US20260126034A1
Retaining Kit for Securing a Port Nut
Publication
Application
Classifications
IPC Classifications
CPC Classifications
Applicants
SPM Oil & Gas Inc.
Inventors
Jeffrey R Haiderer, Jeongpill Ki, Chandu Kumar, Albert Rubalcava
Abstract
A bedrock fracturing unit for pressurizing fluid within a bedrock formation is disclosed and includes a hydraulic pump. The hydraulic pump includes a pump block with a port therein, a plug which seats within a shoulder of the port, and a port nut which threads into a threaded surface of the port such that it presses against the plug. Further, the pump includes a flange which mounts to an outer surface of the pump block and a flange nut which threads into the flange such that it engages the port nut. The port nut and the flange nut have different thread pitches such that rotation of the port nut does not dislodge the flange nut.
Figures
Description
TECHNICAL FIELD
[0001]The present disclosure relates generally to a retaining kit for securing a port nut, and more particularly to a retaining kit for securing a hydraulic pump port nut within a pump block.
BACKGROUND
[0002]Bedrock fracturing units commonly include hydraulic pumps which pump liquids or slurries during a hydraulic fracturing process. The hydraulic pumps generally first pump the liquid or slurry into the bedrock formation until it is full, and then pressurize the liquids or slurries to pressures high enough to fracture the bedrock formation. Due to the high pressures generated by the hydraulic pumps, which may be in excess of 20,000 PSI, they are regularly opened, inspected, and serviced. Accordingly, the hydraulic pumps generally include servicing ports which provide access to the various internal components.
[0003]After servicing a hydraulic pump, the servicing ports are generally sealed off by placing a plug within each servicing port and then threading a port nut into each servicing port, the port nuts holding the plugs in position. While in use, the hydraulic pump may experience high pressures as well as vibration, either of which may loosen the port nuts within the servicing ports, and this may cause the plugs to shift and the hydraulic pump to leak. In some situations, the port nut may be loosened in a manner that can structurally impact or damage the servicing port, such as flattening the threads that hold the port nut in place. Depending on the extent of damage to the servicing port, the entire hydraulic pump may need to be removed from service.
[0004]U.S. Pat. No. 8,402,880B2 describes a locking assembly for a servicing port. The assembly of the '880 patent includes a plug and a port nut which are positioned within a threaded servicing port. The port nut has external threads which engage the threads of the bore, and further includes a central opening. A locking member is inserted into the central opening and a fastener secures the locking member to the plug, preventing rotation of the port nut relative to the plug.
[0005]The locking assembly in the '880 patent represents one possible approach, but additional future designs might present other choices for securing a port nut within a pump block.
SUMMARY
[0006]In an aspect of the present disclosure, there is a bedrock fracturing unit, including a pump block, a plug, a port nut, a flange, and a flange nut. The pump block includes an exterior surface with a port therethrough, the port including an internal shoulder and a threaded internal surface. The plug is configured to seat against the internal shoulder. The port nut includes a first threaded radial surface configured to engage the threaded internal surface, a top surface, and a bottom surface opposite the top surface, the bottom surface configured to compress the plug against the internal shoulder when the port nut is engaged with the threaded internal surface. The flange includes an outer surface, a central aperture defining a threaded inner surface, the inner surface opposite the outer surface, and a plurality of mounting holes configured to mount the flange to the exterior surface of the pump block such that the port nut is accessible through the central aperture. The flange nut includes a top side, a bottom side opposite the top side, the bottom side configured to engage the top surface, and a second threaded radial surface configured to engage the threaded inner surface.
[0007]In another aspect of the present disclosure, there is a kit for securing a port nut in a pump block of a bedrock fracturing unit, the pump block having an external surface and a threaded cavity opening to the external surface, the port nut having a first threaded outer surface configured to mate with the threaded cavity. The kit includes a flange configured to be mounted to the external surface of the pump block and having a threaded opening and a flange nut having a second threaded outer surface configured to mate with the threaded opening of the flange. The first threaded outer surface has a first thread pitch, and the second threaded outer surface has a second thread pitch, the first thread pitch being different from the second thread pitch. After the port nut is secured within the threaded cavity and the flange is connected to the pump block, the flange nut is threaded into the flange until it engages the port nut.
[0008]In yet another aspect of the present disclosure, a method is provided for securing a port nut within a pump block of a bedrock fracturing unit. The method includes threading the port nut into a threaded cavity of the pump block, the port nut having a first thread pitch. The method further includes securing a flange to an external surface of the pump block, the flange having a threaded opening, the threaded opening generally surrounding the threaded cavity of the pump block. The method finally includes threading a flange nut into the threaded opening of the flange and into contacting relationship with the port nut, the flange nut having a second thread pitch different from the first thread pitch of the port nut.
[0009]Other features and aspects of this disclosure will be apparent from the following description and the accompanying drawings.
BRIEF DESCRIPTION OF DRAWINGS
[0010]
[0011]
[0012]
[0013]
[0014]
[0015]
[0016]
DETAILED DESCRIPTION
[0017]
[0018]Although the engine 108 is illustrated as an internal combustion engine, the engine 108 may be a dual fuel or turbine engine, electric motor, and/or other engine or device designed to drive the pump 106. Further, the cooling system 110 may be different and/or removed from the bedrock fracturing unit 100 depending on the engine 108.
[0019]
[0020]The pump block 200 is a steel casing which houses many of the components of the hydraulic pump 106. The pump block 200 includes an external surface 208, a plurality of ports 210, and a plurality of pumping chambers 212. The external surface 208 is shown as the surface the ports 210 extend through, however the external surface 208 may be any surface which defines at least a portion of the outside of the pump block 200.
[0021]The ports 210 are each a passageway that extends outward from one of the pumping chambers 212 and through the external surface 208. The ports 210 provide access to the pumping chambers 212 from the outside of the pump block 200. The ports 210 are sized such that the components within the pumping chambers 212 may be inspected and/or serviced through the ports 210.
[0022]The pumping chambers 212 are each separate cavities within the pump block 200 and are each fluidly connected to one of the ports 210. The pumping chambers 212 are where the fluid is pressurized within the pump block 200 and include various pumping components and passageways.
[0023]The port nuts 202 are threaded nuts which connect to the ports 210 and may be used to close or restrict access to the pumping chambers 212. The pump block 200 is shown with five ports 210, with the leftmost port 210 uncovered and the other four ports 210 each covered by a port nut 202.
[0024]The inlet pipe 204 is a pipe connected to the pump block 200 and the fluid tank 102. The inlet pipe 204 carries fluid to the pump block 200 to be pressurized. The inlet pipe 204 is fluidly connected to each of the pumping chambers 212, such that the fluid may be dispersed to each.
[0025]The outlet pipe 206 is another pipe and is connected to the pump block 200 and the valve 104. The outlet pipe 206 is fluidly connected to each of the pumping chambers 212, and carries the pressurized fluid exiting each pumping chamber 212 to the valve 104.
[0026]
[0027]The port 210 includes a first segment 300, a shoulder 302, and a second segment 304. The first segment 300 extends to the external surface 208, includes a threaded section 306, and is larger in diameter than the second segment 304. The shoulder 302 connects the first segment 300 to the second segment 304 and is where the diameter of the port 210 is decreased from the diameter of the first segment 300 to the diameter of the second segment 304. The second segment 304 is smooth and is open to the pumping chamber 212.
[0028]The port 210 is closed by a plug 308 and a port nut 202. The plug 308 includes a main body 310, a seal 312, and a brim 314. The main body 310 fits within second segment 304 of the port 210 and includes a slot 311, extending around the outside thereof. The seal 312 is compressible and fits within the slot 311. The seal 312 shown is compressed such that it is pressed between the surface of the second segment 304 and the slot 311, creating a seal between the second segment 304 and the plug 308. The brim 314 is located at an end of the plug 308 and has a larger diameter than the second segment 304 such it contacts the shoulder 302 of the port 210 and prevents the plug 308 from moving inwardly through the second segment 304 toward the pumping chamber 212.
[0029]The port nut 202 includes a threaded radial surface 316, a bottom surface 318, a top surface 320, a ledge 322, a land 324, and a tool aperture 326. The threaded radial surface 316 engages the threaded section 306 of the port 210 to connect the port nut 202 to the port 210. The bottom surface 318 is shown contacting the brim 314. The top surface 320 is opposite from and is the surface furthest from the bottom surface 318. The ledge 322 is between the top surface 320 and the land 324. The land 324 is between the ledge 322 and the threaded radial surface 316 and extends circumferentially around the top surface 320. The tool aperture 326 is a hole which extends from the top surface 320 to the bottom surface 318 and is configured to accept a tool used to thread the port nut 202 with respect to the port 210. For example, the tool aperture may have six sides and be configured to receive an allen-type wrench or hex-bit socket for turning the port nut 202.
[0030]
[0031]The flange 402 includes a mounting face 406, a back face 408, a central aperture 410, a threaded inner surface 412, an outer surface 414, and a plurality of mounting holes 416. The mounting face 406 is opposite the back face 408 and is configured to mate with the external surface 208 of the pump block 200. The central aperture 410 extends through the back face 408 and the mounting face 406 and defines the threaded inner surface 412. The outer surface 414 is radially outside of the threaded inner surface 412. The plurality of mounting holes 416 each extend through the mounting face 406 and the back face 408 and are configured to accept fasteners 502 (as described below with respect to
[0032]The flange nut 404 includes a circumferential surface 418, a bottom face 420, a top face 422, and a tool hole 424. The circumferential surface 418 includes a threaded segment 426 and a plurality of tool bores 428. The threaded segment 426 extends from the bottom face 420 towards the top face 422 and engages the threaded inner surface 412 of the flange 402 to connect the flange nut 404 to the flange 402. The tool bores 428 extend radially inwards from the circumferential surface 418 and are configured to accept a tool used to rotate the flange nut 404 with respect to the flange 402. The tool bores 428 are shown located between the threaded segment 426 and the top face 422 and are spaced from one another around the circumferential surface 418.
[0033]The bottom face 420 is opposite the top face 422 and includes a ring 432 which defines a cavity 430. The cavity 430 extends axially inwards from the bottom face 420 and is sized such that a portion of the port nut 202, including its top surface 320, may fit within the cavity 430. The ring 432 protrudes axially outwards from the bottom face 420 and extends circumferentially around the cavity 430. The ring 432 is configured to engage the land 324 of the port nut 202. The tool hole 424 extends through the top face 422 and bottom face 420, the tool hole 424 configured to accept a tool used to rotate the flange nut 404 with respect to the flange 402.
[0034]Although shown having a circular outer surface 414, the outer surface 414 of the flange 402 may be any number of shapes. Further, although the ring 432 is shown as a single piece, the ring 432 may be a series of protrusions spaced circularly around the bottom face 420. In some cases, the bottom face 420 may not include the ring 432 and/or the cavity 430. Additionally, there may be any number of fasteners 502, the fasteners 502 having any number of various shapes and/or sizes.
[0035]
[0036]Turning to
[0037]As for the installation order of the components, the components are laid out left-to-right in order of installation in
[0038]The plug 308 is shown as the first component to be installed, with the plug 308 inserted into the port 210 past the external surface 208 and first segment 300, and generally into the second segment 304. The port nut 202 is shown as the second component to be installed, with the port nut 202 threaded into the threaded section 306 of the port 210 until it contacts the plug 308. The flange 402 is shown as the third component to be installed, with a portion of the fasteners 502 passing through the mounting holes 416 and threading into the mounting bores 500 until the flange 402 is pressed against the external surface 208. The flange nut 404 is shown as the fourth component to be installed, the flange nut 404 threaded into the threaded inner surface 412 of the flange 402 until it contacts the port nut 202.
[0039]To assist with restricting the rotation of the port nut 202 when the flange nut 404 is installed, the port nut 202 and flange nut 404 have differing thread pitches. As shown, the threaded radial surface 316 of the port nut 202 (and corresponding threaded section 306 of the port 210) has a coarser thread than the threaded segment 426 of the flange nut 404 (and corresponding threaded inner surface 412 of the flange 402). Threading may be fine or coarse, with a coarse thread having a pitch which is larger than a fine thread, leading to less threads per inch. With a different thread pitch, rotation of the port nut 202 out of the port 210 does not rotate the flange nut 404 at the same rate, creating resistance.
[0040]For example, the threaded radial surface 316 may be three threads per inch, and the threaded segment 426 may be eight threads per inch, with each having the same-hand threading. In order to rotate out an inch, the threaded radial surface 316 needs to rotate three times while rotating the threaded segment 426 eight times. As such, the threaded radial surface 316 backs out further than the threaded segment 426 per rotation. However, since the port nut 202 and flange nut 404 are pressed together when installed, they both initially try to rotate at the same time. Since the threaded radial surface 316 attempts to move further than the threaded segment 426, such an attempt at rotation would further press them together and create additional resistance to rotation.
[0041]However, there may be many variations of the threading on one or more of the components. For example, the port nut 202 or flange nut 404 may have right-hand threading, while the other has left-hand threading. Accordingly, attempted loosening of the port nut 202 may instead tighten the flange nut 404. Further, depending on particular use, different thread pitches or pitch differences may be desired. For example, some uses may desire at least a two-thread-per-inch pitch difference between the port nut 202 and flange nut 404. In other uses, the pitch of the port nut 202 may be between one and four threads per inch, while the pitch of the flange nut 404 may be between five and ten threads per inch.
[0042]
[0043]Turning to
[0044]
[0045]
[0046]
[0047]
[0048]
[0049]Although described above as installed in a specific manner, the components may generally be installed in many different orders. For example, the flange 402 may be installed at any stage as it does not interfere with the installation of the plug 308 or port nut 202, and the flange nut 404 may be preinstalled within the flange 402. Further, the retaining kit 400 may be installed on a pump block 200 without removing the port nut 202 and/or plug 308, such that it may simply be added to the existing setup.
[0050]Further, although the various components above are described as located in specific positions while installed, there may be a variety of acceptable installation positions for the components. In one example, the mounting face 406 of the flange 402 may be partially engaged with the external face 208 when installed on the pump block 200. In another example, the land 324 of the port nut 202 may be outside of or within the port 210 when the port nut 202 is threaded into the port 210. In a third example, the flange 402 may engage the port nut 202 when in the installed position. Additionally, the port nut 202 and/or flange nut 404 may have differently shaped and/or sized tool apertures 326, tool holes 424, and/or tool bores 428, or may lack them entirely.
[0051]
INDUSTRIAL APPLICABILITY
[0052]The retaining kit 400 may be used for securing a port nut 202 within a pump block 200. The retaining kit 400 includes a flange 402 and a flange nut 404. The flange 402 mates with the external surface 208 of the pump block 200. The flange nut 404 mates with the flange 402 and engages the port nut 202 when the port nut 202 is installed within the port 210 of the pump block 200. The differing pitches of the threaded radial surface 316 and threaded segment 426 effectively lock the port nut 202 to the flange nut 404 without the use of fasteners, such that rotation of the port nut 202 does not also rotate the flange nut 404.
[0053]Accordingly, the pump block 200 using the retaining kit 400 may have port nuts 202 that better resist the disruptive forces of high pressures and vibrations of the pump block 200. As such, the port nuts 202 may experience less loosening within the ports 210. Thereby, the ports 210 may be less susceptible to fluid leakage and damage, and therefore may require less monitoring, maintenance, and repair.
[0054]While aspects of the present disclosure have been particularly shown and described with reference to the embodiments above, it will be understood by those skilled in the art that various additional embodiments may be contemplated by the modification of the disclosed machines, systems, and methods without departing from the spirit and scope of the disclosure. Such embodiments should be understood to fall within the scope of the present disclosure as determined based upon the claims and any equivalents thereof.
Claims
1. A pump, comprising:
a pump block, including:
an exterior surface;
a port through the exterior surface, including:
an internal shoulder; and
a threaded internal surface;
a plug configured to seat against the internal shoulder;
a port nut, including:
a first threaded radial surface configured to engage the threaded internal surface;
a top surface; and
a bottom surface opposite the top surface, the bottom surface configured to compress the plug against the internal shoulder when the port nut is engaged with the threaded internal surface;
a flange, including:
an outer surface;
a central aperture defining a threaded inner surface, the inner surface opposite the outer surface; and
a plurality of mounting holes configured to mount the flange to the exterior surface of the pump block such that the port nut is accessible through the central aperture; and
a flange nut, including:
a top side;
a bottom side opposite the top side, the bottom side configured to engage the top surface; and
a second threaded radial surface configured to engage the threaded inner surface.
2. The pump of
3. The pump of
4. The pump of
5. The pump of
6. The pump of
7. The pump of
8. A kit for securing a port nut in a pump block of a bedrock fracturing unit, the pump block having an external surface and a threaded cavity opening to the external surface, the port nut having a first threaded outer surface configured to mate with the threaded cavity, the kit comprising:
a flange configured to be mounted to the external surface of the pump block and having a threaded opening; and
a flange nut having a second threaded outer surface configured to mate with the threaded opening of the flange;
wherein the first threaded outer surface has a first thread pitch and the second threaded outer surface has a second thread pitch, the first thread pitch being different from the second thread pitch, and
wherein after the port nut is secured within the threaded cavity and the flange is connected to the pump block, the flange nut is threaded into the flange until it engages the port nut.
9. The kit of
10. The kit of
11. The kit of
12. The kit of
13. The kit of
14. The kit of
15. The kit of
16. A method of securing a port nut within a pump block of a bedrock fracturing unit, comprising:
threading the port nut into a threaded cavity of the pump block, the port nut having a first thread pitch;
securing a flange to an external surface of the pump block, the flange having a threaded opening, the threaded opening generally surrounding the threaded cavity of the pump block; and
threading a flange nut into the threaded opening of the flange and into contacting relationship with the port nut, the flange nut having a second thread pitch different from the first thread pitch of the port nut, and wherein the contacting relationship between the flange nut and the port nut is an outer ledge of the flange nut engaging an outer shoulder of the port nut.
17. The method of
18. The method of
19. (canceled)
20. The method of