power source (not shown) to drive power end 10. In other embodiments, pinion gear assembly 30 may be eliminated and the power source (not shown) may be coupled directly to a crankshaft, such as the crankshaft described below. In these embodiments, it will be appreciated that one or both gearbox assemblies 24a, 24b may also be eliminated.
In one or more embodiments, crankcase 12 may include one or more eye flanges 34. In the illustrated embodiment, each first side 20 includes a forward eye flange 34a and a rear eye flange 34b, and second side 22 likewise includes a forward eye flange 34a and a rear eye flange 34b. Crankcase 12 may further include one or more access covers 36. An oil port 37 is shown formed within crankcase 12.
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Crankcase housing 14 has crankcase axis 15 extending therethrough. As shown, each crosshead extension rod 26 is generally formed along a crosshead axis 45 which is generally perpendicular to crankcase axis 15. In one or more embodiments, crosshead axis 45 intersects crankcase axis 15. As shown, pinion axis 32 is generally parallel with, but spaced apart from crankcase axis 15. Each crosshead extension rod 26 is shown having four stay rods 28 adjacent thereto. The pinion shaft 38 of pinion gear assembly 30 is shown extending only from first end 16 of crankcase housing 14, and in particular, extending through gearbox assembly 24a. The interior of crankcase housing 14 can be accessed through removable access covers 36. Section line A-A is shown passing through crankcase housing 14.
A rib 66 is shown as extending within crankcase housing 14 so as to be generally perpendicular to crankcase axis 15 and generally parallel with crosshead axis 45. As will be discussed below, in one or more embodiments, crankcase housing 14 may include a plurality of spaced apart ribs 66 within crankcase housing 14 between the first and second ends 16, 18 of crankcase housing 14. Shown formed within rib 66 is a crankshaft aperture 70 generally coaxial with crankcase axis 15 and a pinion aperture 72 generally coaxial with pinion axis 32. Together, the crankshaft apertures 70 of the plurality of spaced apart ribs form a crankshaft bore through which crankshaft 44 extends. Likewise, together, the pinion apertures 72 of spaced apart ribs form a pinion bore through which crankshaft 44 extends.
At least one torsion tube 76 is shown extending through crankcase housing 14 so as to be generally parallel with crankcase axis 15, and thus generally perpendicular to rib 66. Torsion tube 76 is affixed to rib 66 thereby providing support to rib 66. In one or more embodiments, torsion tube 76 is affixed to each rib 66 that torsion tube 76 intersects. In one or more embodiments, plurality of torsion tubes 76 may extend within crankcase housing 14. In the illustrated embodiment, at least 4 torsion tubes 76a, 76b, 76c and 76d are illustrated. Torsion tubes 76 may be hollow or solid in cross-section. Torsion tubes 76 may be positioned to extend through those portions of crankcase housing 14 which experiences the greatest degree of flexing during operation and/or movement. Thus, in some embodiments, the plurality of torsion tubes 76 may be positioned in crankcase housing 14 so as to be spaced away from pinion gear assembly 30 and crosshead assembly 54. In one or more embodiments, crankcase housing has a base 75 and an upper surface 77 where access ports 36 and/or eyes 34 are generally positioned adjacent the upper surface 77. One or more of the ribs 66 extend from adjacent the base 75 to adjacent the upper surface 77. The plurality of torsion tubes 76 may generally be positioned within crankcase housing 14 adjacent the upper surface 77 to minimize flexing of this portion of crankcase 12.
In one or more embodiments, an oil distribution tube 78 may also extend within crankcase housing 14 between the first and second ends 16, 18. Oil distribution tube 78 is in fluid communication with oil port 37 of
In one or more embodiments, a torsion tube such as 76e may include apertures 80 and thus may be utilized as an oil distribution tube. Any oil distribution tube as described herein is in fluid communication with an oil source (not shown), such as an oil pump or an oil reservoir as is well known in the industry.
Finally, it will be appreciated by persons of skill in the art that while crankshaft 44 is coaxial with crankcase axis 15, the individual crank pins (not shown) of the driveshaft to which piston rod 56 is attached in an orbit about crankcase axis 15 as shown in
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In any event, torsion tube 76b is illustrated as generally being positioned between crankcase axis 15 and upper surface 77 of crankcase housing 14. While other torsion tubes 76 may extend within crankcase housing 14 at any location, including adjacent base 75 of crankcase housing 14, in one or more embodiments, the plurality of torsion tubes 76 are positioned between crankcase axis 15 and upper surface 77. In this regard, torsion tubes 76 may be positioned adjacent upper surface 77. Although torsion tube 76b is illustrated as hollow, in other embodiments, torsion tube 76b may be solid. Moreover, while torsion tube(s) 76 are generally depicted as circular in cross-section, torsion tube(s) 76 may have any shape, including without limitation square or rectangular. Thus, in some embodiments, torsion tube 76 may be a solid rectangular bar. In any event, it will be understood that in such case, aperture 82 formed in rib 66 may be shaped to correspond with the shape of torsion tube 76 passing therethrough.
As described herein, power end 10 of a hydraulic fracturing pump may be coupled with any hydraulic fracturing pump wet end and will provide greater overall integrity to the hydraulic fracturing pump during operation.
Thus, a hydraulic fracturing pump has been described. The hydraulic fracturing pump may generally include a crankcase housing having a first side at a first end of the crankcase housing and a second side at a second end of the crankcase housing, an upper surface extending between the first and second sides and a base and, the crankcase housing formed along a crankcase axis extending between the two ends, the crankcase housing further having a plurality of crosshead apertures formed in the crankcase housing, each crosshead aperture formed about a crosshead axis that is generally perpendicular to the crankcase axis; a plurality of ribs within the crankcase housing between the two ends, each rib generally perpendicular to the crankcase axis and each rib having at least a first torsion tube aperture and a second torsion tube aperture formed therein and further having a crankshaft aperture formed therein, each crankshaft aperture generally coaxially with the crankcase axis; at least two torsion tubes positioned between the two ends of the crankcase housing and between the crankcase axis and the upper surface, each torsion tube intersecting a plurality of ribs, passing through a torsion tube aperture of each rib, wherein each torsion tube is rigidly affixed to each of the plurality of ribs. In other embodiments, the hydraulic fracturing pump may include a crankcase housing having a first side at a first end of the crankcase housing and a second side at a second end of the crankcase housing, an upper surface extending between the first and second sides and a base and, the crankcase housing formed along a crankcase axis extending between the two ends, the crankcase housing further having a plurality of crosshead apertures formed in the crankcase housing, each crosshead aperture formed about a crosshead axis that is generally perpendicular to the crankcase axis; a plurality of ribs within the crankcase housing between the two ends, each rib generally perpendicular to the crankcase axis and parallel with the crosshead axis, each rib having at least a first torsion tube aperture formed therein and each rib further having a crankshaft aperture formed therein, each crankshaft aperture generally coaxially with the crankcase axis; one or more torsion tubes positioned between the two ends of the crankcase housing and between the crankcase axis and the upper surface of the crankcase housing, each torsion tube intersecting a plurality of ribs, passing through a torsion tube aperture of each rib, wherein each torsion tube is affixed to each of the plurality of ribs. In yet other embodiments, the hydraulic fracturing pump may include a crankcase housing having a first side at a first end of the crankcase housing and a second side at a second end of the crankcase housing, an upper surface extending between the first and second sides and a base and, the crankcase housing formed along a crankcase axis extending between the two ends, the crankcase housing further having a plurality of crosshead apertures formed in the crankcase housing, each crosshead aperture formed about a crosshead axis that is generally perpendicular to the crankcase axis; a plurality of ribs within the crankcase housing between the two ends, each rib generally perpendicular to the crankcase axis and each rib having at least a first torsion tube aperture and a second torsion tube aperture formed therein and further having a crankshaft aperture formed therein, each crankshaft aperture generally coaxially with the crankcase axis; a crankshaft extending along the crankcase axis; a piston arm pivotally coupled to the crankshaft at a first end of piston arm, the piston arm pivotally coupled to a crosshead at a second end of the piston arm, the crosshead reciprocal along the crosshead axis; and at least two torsion tubes positioned between the two ends of the crankcase housing and between the crankcase axis and the upper surface, each torsion tube intersecting a plurality of ribs, passing through a torsion tube aperture of each rib, wherein each torsion tube is rigidly affixed to each of the plurality of ribs. Still yet other embodiments of a power end of a hydraulic fracturing pump may include a crankcase housing having a first side at a first end of the crankcase housing and a second side at a second end of the crankcase housing, an upper surface extending between the first and second sides and a base and, the crankcase housing formed along a crankcase axis extending between the two ends, the crankcase housing further having a plurality of crosshead apertures formed in the crankcase housing, each crosshead aperture formed about a crosshead axis that is generally perpendicular to the crankcase axis; a plurality of ribs within the crankcase housing between the two ends, each rib generally perpendicular to the crankcase axis and each rib having at least a first torsion tube aperture and a second torsion tube aperture formed therein and further having a crankshaft aperture formed therein, each crankshaft aperture generally coaxially with the crankcase axis, each rib having a pinion aperture formed therein about a pinion axis that is generally parallel with the crankshaft axis, a crankshaft extending along the crankcase axis; a piston arm pivotally coupled to the crankshaft at a first end of piston arm, the piston arm pivotally coupled to a crosshead at a second end of the piston arm, the crosshead reciprocal along the crosshead axis; a pinion assembly extending along the pinion axis, the pinion assembly having a pinion gear meshed with a gearset that engages the crankshaft; and at least two torsion tubes positioned between the two ends of the crankcase housing and between the crankcase axis and the upper surface, each torsion tube intersecting a plurality of ribs, passing through a torsion tube aperture of each rib, wherein each torsion tube is rigidly affixed to each of the plurality of ribs, wherein the pinion assembly is positioned below the crosshead axis and the at least two torsion tubes are positioned above the crosshead axis.
For any of the foregoing embodiments, the hydraulic fracturing pump may include any one of the following elements, alone or in combination with each other:
Although various embodiments have been shown and described, the disclosure is not limited to such embodiments and will be understood to include all modifications and variations as would be apparent to one skilled in the art. Therefore, it should be understood that the disclosure is not intended to be limited to the particular forms disclosed; rather, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the disclosure as defined by the appended claims.
The present application is a Continuation of U.S. patent application Ser. No. 16/680,305, filed Nov. 11, 2019, the disclosure of which is hereby incorporated by reference in its entirety.
Number | Name | Date | Kind |
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2237113 | Plumb | Apr 1941 | A |
9879659 | Kumar et al. | Jan 2018 | B2 |
10352321 | Byrne et al. | Jul 2019 | B2 |
20170370524 | Wagner | Dec 2017 | A1 |
Number | Date | Country | |
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20210239112 A1 | Aug 2021 | US |
Number | Date | Country | |
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Parent | 16680305 | Nov 2019 | US |
Child | 17236881 | US |