This disclosure is directed generally to efficient solids control in subterranean drilling applications (for example), and more particularly to an in-line mud screen manifold that in such drilling applications, simplifies the handling and replacement of conventional drop-down drilling mud screens.
Mud screen filters are used generally to filter drilling fluid before it flows down the inside of a drill string. The purpose is to prevent trash, debris or excessive solids or drill bit cuttings from entering or re-entering the drill string, so as to reduce the chance of plugging or clogging downhole tools to a point where they will not operate properly. The two most common conventional locations for placement of a mud screen are: (1) inside of the box end connection of the top joint of pipe as drilling occurs; and (2) further down the drill-string as an in-line mud screen.
Mud screens are conventionally “dropped into” the drill string at a joint of drill pipe as a new length of pipe is added to the string on the rig floor. See
FIG. 1E in U.S. Provisional Application Ser. No. 62/560,652, incorporated herein by reference, depicts various types and styles of conventional drop-in mud screens that might be used in the prior art methods described with reference to
There are at least three disadvantages of conventional drop-in mud screens as used in the prior art as described above. First, the mud screens can cause significant damage to the drill pipe connections, requiring cost and time to repair. As shown on
Second, if a well control situation occurs, the presence of a drop-in mud screen in the drill string may (for example) restrict mud flow, and thus may become a serious impediment to regaining control of the well.
Third, as depicted in the prior art video cited above, removal and re-insertion of a drop-in mud screen adds additional steps, and therefore time, to the process of inserting additional pipe joints in a drill string. Time is always of the essence in drilling operations. Also, additional steps may bring additional personnel safety concerns. Further, operators may forget to remove or re-insert drop-in mud screens during an extended drilling operation. In such cases, redundant additional drop-in screens may be left in the drill string, or drill strings may operate for periods with no screen in place. Either situation is not optimal for efficient solids control.
These and other drawbacks in the prior art are addressed by an in-line mud screen manifold (“MSM”) as described in this disclosure. The disclosed MSM completely eliminates the need for drop-in mud screens placed inside the drill string. Preferably, with reference to
In order to facilitate conventional pumping hardware connections, MSM 300 advantageously provides API hammer unions that match conventional mud flow piping. MSM 300 is further designed and built with the API unions facing the correct flow direction.
Embodiments of the disclosed MSM are engineered to reduce turbulence in fluid flow through the MSM, thereby promoting laminar flow. Laminar flow optimizes fluid flow velocity and volume through the MSM, and reduces wear on internal parts. Laminar flow further tends to encourage solids in the fluid to flow into the screen provided in the MSM rather than allowing solids to build up in and around other internal MSM components.
Embodiments of the disclosed MSM are further engineered to provide effective contact seals on internal parts in order to minimize, if not eliminate, leakage of unscreened fluid around the screen provided in the MSM. The MSM of this disclosure is therefore highly efficient at solids removal. At the same time, the internal seals are provided with quick and easy maintenance of the MSM in mind. Once taken out of service, design features of the MSM internals allow the MSM screen to be removed and cleaned or replaced quickly and efficiently.
The disclosed MSM embodiments provide at least the following additional technical advantages:
The location of the disclosed MSM enables the MSM to filter out trash, debris and other undesirable solids from the mud flow before the mud ever reaches the rig floor at the standpipe.
The disclosed MSM reduces scope for human error as compared to conventional drop-in mud screens as described above with reference to
The disclosed MSM improves control of the well. Advantageously, the design will maximize the mud flow rate capacities of the drill mud pumps, and allow the continuous drilling for longer intervals without having to cease operations to clean out the MSM.
Conventional drop-in mud screens have also been known to break apart during operation. The pieces from the broken screen will then flow down with the mud to the bottom hole assembly. The broken pieces will likely damage MWD or LWD instruments, drill bit hardware and other expensive items. In severe cases, the presence of broken mud screen pieces in the bottom hole assembly may cause shut down of drilling operations, or even well control issues. The disclosed MSM eliminates the drop-in mud screen and thus reduces the chance of any of the foregoing adverse events occurring.
In a first aspect, embodiments of an MSM according to this disclosure comprise: a body, the body having mud flow inlet, a mud flow outlet and a screen insertion port; the body further having a saver sub chamber, a seal chamber, a screen chamber and a mud inlet chamber all formed therein, the seal chamber further providing a seal chamber interior surface formed thereon; wherein the screen insertion port is in fluid flow communication with the saver sub chamber, the mud flow outlet is in fluid flow communication with the screen chamber, and the seal chamber is in fluid flow communication with the saver sub chamber and the screen chamber; a hollow saver sub, the saver sub further having first and second saver sub ends, the saver sub having a cutout therein between the first and second saver sub ends; a shaped flange provided on the first saver sub end, the shaped flange disposed to be received into a correspondingly shaped recess formed in the saver sub chamber; an exterior of the second saver sub end having a first seal portion formed therein; wherein, when an elongate screen cage is rigidly connected to the second saver sub end, and when the saver sub and the screen cage are inserted through the screen insertion port and into the saver sub chamber such that the shaped flange is received into the shaped recess: (1) the mud flow inlet is in fluid flow communication with the saver sub cutout via the mud inlet chamber; (2) the saver sub is in fluid flow communication with the screen chamber via fluid flow through the screen cage; and (3) the saver sub first seal portion forms a first contact seal with the seal chamber interior surface.
In other embodiments according to the first aspect, the exterior of the second saver sub end has first and second seal portions formed therein with the first seal portion nearer the first saver sub end than the second seal portion; the exterior of the second saver sub end further provides an exterior threaded portion between the first and second seal portions; and the screen cage has an interior cage surface such that the interior cage surface forms a second contact seal with the saver sub second seal portion when the screen cage is rigidly connected to the second saver sub end via threaded engagement with the exterior threaded portion.
In other embodiments according to the first aspect, selected ones of the first and second contact seals are assisted by at least one o-ring.
In other embodiments according to the first aspect, the MSM further comprises a magnetic rod, the magnetic rod disposed to be rigidly connected to the saver sub while positioned within the saver sub. In some such embodiments, the first saver sub end provides saver sub interior threads; and the magnetic rod is disposed to be rigidly connected to the saver sub via threaded engagement with the saver sub interior threads.
In other embodiments according to the first aspect, the shaped flange and the shaped recess cooperate to locate the saver sub cutout in a predetermined unitary location and a predetermined unitary orientation relative to the mud inlet chamber each time the shaped flange is received into the shaped recess.
In other embodiments according to the first aspect, the mud inlet chamber and the saver sub chamber are straight throughbores subtending a predetermined mud flow angle. In some such embodiments, the predetermined mud flow angle is 45 degrees.
In other embodiments according to the first aspect, the mud inlet chamber, the saver sub and the saver sub cutout cooperate to form a smooth-walled passageway for fluid flow communication between at least the mud inlet chamber and the screen cage.
In other embodiments according to the first aspect, a downstream end of the saver sub cutout provides convex rim curvature.
In other embodiments according to the first aspect, the screen cage includes screen mesh for retaining solids during fluid flow through the screen cage. Alternatively, the screen cage may act as a retainer for a separate drop-in mud screen.
In a second aspect, embodiments of an MSM according to this disclosure comprise: a body, the body having mud flow inlet, a mud flow outlet and a screen insertion port; the body further having a saver sub chamber, a seal chamber, a screen chamber and a mud inlet chamber all formed therein, the seal chamber further providing a seal chamber interior surface formed thereon; wherein the screen insertion port is in fluid flow communication with the saver sub chamber, the mud flow outlet is in fluid flow communication with the screen chamber, and the seal chamber is in fluid flow communication with the saver sub chamber and the screen chamber; a hollow saver sub, the saver sub further having first and second saver sub ends, the saver sub having a cutout therein between the first and second saver sub ends; a shaped flange provided on the first saver sub end, the shaped flange disposed to be received into a correspondingly shaped recess formed in the saver sub chamber; an exterior of the second saver sub end having first and second seal portions formed therein with the first seal portion nearer the first saver sub end than the second seal portion; an elongate screen cage, the screen cage having an interior cage surface such that the interior cage surface forms a first contact seal with the saver sub second seal portion when the screen cage is rigidly connected to the second saver sub end; wherein, when the screen cage is rigidly connected to the second saver sub end, and when the saver sub and the screen cage are inserted through the screen insertion port and into the saver sub chamber such that the shaped flange is received into the shaped recess: (1) the mud flow inlet is in fluid flow communication with the saver sub cutout via the mud inlet chamber; (2) the saver sub is in fluid flow communication with the screen chamber via fluid flow through the screen cage; and (3) the saver sub first seal portion forms a second contact seal with the seal chamber interior surface.
In a third aspect, embodiments of an MSM according to this disclosure comprise: a body, the body having mud flow inlet, a mud flow outlet and a screen insertion port; the body further providing a saver sub chamber, a screen chamber and a mud inlet chamber all formed therein and all in fluid flow communication with each other; wherein the screen insertion port is in fluid flow communication with the saver sub chamber, and the mud flow outlet is in fluid flow communication with the screen chamber; a hollow saver sub, the saver sub further having first and second saver sub ends, the saver sub having a cutout therein between the first and second saver sub ends; wherein, when an elongate screen cage is rigidly connected to the second saver sub end, and when the saver sub and the screen cage are inserted through the screen insertion port and into the saver sub chamber such that the first saver sub end is towards the screen insertion port: (1) the mud flow inlet is in fluid flow communication with the saver sub cutout via the mud inlet chamber; (2) the saver sub is in fluid flow communication with the screen chamber via fluid flow through the screen cage; and (3) the mud inlet chamber, the saver sub and the saver sub cutout cooperate to form a smooth-walled passageway for fluid flow communication between at least the mud inlet chamber and the screen cage.
In other embodiments according to the third aspect, a shaped flange is provided on the first saver sub end, the shaped flange disposed to be received into a correspondingly shaped recess formed in the saver sub chamber; wherein the shaped flange and the shaped recess cooperate to locate the saver sub cutout in a predetermined unitary location and a predetermined unitary orientation relative to the mud inlet chamber each time the saver sub is inserted through the screen insertion port such that the shaped flange is received into the shaped recess.
In other embodiments according to the third aspect, the mud inlet chamber and the saver sub chamber are straight throughbores subtending a predetermined mud flow angle.
The foregoing has rather broadly outlined some features and technical advantages of the disclosed MSM, 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 the embodiments described in this disclosure, and their advantages, reference is made to the following detailed description taken in conjunction with the accompanying drawings, in which:
For general reference,
Extraction is essentially the reverse. If installed, magnetic rod 331 may be extracted once screen insertion port 305 is opened via removal of end flange 306, end gasket 307 and end plug 308. Tool T may be adapted to provide a suitable hexagonal key to engage the hexagonal recess provided in a head portion of magnetic rod 331, and then unscrew same. With magnetic rod 331 removed, tool T may threadably engage saver sub interior threads 361 and extract screen cage 321 and saver sub 341. Screen cage 321 may then be unscrewed from saver sub 341.
An open design is thus provided in illustrated embodiments in order to enable an internal pressure wash, if desired, before complete disassembly. The pressure wash removes an initial quantity of solids and debris from the assembled screen cage 321 and saver sub 341 while they are still resident in body 301. The initial removal of solids and debris also facilitates extraction of the assembled screen cage 321 and saver sub 341. If desired, the pressure wash may be done after removal of end flange 306, end gasket 307 and end plug 308, or alternatively after removal of magnetic rod 331 (if present).
In other embodiments (not illustrated), further internal threads may be provided on saver sub 341 immediately adjacent to and inside shaped flange 342. Tool T may be adapted to engage these further internal threads during insertion and extraction, rather than engaging interior threads 361 (shown on
In other embodiments (not illustrated), shaped flange 342 may be provided on saver sub 341 as a solid blank flange sealing off the end of saver sub 341. In such embodiments, a threaded hole may be provided blank shaped flange 342, in the surface thereof facing screen insertion port 305. Preferably, the threaded hole would not penetrate blank shaped flange 342. Tool T may be adapted to provide a corresponding threaded rod for engagement of the threaded hole. Once engaged in the threaded hole, tool T may then be used to perform insertions or retractions through insertion port 305. Alternatively, in embodiments in which the threaded hole penetrates blank shaped flange 342, a threaded plug may be used to close off the threaded hole prior to closing up insertion port 305.
Field testing has demonstrated high wear performance of MSM embodiments as described in this disclosure. In one field test, an MSM embodiment according to this disclosure was placed in standard drilling fluid service for 2,200 circulating hours before replacement of the screen cage. Inspection of the interior of the saver sub revealed only 0.002″ wear and no cavitation present (suggesting low turbulence in fluid flow). No prior surface hardening or wear coating had been done on the internals.
In a second field test, an MSM embodiment according to this disclosure was placed standard drilling fluid service for 2,170 circulating hours. The average working fluid pressure was 3,400 psi, the average flow rate was 600 gpm and the average fluid temperature was 175 deg F. at the rig floor. Inspection of the interior of the saver sub revealed less than 0.003″ wear and no cavitation present (again, suggesting low turbulence in fluid flow). As before, no prior surface hardening or wear coating had been done on the internals.
With reference now to
In more detail, saver sub embodiments 341 and 351 thus differ further in the design of corresponding cutouts 343 and 353. As noted, saver sub 351 provides additional convex rim curvature 372 on the downstream end of saver sub cutout 353 in saver sub 351. Generally, per discussion of
The selection of a preferred mud flow angle 316 of 45 degrees is as a result of trial and error, balancing competing design factors. A lower mud flow angle 316 tended to cause greater wear to screen cage 321 and thus more frequent failures of screen cage 321, due to increased velocity of fluid flow F carrying unscreened solids and debris impacting screen cage 321. Increased velocity of fluid flow F also tended to increase turbulence in the portion of saver sub 341 resident in saver sub chamber 313 on
Referring now to
Similarly, now referring to
It will be appreciated that in some embodiments (not illustrated), magnetic rod 331 may be omitted from MSM 300, particularly in deployments where metal cuttings and other ferromagnetic debris are not expected to be encountered in the fluid passing through MSM 300.
Currently preferred embodiments of MSM body 301 are manufactured from one of two material designations, “75K” and “100K”, with material specifications as set forth in Table 1 below. 75K and 100K are made from ASTM/AISI 4130 steel, with the following Charpy V-notch test (CVN) requirement per ASTM 370:
999 lbs
It will be understood from Table 2 and
With reference now to
Referring again to
With further reference to
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 as defined by the appended claims. It will be further appreciated by those skilled in the art that the concepts 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 and/or as claimed.
This application claims the benefit of and priority to commonly-invented and commonly-assigned U.S. Provisional Application Ser. No. 62/560,652, filed Sep. 19, 2017. The entire disclosure of 62/560,652 is incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
834431 | Williams | Oct 1906 | A |
1112117 | Carbis | Sep 1914 | A |
2855048 | Jones | Oct 1958 | A |
3302722 | Madeley, Sr. | Feb 1967 | A |
4090573 | Rankin | May 1978 | A |
4106562 | Barnes | Aug 1978 | A |
4495073 | Beimgraben | Jan 1985 | A |
5738172 | van Mook | Apr 1998 | A |
6598685 | Mashburn | Jul 2003 | B1 |
7980330 | LeJeune | Jul 2011 | B1 |
8002028 | Swietlik | Aug 2011 | B2 |
8047278 | Swietlik | Nov 2011 | B2 |
8127867 | Droke | Mar 2012 | B1 |
8573306 | Donald | Nov 2013 | B2 |
8746340 | Mashburn | Jun 2014 | B2 |
9657554 | Morton, Jr. | May 2017 | B2 |
20040079551 | Herst | Apr 2004 | A1 |
20040238180 | McGee | Dec 2004 | A1 |
20050109503 | Kutryk | May 2005 | A1 |
20060065443 | Hall | Mar 2006 | A1 |
20060065444 | Hall | Mar 2006 | A1 |
20060213667 | Mashburn | Sep 2006 | A1 |
20100236833 | Hall | Sep 2010 | A1 |
20140311343 | Hendrix | Oct 2014 | A1 |
20180135371 | Cherewyk | May 2018 | A1 |
20180313178 | Biggerstaff | Nov 2018 | A1 |
Number | Date | Country |
---|---|---|
2877020 | Oct 2015 | CA |
Entry |
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Prior art Youtube video posted Jul. 29, 2014 showing conventional mud screen operations. See particularly at about 1:00 mins to 1:20 mins—https://www.youtube.com/watch?v=KZxUiFFVEAQ&feature=youtu.be. |
Number | Date | Country | |
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20190085663 A1 | Mar 2019 | US |
Number | Date | Country | |
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62560652 | Sep 2017 | US |