U.S. patent application number 13/182331 was filed with the patent office on 2011-11-03 for threaded union for tubulars used in high-pressure fluid applications.
This patent application is currently assigned to Stinger Wellhead Protection, Inc.. Invention is credited to Bob McGuire.
Application Number | 20110266795 13/182331 |
Document ID | / |
Family ID | 40787702 |
Filed Date | 2011-11-03 |
United States Patent
Application |
20110266795 |
Kind Code |
A1 |
McGuire; Bob |
November 3, 2011 |
THREADED UNION FOR TUBULARS USED IN HIGH-PRESSURE FLUID
APPLICATIONS
Abstract
A threaded union for tubulars used for high-pressure fluid
applications includes a unitary nut supported by at least two nut
retainer segments received under a top wall of the nut in an
annular segment retainer groove in one of the tubulars. The nut
retainer segments fully support the unitary nut. The nut retainer
segments are held in the annular segment retainer groove by
limiting travel of the nut or by securing the nut retainer segments
in the segment retainer groove.
Inventors: |
McGuire; Bob; (Meridian,
OK) |
Assignee: |
Stinger Wellhead Protection,
Inc.
Oklahoma City
OK
|
Family ID: |
40787702 |
Appl. No.: |
13/182331 |
Filed: |
July 13, 2011 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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12002823 |
Dec 19, 2007 |
7984932 |
|
|
13182331 |
|
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Current U.S.
Class: |
285/354 |
Current CPC
Class: |
F16L 19/00 20130101;
F16L 19/0231 20130101 |
Class at
Publication: |
285/354 |
International
Class: |
F16L 19/00 20060101
F16L019/00 |
Claims
1. A threaded union for first and second tubulars having mating
ends, comprising: a unitary nut having a top wall, an outer
sidewall, an inner sidewall and a depending skirt defining a box
thread that engages a pin thread on a male end of the second
tubular, the top wall extending past the inner sidewall to define a
top flange that extends to and closely surrounds an outer sidewall
of the first tubular; at least two P-shaped nut retainer segments
for supporting the top flange of the unitary nut, the P-shaped nut
retainer segments having a head portion and a depending leg
portion, the head portion being closely received in an annular
segment retainer groove in an outer sidewall of the mating end of
the first tubular and the depending leg portion substantially
filling a gap between the inner sidewall of the unitary nut and the
outer sidewall on the mating end of the first tubular; and an
O-ring received an O-ring groove in an outer sidewall of the
P-shaped nut retainer segments to hold the P-shaped nut retainer
segments in the annular segment retainer groove.
2. The threaded union as claimed in claim 1 comprising at least two
O-rings respectively received in spaced-apart O-ring grooves in the
outer sidewall of the P-shaped nut retainer segments to hold the
P-shaped nut retainer segments in the annular segment retainer
groove.
3. The threaded union as claimed in claim 1 further comprising an
annular relief groove at a top of the inner sidewall of the unitary
nut to inhibit the unitary nut from binding on the P-shaped nut
retainer segments.
4. The threaded union as claimed in claim 1 wherein the unitary nut
comprises a wing nut.
5. The threaded union as claimed in claim 1 wherein the unitary nut
comprises a spanner nut.
6. A threaded union for first and second tubulars having mating
ends, comprising: a unitary nut having a top wall, an outer
sidewall, an inner sidewall and a depending skirt defining a box
thread that engages a pin thread on a male end of the second
tubular, the top wall extending past the inner sidewall to define a
top flange that extends to and closely surrounds an outer sidewall
of the first tubular; at least two P-shaped nut retainer segments
for supporting the top flange of the unitary nut, the P-shaped nut
retainer segments having a head portion and a depending leg
portion, the head portion being closely received in an annular
segment retainer groove in an outer sidewall of the mating end of
the first tubular and the depending leg portion substantially
filling a gap between the inner sidewall of the unitary nut and the
outer sidewall on the mating end of the first tubular; and a pin
slidably received in a smooth bore in a top wall of respective ones
of the at least two P-shaped nut retainer segments and a set screw
received in a threaded bore in an outer sidewall of respective ones
of the at least two P-shaped nut retainer segments, the threaded
bore communicating with the smooth bore so that the set screw can
be tightened against a bottom end of the pin to force the pin into
contact with a surface of the annular segment retainer groove to
retain the respective P-shaped nut retainer segments in the annular
segment retainer groove.
7. The threaded union as claimed in claim 6 wherein the pin
contacts a top surface of the annular segment retainer groove.
8. The threaded union as claimed in claim 6 wherein the pin further
comprises a smooth shaft and a head that is larger than the smooth
shaft.
9. The threaded union as claimed in claim 8 further comprising a
box thread in a top end of the smooth bore for receiving a collar
having a pin threaded outer wall, the collar surrounding the shaft
of the pin and permitting the shaft to reciprocate freely there
through, but preventing the head of the pin from passing so that
the pin cannot fall out of the smooth bore.
10. The threaded union as claimed in claim 6 further comprising an
annular relief groove at a top of the inner sidewall of the unitary
nut to inhibit the unitary nut from binding on the P-shaped nut
retainer segments.
11. The threaded union as claimed in claim 6 wherein the unitary
nut comprises a wing nut.
12. The threaded union as claimed in claim 6 wherein the unitary
nut comprises a spanner nut.
13. A threaded union for first and second tubulars having mating
ends, comprising: a unitary nut having a top wall, an outer
sidewall, an inner sidewall and a depending skirt defining a box
thread that engages a pin thread on a male end of the second
tubular, the top wall extending past the inner sidewall to define a
top flange that extends to and closely surrounds an outer sidewall
of the first tubular; at least two P-shaped nut retainer segments
for supporting the top flange of the unitary nut, the P-shaped nut
retainer segments having a head portion and a depending leg
portion, the head portion being closely received in an annular
segment retainer groove in an outer sidewall of the mating end of
the first tubular and the depending leg portion substantially
filling a gap between the inner sidewall of the unitary nut and the
outer sidewall on the mating end of the first tubular; and a
U-shaped spring clip received in a spring clip groove in the head
portion of respective ones of the at least two P-shaped nut
retainer segments, the spring clips having spring clip ends that
engage respective top and bottom surfaces of the annular segment
retainer groove when the respective P-shaped nut retainer segments
are inserted into the annular segment retainer groove.
14. The threaded union as claimed in claim 13 wherein the spring
clip further comprises inward bends near the spring clip ends, the
inward bends engaging locking notches in the spring clip grooves to
lock the respective spring clips in the respective spring clip
grooves.
15. The threaded union as claimed in claim 13 further comprising an
annular relief groove at a top of the inner sidewall of the unitary
nut to inhibit the unitary nut from binding on the P-shaped nut
retainer segments.
16. The threaded union as claimed in claim 13 wherein the unitary
nut comprises a wing nut.
17. The threaded union as claimed in claim 13 wherein the unitary
nut comprises a spanner nut.
Description
RELATED APPLICATIONS
[0001] This is a division of U.S. patent application Ser. No.
12/002,823 filed Dec. 19, 2007.
FIELD OF THE INVENTION
[0002] This invention relates in general to connections for
tubulars used to convey high-pressure fluids in the oil, gas and
chemical industries and, in particular, to a threaded union used to
join tubulars used in high pressure fluid applications.
BACKGROUND OF THE INVENTION
[0003] In the threaded union for tubulars, a threaded male end on
one of the tubulars is received by a female nut supported on a
shoulder formed on or supported by the other tubular. The threaded
union is a commonly used and popular connector for joining tubulars
in a wide variety of applications because it is relatively
inexpensive to manufacture and permits rapid end-to-end connection
of two tubulars without axial rotation of either tubular. While
threaded unions are popular, they generally lack the holding
strength of a flanged connection. This is due to either of two
factors, namely: the nut is dissected in two parts that are welded
together after the nut is positioned above a shoulder that supports
it; or, the top flange of the nut is weakened because it is reduced
in width to accommodate a multi-part collar that provides the
shoulder for supporting the nut. In high-pressure fluid
applications the strength of a threaded union is critical. This is
especially true in the oil and gas industry where tubulars are
often subjected to severe mechanical stresses as well as extreme
fluid pressures of 20,000 psi or more.
[0004] Therefore there exists a need for a threaded union for
tubulars used in high-pressure fluid applications.
SUMMARY OF THE INVENTION
[0005] It is therefore an object of the invention to provide a
threaded union for tubulars used in high-pressure fluid
applications.
[0006] The invention therefore provides a threaded union for first
and second tubulars having mating ends, comprising: a unitary nut
having a top wall, an outer sidewall, an inner sidewall and a
depending skirt defining a box thread that engages a pin thread on
a male end of the second tubular, the top wall extending past the
inner sidewall to define a top flange that extends to and closely
surrounds an outer sidewall of the first tubular; at least two
P-shaped nut retainer segments for supporting the top flange of the
unitary nut, the P-shaped nut retainer segments having a head
portion and a depending leg portion, the head portion being closely
received in an annular segment retainer groove in an outer sidewall
of the mating end of the first tubular and the depending leg
portion substantially filling a gap between the inner sidewall of
the unitary nut and the outer sidewall on the mating end of the
first tubular; and an O-ring received an O-ring groove in an outer
sidewall of the P-shaped nut retainer segments to hold the P-shaped
nut retainer segments in the annular segment retainer groove.
[0007] The invention further provides a threaded union for first
and second tubulars having mating ends, comprising: a unitary nut
having a top wall, an outer sidewall, an inner sidewall and a
depending skirt defining a box thread that engages a pin thread on
a male end of the second tubular, the top wall extending past the
inner sidewall to define a top flange that extends to and closely
surrounds an outer sidewall of the first tubular; at least two
P-shaped nut retainer segments for supporting the top flange of the
unitary nut, the P-shaped nut retainer segments having a head
portion and a depending leg portion, the head portion being closely
received in an annular segment retainer groove in an outer sidewall
of the mating end of the first tubular and the depending leg
portion substantially filling a gap between the inner sidewall of
the unitary nut and the outer sidewall on the mating end of the
first tubular; and a pin slidably received in a smooth bore in a
top wall of respective ones of the at least two P-shaped nut
retainer segments and a set screw received in a threaded bore in an
outer sidewall of respective ones of the at least two P-shaped nut
retainer segments, the threaded bore communicating with the smooth
bore so that the set screw can be tightened against a bottom end of
the pin to force the pin into contact with a surface of the annular
segment retainer groove to retain the respective P-shaped nut
retainer segments in the annular segment retainer groove.
[0008] The invention yet further provides a threaded union for
first and second tubulars having mating ends, comprising: a unitary
nut having a top wall, an outer sidewall, an inner sidewall and a
depending skirt defining a box thread that engages a pin thread on
a male end of the second tubular, the top wall extending past the
inner sidewall to define a top flange that extends to and closely
surrounds an outer sidewall of the first tubular; at least two
P-shaped nut retainer segments for supporting the top flange of the
unitary nut, the P-shaped nut retainer segments having a head
portion and a depending leg portion, the head portion being closely
received in an annular segment retainer groove in an outer sidewall
of the mating end of the first tubular and the depending leg
portion substantially filling a gap between the inner sidewall of
the unitary nut and the outer sidewall on the mating end of the
first tubular; and a U-shaped spring clip received in a spring clip
groove in the head portion of respective ones of the at least two
P-shaped nut retainer segments, the spring clips having spring clip
ends that engage respective top and bottom surfaces of the annular
segment retainer groove when the respective P-shaped nut retainer
segments are inserted into the annular segment retainer groove.
BRIEF DESCRIPTION OF THE DRAWINGS
[0009] Having thus generally described the nature of the invention,
reference will now be made to the accompanying drawings, in
which:
[0010] FIG. 1 is a schematic cross-sectional diagram of one
embodiment of a threaded union in accordance with the
invention;
[0011] FIG. 2 is a schematic cross-sectional diagram of the
embodiment shown in FIG. 1, with a first tubular configured with a
male end for a threaded union for the connection of equipment to
the first tubular;
[0012] FIG. 3 is a schematic cross-sectional diagram of the
embodiment shown in FIG. 1, with a first tubular configured with a
flange for the connection of flanged equipment to the first
tubular;
[0013] FIG. 4 is a schematic cross-sectional diagram of the
embodiment shown in FIG. 1, with a first tubular configured with a
flange used for a clamp connection of equipment to the first
tubular;
[0014] FIG. 5 is a schematic cross-sectional diagram of another
embodiment of the threaded union in accordance with the
invention;
[0015] FIG. 6 is a schematic cross-sectional diagram of yet another
embodiment of the threaded union in accordance with the
invention;
[0016] FIG. 6A is detailed cross-sectional diagram of a pin used to
lock nut retainer segments shown in FIG. 6 in an annular retainer
groove in a tubular that supports a nut for the threaded union in a
accordance with the invention;
[0017] FIG. 7 is a schematic cross-sectional diagram of yet another
embodiment of the threaded union in accordance with the invention,
in which a spring clip secures each nut retainer segment in an
annular segment retainer groove in the first tubular;
[0018] FIG. 7a is a detailed schematic top plan view of one of the
nut retainer segments shown in FIG. 7; and
[0019] FIG. 7b is an end elevational view of one of the spring
clips shown in FIG. 7.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0020] The invention provides a threaded union for tubulars used in
high-pressure fluid applications such as wellhead isolation tools,
frac irons, gas or oil pipelines, chemical plant piping, refinery
tubing and piping, and the like. The threaded union in accordance
with the invention is particularly robust and may be used to join
tubulars that conduct fluids at extreme pressures, in excess of
20,000 psi. A unitary nut turned from solid stock is fully
supported by a segmented retainer ring received in an annular
groove in a tubular that serves as the female end of the threaded
union. Because the unitary nut is fully supported, the threaded
union provides at least a holding strength of a bolted flange for
two tubulars of the same diameter.
[0021] FIG. 1 is a schematic cross-sectional diagram of a threaded
union 10 in accordance with one embodiment of the invention. The
threaded union 10 includes a unitary nut 12 that is turned from
solid stock, generally 1040 steel or the like, for high pressure
applications. The unitary nut 12 is fully supported by a nut
retainer ring that includes at least two P-shaped nut retainer
segments 14 received in an annular segment retainer groove 16 in a
first tubular 18. The first tubular 18 is connected to a second
tubular 20 by the nut 12. The nut 12 is typically a wing nut
provided with a plurality of hammer lugs 13. The hammer lugs 13
permit the wing nut to be tightened or "hammered up" using a hammer
in a manner well known in the art. However, the nut 12 may also be
a spanner nut, which is tightened using a spanner wrench in a
manner equally well known in the art.
[0022] The nut 12 has a top wall 22, an outer sidewall 24, an inner
sidewall 26 and a depending skirt 28. The top wall 22 extends
inwardly past the inner sidewall 26 to define a top flange 23 that
closely surrounds the first tubular 18. An inner wall of the
depending skirt 28 is threaded to form a box thread 30 that engages
a pin thread 32 on a male end 34 of the second tubular 20. As will
be understood by those skilled in the art, the box thread and the
pin thread must be engineered for maximum sheer strength, and the
thread pattern selected accordingly. The thread pattern may be, for
example, a 3 TPI (threads per inch) Acme thread or a 4 TPI Acme
thread. An annular relief groove 36 at a top of the inner sidewall
26 of the nut 12 helps to ensure that the nut 12 does not bind on
the nut retainer segments 14 when the nut 12 is subjected to
mechanical stress applied externally to the first tubular 18 or the
second tubular 20, or applied internally by extreme fluid
pressures. As explained above, the top flange 23 of the integral
nut 12 extends to and closely surrounds an outer sidewall 48 of the
first tubular 18.
[0023] Each of the P-shaped nut retainer segments 14 has a head
portion 37 closely received in the annular segment retainer groove
16 and a depending leg 44 that substantially fills a gap between
the outer sidewall 48 of the first tubular and the inner sidewall
26 of the nut 12. The head portion 37 has a top wall 38, a bottom
wall 39, an inner sidewall 40, and an outer wall 42. The outer wall
42 extends in a continuous straight line from the top wall 38 to a
bottom of the depending leg 44. An inner surface 46 of the
depending leg 44 rests against and is supported by the outer
sidewall 48 of the first tubular 18 below the annular segment
retainer groove 16. The outer sidewall 48 extends downwardly along
an entire length of the inner sidewall 26 of the unitary nut 12 and
provides support to reduce stress on the top flange 23 of the nut
12.
[0024] The nut retainer segments 14 are preferably held in the
annular segment retainer groove 16 by some kind of nut retainer
segment holder. In this embodiment, the nut retainer segments 14
are held in the annular segment retainer groove 16 by the nut 12.
Consequently, a nut travel limiter is used to ensure that the nut
12 keeps the nut retainer segments 14 in the annular segment
retainer groove 16. In this embodiment the nut travel limiter is at
least one short travel-limit bolt or stud 50a, 50b received in
threaded bores 52a, 52b in the outer sidewall 48 of the first
tubular 18 above the annular segment retainer groove 16 prevents
the nut 12 from sliding or being raised far enough above the
annular segment retainer groove 16 to permit the nut retainer
segments 14 to fall out of the annular segment retainer groove 16.
The female end of the threaded union 10 is assembled before the
travel-limit bolts or studs 50a, 50b are screwed into the threaded
bores 52a, 52b. The female end of the threaded union 10 is
assembled by sliding the unitary nut over the bottom end of the
first tubular 18 until the segment retainer groove 16 is exposed.
The nut retainer segments 14 are then inserted into the annular
segment retainer groove 16. The nut 12 is lowered over the nut
retainer segments 14, and the travel-limit bolts or studs 50a, 50b
are screwed into the threaded bores 52a, 52b. If the nut retainer
segments 14 require inspection, replacement or repair for any
reason, the travel-limit bolt(s) or stud(s) 50a, 50b can be removed
and the nut lifted to permit the nut retainer segments 14 to be
slid out of the annular segment retainer groove 16.
[0025] As will be understood by those skilled in the art, the
mating ends of the first tubular 18 and the second tubular 20 can
be configured in many ways to provide a fluid tight seal between
the first tubular 18 and the second tubular 20. In this embodiment,
the mating ends of the first tubular 18 and the second tubular 20
are configured as described in Assignee's co-pending United States
Patent application published on Jan. 18, 2007 under publication
number US2007/0013188 A1, now U.S. Pat. No. 7,484,776.
[0026] The male end 34 of the second tubular 20 includes a socket
54 that receives a pin end 56 formed on the mating end of the first
tubular 18. A metal ring gasket groove 58 in the bottom of the
socket 54 mates with a corresponding metal ring gasket groove 60 in
a bottom of the pin end 56. A metal ring gasket 62, described in
detail in the above-referenced patent application, is received in
the mating metal ring gasket grooves 58, 60 to provide a very high
pressure fluid seal between the mating ends of the first tubular 18
and the second tubular 20. A backup seal is provided by O-rings
66a, 66b received in O-ring grooves 64a, 64b in the pin end 56 of
the first tubular 18.
[0027] As explained above, the threaded union in accordance with
the invention may be used for many different purposes. FIG. 2 is a
schematic cross-sectional view of the threaded union 10 in which
the first tubular 18 is configured with a male end 68 configured
with a pin thread 70 to permit connection of a threaded adapter, or
the like (not shown). It should be understood that the male end 68
could be configured with a socket 54 containing the metal ring
gasket groove 58 as described above with reference to FIG. 1. In
this embodiment, the nut retainer segments 14 are held in the
annular segment retainer groove 16 by the nut 12, as explained
above. However, the nut travel limiter is one or more travel-limit
blocks 72a, 72b that are made to any required height. The
travel-limit blocks are respectively connected to the top wall 22
of the nut 12 by short bolts 74a, 74b received in threaded bores
76a, 76b in the top wall 22 of the nut 12 after the female end of
the threaded union 10 is assembled, as explained above with
reference to FIG. 1. When the nut 12 is raised or slides towards
the male end 68 of the fist tubular 18, the travel-limit blocks
contact the male end 68 of the first tubular 18 before the nut
retainer segments 14 are completely exposed by depending skirt 28
of the nut 12. Thus the nut retainer segments 14 are prohibited
from dislodging from the annular segment retainer groove 16. If the
nut retainer segments 14 must be removed for inspection or repair,
the travel-limit blocks 72a, 72b are removed and the nut lifted
upwards to expose the nut retainer segments 14 so they can be
removed from the annular segment retainer groove 16.
[0028] FIG. 3 is a schematic cross-sectional diagram of another
embodiment of the invention in which a top end of the first tubular
18 terminates in a flange 78 configured with a plurality of flange
bolt bores 80 and a metal ring gasket groove 82 in accordance with
API specifications. In all other respects, this embodiment is
identical to the embodiment described above with reference to FIG.
2.
[0029] FIG. 4 is a schematic cross-sectional view of yet another
embodiment of the invention in which a top end of the first tubular
18 terminates in a clamp connector flange 84, commonly referred to
as a Grayloc.RTM. connector flange, which is well known in the art.
A gasket groove 86 receives a clamp connector gasket, also well
known in the art. In all other respects, this embodiment is
identical to the embodiment described above with reference to FIG.
2.
[0030] FIG. 5 is a schematic cross-sectional diagram of yet a
further embodiment of the invention. In this embodiment, at least
one O-ring 88a, 88b holds the nut retainer segments 14 in the
annular segment retainer groove 16. The respective O-ring(s) are
received in at least one O-ring groove 90a, 90b. As will be
understood by those skilled in the art, although two O-rings 88a,
88b provide redundant backup, a single O-ring or three or more
O-rings may be used for the same purpose. Since the nut retainer
segments 14 are held in the annular segment retainer groove 16,
neither the travel-limit bolt(s) 50a, 50b nor the travel-limit
block(s) 72a, 72b is required to limit the travel of the nut
12.
[0031] FIG. 6 is a schematic cross-sectional diagram of yet another
embodiment of the threaded union 10 in accordance with the
invention. In this embodiment, the respective nut retainer segments
14 are held in the annular segment retainer groove 16 by a
cylindrical pin 92a, 92b that is received in a smooth bore 94a, 94b
in the top wall 38 in each nut retainer segment 14. A threaded bore
96a, 96b in the outer wall 42 of each nut retainer segment 14
communicates with a respective one of the smooth bores 94a, 94b and
receives a set screw 98a, 98b with a pointed end 100a, 100b. After
a nut retainer segment 14 is inserted into the annular segment
retainer groove 16, the set screw 98a, 98b is screwed inwardly so
that the pointed end 100a, 100b forces the pin 92a, 92b upwardly
against a top wall of the annular segment retainer groove 16 to
hold the nut retainer segments 14 in the annular segment retainer
groove 16 if the nut 12 is lifted or slides far enough to expose
the nut retainer segments 14.
[0032] FIG. 6a is a detailed view of an embodiment of the pin 92
that cannot fall out of a nut retainer segment 14. In this
embodiment, a top of the smooth bore 94a, 94b is threaded in a box
thread 104. The box thread is engaged by a pin thread 101 on an
outer wall of a threaded collar 102. A central passage of the
threaded collar 102 permits a shaft of the pin 92a, 92b to slide
freely there through but will not permit a head 106 of the pin 92a,
92b to pass, so the pin 92 cannot fall out of the bore 94.
[0033] FIG. 7 is a schematic cross-sectional view of yet another
embodiment of the invention. In this embodiment, the nut retainer
segments 14 are held in the annular segment retainer groove 16 by
spring clips 110a, 110b. Each spring clip 110a, 110b is received in
a spring clip groove 112 machined in each nut retainer segment 14,
shown in plan view in FIG. 7a. Each spring clip 110a, 110b is
generally U-shaped and includes opposed inward bends 113 that
engage locking notches 114 at opposite ends of the spring clip
groove 112. When the respective spring clips 110a, 110b, which are
shown in more detail in FIG. 7b, are pushed into the respective
spring clip grooves 112, the inward bends 113 clip into the locking
notches 114 to lock the spring clip in place. Opposed spring clip
ends 116 of the spring clips 110a, 110b extend slightly above the
respective top wall 38 and bottom wall 39 of the nut retainer
segment 14. When the respective nut retainer segments 14 are pushed
into the annular segment retainer groove 16, the spring clip ends
116 are forced downwardly, which forces the inward bends 113 deeper
into the locking notches 114 and the respective spring clip ends
116 grip the respective top and bottom surfaces of the annular
segment retainer groove 16 to hold the respective nut retainer
segments 14 in the annular segment retainer groove 16. If the nut
retainer segments 14 require inspection, maintenance or
replacement, the nut 12 is raised and the nut retainer segments 14
are simply pulled straight out of the annular segment retainer
groove 16. If the top and bottom surfaces of the annular segment
retainer groove 16 are very smooth, the spring clips 110a, 110b
pull out of the annular segment retainer groove 16 with the nut
retainer segments 14. However, if the top and bottom surfaces of
the annular segment retainer groove are rough or scored, the spring
clip ends 116 may catch and the inward bends 113 are forced out of
the locking notches 114. Consequently, the spring clips 110a, 110b
will remain in the annual segment retainer groove 16, but the
spring clips 110a, 110b may be easily removed from the annular
segment retainer groove 16 using a pair of pliers.
[0034] As will be understood by those skilled in the art, the
number of nut retainer segments 14 is a matter of design choice. At
least two are required.
[0035] The embodiments of the invention described above are only
intended to be exemplary of the threaded union 10 in accordance
with the invention, and not a complete description of every
possible configuration of the threaded union 10. The scope of the
invention is therefore intended to be limited solely by the scope
of the appended claims.
* * * * *