U.S. patent application number 10/774544 was filed with the patent office on 2004-08-12 for locking device and method for securing telescoped pipe.
This patent application is currently assigned to United States Pipe and Foundry Company, United States Pipe and Foundry Company. Invention is credited to Copeland, Daniel A., Holmes, William W. IV.
Application Number | 20040155458 10/774544 |
Document ID | / |
Family ID | 21785105 |
Filed Date | 2004-08-12 |
United States Patent
Application |
20040155458 |
Kind Code |
A1 |
Holmes, William W. IV ; et
al. |
August 12, 2004 |
Locking device and method for securing telescoped pipe
Abstract
A locking segment for use in connecting two lengths of pipe has
a radically extending heel that serves as a rotational brake. By
mating the brake into an annular trough, that is, by placing it
between two walls, the rotation of the segment can continue only
until points on the brake mure between the two walls. Rotation of
the segment in response to increasing thrust pressures can thereby
be arrested before the rotation causes the segment to bear on the
spigot with a radially inward force great enough to penetrate the
spigot.
Inventors: |
Holmes, William W. IV;
(Hoover, AL) ; Copeland, Daniel A.; (Bessemer,
AL) |
Correspondence
Address: |
BRADLEY ARANT ROSE & WHITE, LLP
INTELLECTUAL PROPERTY DEPARTMENT-NWJ
1819 FIFTH AVENUE NORTH
BIRMINGHAM
AL
35203-2104
US
|
Assignee: |
United States Pipe and Foundry
Company
|
Family ID: |
21785105 |
Appl. No.: |
10/774544 |
Filed: |
February 9, 2004 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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10774544 |
Feb 9, 2004 |
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10017889 |
Dec 12, 2001 |
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6688652 |
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Current U.S.
Class: |
285/104 ;
285/374 |
Current CPC
Class: |
F16L 37/0845
20130101 |
Class at
Publication: |
285/104 ;
285/374 |
International
Class: |
F16L 033/16 |
Claims
We claim:
1. A joint for pipes comprising a bell, a spigot partially disposed
within the bell, a locking segment disposed between the bell and
the spigot, and a retainer capable of holding said locking segment
in the bell during assembly, wherein said locking segment is
adapted to rotate in the absence of a fixed axis of rotation into
locking engagement between the bell and the spigot in response to
movement of the spigot outward of the bell, and wherein further the
locking segment is adapted to resist rotation in response to said
outward movement beyond a desired maximum rotation by muring
between a first surface of the bell and a second surface of the
bell, and wherein further the segment is adapted to resist rotation
beyond a desired limit of rotation in an opposite direction by
muring within the bell.
2. A method of controlling radial pressures exerted between a bell
and a spigot in a joint comprising the steps of a. Placing the
segment within the bell, and b. Rotating the segment against a
fulcrum on the interior of the bell such that a radially inward
portion of the segment rotates in the axially inward direction, c.
increasing radial forces between the bell and the spigot primarily
by rotating the locking segment about a different axis than the
fulcrum, and d. muring a portion of the segment between two
surfaces of the bell, whereby further rotation of the segment is
arrested.
3. A gasket for use in connecting a spigot within a bell having an
annular trough for receiving a portion of the gasket, the gasket
comprising a sealing portion, a retainer heel adapted to mate with
the annular trough, and a locking segment comprising a brake and a
toe, the toe having a tooth capable of penetrating into the spigot,
the brake being disposed at least partially within said retainer
heel, such that when said retainer heel is placed in the annular
trough at least a portion of the brake is disposed within the
annular trough, which brake possesses at least two points separated
by a distance greater than the width of the annular trough, such
that upon a maximum rotation a first of the at least two points
resistively meets a first wall of the annular trough while a second
of the at least two points resistively meets a second and opposing
wall of the annular trough, such that rotation is arrested, and
wherein further the brake aids in retention of the heel in the
annular trough during insertion of the spigot into the bell.
Description
[0001] This application is a Divisional of prior filed and
copending U.S. patent application Ser. No. 10/017,889, filed Dec.
12, 2001, and claims the benefit and priority of such prior
application, which is hereby incorporated by reference.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] This invention relates generally to connections between
lengths of pipe, or between pipes and fittings. More particularly,
the invention is directed toward a device and method of connecting
two lengths of pipe in a restrained joint configuration, while
employing a locking segment that is self-braking to prevent
over-rotation and penetration of a spigot.
[0004] 2. Description of Related Art
[0005] Due to thrust forces, earth movement, and external
mechanical forces exerted on pipes, the industry has focused
substantial attention on the problem of maintaining connections
between adjacent lengths of pipe after installation. The result of
this attention is a library of differing solutions and approaches
known in the art. The majority of these solutions can be
categorized into either "push-on" joints or "mechanical
joints."
[0006] Push-on solutions are exemplified by U.S. Pat. No.
2,953,398, and account for the majority of straight-run pipe
connections. In a typical configuration, a spigot end of a pipe
slides into a bell end of another pipe past a tightly fitted
gasket. A variation of the push-on joint is evidenced by U.S. Pat.
No. 2,201,372, to Miller, which employs a compression snap-ring
fitted within a special lip of the bell, in order to exert pressure
onto locking segments and thus drive them into the spigot,
restraining the joint against thrust forces. U.S. Pat. No.
3,445,120, to Barr, likewise employs a gasket with stiffening
segments completely encased therein that are generally disposed
such that they and the gasket may roll between a locking and a free
position. As the Barr gasket-rolls under extraction forces, it is
intended eventually to encounter a position in which the stiffened
plane needs to compress for further rolling, in theory terminating
the rolling and restraining the joint.
[0007] Other examples of restrained push-on joints include U.S.
Pat. Nos. 5,295,697; 5,464,228; and 5,067,751. The securement of
the connection in such references is effected by locking segments
or wedges within the gasket that engage the spigot. The locking
segments possess a groove that mates with an annular rib on the
bell, such that the rib acts as a rocker, or cam, or during some
movements, as a wedge. During insertion of the spigot into the
bell, the segments rotate on the rib, but are prevented from
appreciable straight-line movement by the mating of the rib and
groove. Upon experiencing counter-forces tending to effect removal
of the spigot, the rib acts as a cam, both causing the segments to
pivot on the rib as an axis, and exerting a radially inward
pressure as the segment attempts to slide past the rib.
BRIEF SUMMARY OF THE INVENTION
[0008] A locking segment for use in a restrained joint avoids
over-rotation and penetration of the inserted spigot by muring
between two surfaces in the bell, thus arresting rotation before
positions are reached in which pressures on the spigot would result
in likely penetration. The segment therefore can rotate to an
effective locking degree, upon which rotation the radial forces by
which the segment bites into the pipe increase. By virtue of the
muring that prevents rotation beyond a desired maximum, a graph of
the relationship between a radial force exerted by the segment on
the spigot, in relation to the thrust force experienced could show
a radial force that generally increases as thrust forces increase,
but only up to a given point. At that point, the line representing
radial force could be made to substantially plateau. By selection
of materials and configurations, the plateau may be fixed below a
spigot penetration value.
OBJECTS OF THE INVENTION
[0009] The following stated objects of the invention are
alternative and exemplary objects only, and no one or any should be
read as required for the practice of the invention, or as an
exhaustive listing of objects accomplished.
[0010] As suggested by the foregoing discussion, an exemplary and
non-exclusive alternative object of this invention is to provide a
locking segment that is capable under certain conditions of
self-braking, to prevent over-rotation or other un-capped increases
in radially inward pressure as thrust forces increase.
[0011] A further exemplary and non-exclusive alternative object is
to provide a joint in which a locking segment is capable of
selectively converting a portion of thrust forces into radially
inward pressures, up to a maximum radial pressure that is
thereafter unaffected by increasing thrust forces.
[0012] A further exemplary and non-exclusive alternative object is
to provide a joint that counters extraction of a spigot by
distributing thrust forces into opposing axial forces in the bell,
and a radial force between bell and spigot that has a maximum,
which is below the magnitude of force that would fail the
spigot.
[0013] A further exemplary and non-exclusive alternative object is
to provide an effective restrained joint that resists
over-penetration of the spigot.
[0014] The above objects and advantages are neither exhaustive nor
individually or collectively critical to the spirit and practice of
the invention, except as stated in the claims. Other or alternative
objects and advantages of the present invention will become
apparent to those skilled in the art from the following description
of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
[0015] FIG. 1 shows a diagram of a cut-away of the gasket and
locking segment of the present invention, in place in a bell of a
pipe, and in an unstressed position (in absence of a spigot, with
spigot position shown by dotted horizontal).
[0016] FIG. 2 depicts a close detail of an embodiment of the
segment of the present invention, in profile.
[0017] FIG. 3 demonstrates the cross-sectional view of the gasket
and locking segment of the present invention in the presence of a
spigot segment during the insertion movement.
[0018] FIG. 4 is a drawing of the locked pipe joint under the
present invention, following insertion and extraction thrusts,
wherein the segment is fully engaged with the spigot to prevent
extraction.
[0019] FIG. 5 is a gasket as in the present invention, shown in
cut-away for viewing a cross-sectional profile at location of an
embedded segment.
DETAILED DESCRIPTION OF THE INVENTION
[0020] The following is a detailed exemplary description of an
embodiment of the invention, in a number of its various aspects.
Those skilled in the art will understand that the specificity
provided herein is intended for illustrative purposes with respect
to an exemplary embodiment, and is not to be interpreted as
limiting the scope of the invention or claims. References to "pipe"
in this document, when used with respect to the present invention,
shall be understood equally to refer to any pipe length,
appurtenance, fitting, connection, or any other connected or
connectable device or element.
[0021] As is depicted in FIGS. 1 and 2, the locking segment 1 of
the present invention is optimally constructed to fit within a
gasket 30 that is configured to fit within any standard push-on
bell having a gasket seat configured with an annular trough 47,
also known as a keeper groove, without necessitating changes to the
configuration of the bell or spigot. Alternatively, the locking
segment 1 of the present invention can be used with a mechanical
joint having a thrust ring or gland follower, rather than a cast
bell lip 44, so long as an annular trough 47 is present in the
assembled joint. In the spirit of the invention, non-standard bell
configurations may be constructed to fall within the claims.
[0022] Looking to FIG. 1, as will be understood in the art, a
typical bell configuration (standard or non-standard) will exhibit,
at a minimum, a socket area of the bell 40, having an increased
internal diameter as compared to the flow-area internal diameter of
the bell pipe. A bell lip 44 extends in a generally radial
direction, which serves as an externally visible face of the bell.
Moving axially inwardly of the bell lip 44, in the direction of
insertion (shown by arrow 64), the bell 40 has a cavity for
receiving and mating with the spigot 70. In assembled operation,
following insertion of a spigot 70, the cavity will take the form
of an annular gap 60 between the spigot and the bell cavity
boundary 45, which cavity boundary 45 in the shown embodiment is
represented by a generally cylindrical internal wall of the bell,
but which also may have ridges, ribs, gasket retainers, steps,
varying radial depths, and other non-cylindrical characteristics
such as gasket compression rib 48, as depicted in FIG. 4.
[0023] In addition to the cavity boundary 45, the shown internal
configuration of bell 40 includes an annular trough 47, arranged
and suited in the shown configuration for the purpose of
positioning a sealing gasket or other materials. This annular
trough 47 may be located immediately adjacent the internal side of
bell lip 40, as it appears in the shown embodiment (FIG. 1), or it
may divide cavity boundary 45 into two axially separated sections.
This annular trough 47 is bounded at its radial extreme by a trough
terminus 42, which may be cylindrical as shown in the figures, or
may be of other geometry, and is bounded on axially inward and
outward sides a first interior surface and a second interior
surface opposing the first interior surface, shown in the figures
as a first wall 43 and second wall 41, respectively. Trough first
and second walls 43 and 41 are generally radially extending, though
they may have a curved or slanted geometry, so long as they do not
detract from the ability to brace the mured braking effect
described in summary above or in greater detail below. As shown in
FIG. 1, the second wall 41 is joined to cavity boundary 45 at a
shoulder that serves as an insertion fulcrum 46 during assembly,
but which during extraction movements of spigot 70 bears no force
and presents no radially inward cam-type influence on segment 1.
Notably in the shown embodiment, the segment 1 possesses no
radially outwardly protruding surfaces outside of annular trough 47
that would impede substantially straight-line movement of segment 1
as a whole in the direction of the bell lip 44.
[0024] Moving still further inward of the annular trough 47 and the
cavity boundary 45, the bell 40 possesses a shoulder 52 stepping
the interior profile of the bell 40 to a lower radius of clearance.
As will be understood in the art, this shoulder acts as a stop to
further insertion of the spigot 70.
[0025] Looking now at FIG. 5, an embodiment of a gasket 30 for use
with the present invention is shown. As will be appreciated in the
art, shown gasket 30 is configured with a bulb 32 for sealing a
joint against fluid leakage. To this end, the gasket may be a
complete ring with its outer diameter approximating or slightly
greater than the inner diameter of bell 40 at the location into
which gasket 30 is to fit. This bulb may be of an elastomeric or
other resilient material sized with consideration taken to its
elasticity and compressibility. In operation of the joint, if the
gasket 30 is intended to seal the joint, it should be sized to fit
within the annular gap 60 only upon some compression between the
spigot 70 and the bell 40. In particular, for any given spigot 70,
gasket 30 tends to have a slightly smaller inner diameter than the
outer diameter of the spigot 70. Accordingly, insertion of spigot
70 into bell 40 will require exertion of force sufficient to
compress gasket 30 against cavity boundary 45. In addition to the
bulb 32, gasket 30 possesses a retainer heel 31, configured to mate
with annular trough 47 in such a manner that when gasket 30 is
installed in bell 40, retainer heel 31 fits within annular trough
47 and positions bulb 32 such that gasket 30 is appropriately
oriented. Typically, though not necessarily, retainer heel may be
constructed of an elastomer of a higher durometer rating than that
of bulb 32. As will be understood in the art, this is because bulb
32 should desirably be capable of flexibility and compression for
sealing efficiency, while an increased firmness of retainer heel 31
may allow the retainer heel 31 to remain mated within annular
trough 47 despite axial movement of spigot 70.
[0026] In addition to sealing, gasket 30 retains locking segment 1
within a range of desired orientations during assembly. It thus
should be understood that the gasket 30 need not necessarily
effectively perform a sealing function to fall within the scope of
the invention. Although in the shown embodiment and the remainder
of this description the gasket 30 is sufficient to provide a
sealing function, the inventors recognize within the spirit and
scope of one alternative embodiment that the shown gasket 30 may be
substituted with a simple positioning body, or retainer, operating
to hold the locking segments 1 in a desired range of orientations
during assembly. In such alternative, the gasket 30 need not have
sealing properties, nor be continuous about the perimeter. It is
possible in such alternative that the retainer be a wire or snap
ring urging the locking segment 1 radially outward.
[0027] Turning now to FIG. 2, an embodiment of a locking segment 1
is depicted. Reference to directions and orientation in this
description of the shown locking segment 1 is made with respect to
the orientation of the locking segment 1 as installed in a bell 40,
seen in FIG. 1. Locking segment 1 generally may be divided for
discussion purposes into a first portion, or brake 12, and a second
portion, or toe 13. Brake 12 extends radially outwardly of toe 13.
Toe 13 is constructed to engage spigot 70, at least upon movement
of spigot 70 in an extraction direction. To facilitate this
engagement, the shown toe 13 is configured as a wedge or triangular
shape, and possesses on its radially inward bottom 9 as a toothed
surface with at least one tooth 7, which is constructed of a
material having a hardness sufficient to penetrate the surface of
spigot 70. In the shown embodiment, the radially outward side of
toe 13 opposite bottom 9 is top 8, is shown without teeth or any
protrusion or extension that could impinge, rotate, or resistively
meet cavity boundary 45. As shown top 8 joins to axially inward
heel side 14 at a transition point 6. Similarly, bottom 9 joins an
axially outward side of brake 12 at a braking elbow 2. Outward side
11 and inward side 14 are connected at their radial extremes by a
mating surface 10. In the shown embodiment, the transition from
inward side 14 to mating surface 10 serves also as forward brake 3,
though it will be understood from the discussion below that the
forward brake 3 need not necessarily be at the intersection of
inward side 14 and mating surface 10 (e.g., it could be a
protrusion or nub in the middle of inward side 14, or adapt a
functionally similar alternative location). Similarly, the shown
embodiment features an insertion brake 5 located as a portion of
outward side 11 near outer comer 4, though the insertion brake 5
and outer comer 4 can in some embodiments be coincident, and,
indeed, even in the shown embodiment the outer comer 4 may perform
the insertion braking function of insertion brake 5 to some degree.
In the shown embodiment, segment 1 appears with the angle between
the toe and the heel between approximately 120 degrees and 170
degrees.
[0028] As can be seen readily from FIG. 1, brake 12 is held by
gasket 30 (or other retainer used in place of gasket 30) at least
partially within annular trough 47, and having at least a portion
of toe 13 extending exteriorly of the annular trough 47, and
radially inward of the same, to allow contact between a tooth 7 and
the spigot 70 in some orientations of locking segment 1. While the
figures show an embodiment having the toe 13 extending from the
annular trough, it is conceivable within the scope of the invention
that the locking segment 1, including all portions of toe 13, may
in some alternative embodiments reside entirely within the annular
trough 47, so long as the toe 13 is capable of making resistive
contact with spigot 70, whether by alternative configurations of
the bell 40 or the spigot 70. For ease of application to a wide
range of spigots 70 and bells 40 as are already present in the
market, the inventors have shown the particular embodiment having a
toe 13 extending from annular trough 47 to meet spigot 70, rather
than an embodiment that may rely on special configurations of
spigot 70.
[0029] In assembly, locking segment 1 is molded into or inserted
into gasket 30, with the brake 12 of locking segment 1 extending
into the retainer heel 31 of gasket 30, as may be seen from the
cut-away of FIG. 5. Although not shown, the brake 12 can, in
addition to extending into retainer heel 31, extend beyond the
retainer heel 31, such that the brake 12 is visible from outside
the retainer heel 31. As shown, the tooth 7 should be sufficiently
near the surface of bulb 32 to allow penetration of the bulb and
direct contact with spigot 70. It will be understood in the art
that some alternative embodiments may not require or encourage
direct spigot 70-to-tooth 7 contact. In such cases, the operation
of the invention may continue in effect, though appropriate
modifications may be necessary to provide a sufficient resistance
between the locking segment 1 and spigot 70, such as special ribs
or notches formed onto the spigot 70. Regardless of the mode of
contact between locking segment 1 and spigot 70, typically, though
not absolutely necessarily, a number of locking segments 1 will be
dispersed about gasket 30. In the shown embodiment, fifty-six
locking segments 1 are dispersed about a thirty-six inch diameter
spigot 70. The inventors' experiments suggest the invention will
bring ready improvements over the art to at least thirty through
sixty-four inch pipe; the invention is applicable to smaller
diameters and possibly to larger diameters as well, and, though not
empirically tested, is expected to provide excellent results.
[0030] Furthering the assembly, the gasket 30 is placed within bell
40, such that retainer heel 31 mates with annular trough 47. This
assembly arrangement will cause brake 12 also to be at least
partially within annular trough 47, and toe 13 to extend out of the
annular trough 47 and into the cavity 49 (i.e., in presence of a
spigot 70, the annular gap 60). In this orientation, prior to
extraction movements of a spigot, segment 1 is in a resting
position. The presence of the retainer heel 31 in annular trough 47
tends to secure the gasket 30 in place against axial displacement.
In some embodiments, the locking segments 1 may further this
securement, as well. Following insertion and seating of the gasket
30, spigot 70 is inserted into the bell 40 by movement in the
direction of arrow 64. As spigot 70 passes lip 44, it will come
into contact with gasket 30. Upon insertion pressures, spigot 70
will tend to push gasket 30 axially inwardly, but as a body, gasket
30 resists such movement due to the securement of retainer heel 31
in annular trough 47. Consequently, bulb 32 is compressed within
the annular gap 60, as may be seen in FIG. 3. It will be understood
that this compression has a number of effects. Among the effects
are the sealing of the joint against fluid flow through the annular
gap 60, and the relative centering of the spigot 70 within the
cavity 49 due to circumferentially distributed pressures of the
gasket 30.
[0031] As the gasket is compressed, it will be evident to those in
the art that the locking segment 1 will rotate such that the toe 13
moves radially outwardly, but heel 12, being engaged with the
annular trough 47, has a limited range of radial movement. In
operation, during insertion the shown locking segment 1 rotates
against insertion fulcrum 46, pivoting about this point as an axis
of rotation. It will be understood by those in the art that
although the insertion fulcrum 46 is shown as a right-angle
shoulder, alternative embodiments of the joint described and
claimed herein may form insertion fulcrum 46 as a rib raised in a
radially inward direction from the cavity boundary 45, or as a
depression at the intended location for locking segment 1, recessed
radially outwardly from cavity boundary 45 to create a more gentle
or a cammed fulcrum or other effect. The locking segment 1 is
constructed and oriented in such a manner as to allow the locking
segment 1 enough rotational freedom within the annular trough 47
and the annular gap 60 to accommodate entry of the spigot 70 into
the cavity 49. With the particular embodiment shown, due to the
closely mated profiles of the heel 12 and the annular trough 47,
the radially outward rotation of toe 13 as it pivots on insertion
fulcrum 46 may be limited by the contact between insertion brake 5
(which may be coincident with outer comer 4) and a wall of trough
47. In addition to other reasons, the inventors have drawn the
locking segment 1 in this manner to take advantage of the enhanced
retention of the gasket 30 in annular trough 47 made possible by
braking rotation of the locking segment 1 on insertion. The shown
configuration allows sufficient rotation to allow insertion of
spigot 70 without extrusion or gouging of the surface of spigot 70.
In some applications, the user may desire to provide a tighter fit,
even one that causes such gouging or scraping, in order to ensure
an early bite of the tooth 7 into spigot 70.
[0032] Following insertion, thrust forces and other forces tending
to urge separation of the bell 40 and the spigot 70 will typically
cause the spigot 70 to move in an extraction direction (e.g., along
the direction of arrow 63) relative to bell 40. By virtue of the
pressure exerted by bulb 32 of gasket 30, tooth 7 will be in
proximity to spigot 70, if not in direct contact. In one
embodiment, tooth 7 is, in the uncompressed state of gasket 30,
already exposed. This exposure may be by protrusion from the
surface of gasket 30, or by slight recessing beneath the surface in
combination with the absence of gasket material covering the teeth.
An alternative embodiment presents tooth 7 slightly recessed within
gasket 30, and covered by a membrane or thin layer of compressible
or puncturable material, so long as the depth and placement of
tooth 7 are adapted to ensure engagement between tooth 7 and spigot
70 upon compression of gasket 30. In the shown configuration,
locking segment 1 possesses a plurality of teeth 7, the tips of
which are arranged in an arcuate relationship. The arcuate
relationship enhances the ability of at least one tooth 7 to bite
into spigot 70 despite any variations in circumference of spigot 70
or the inner dimensions of bell 40. This is because a larger
annular gap (frequently due to manufacturing tolerances) will cause
locking segment 1 in assembly to be rotated toward a less acute
engagement angle 62 than exists in an installation having a larger
spigot 70. Given the arcuate relationship of teeth 7, upon such
rotation of locking segment 1 the teeth nearest the end of toe 13
rotate into contact with spigot 70. The arcuate configuration
further urges at least two teeth 7 to be in contact with spigot 70,
regardless of the rotation of segment 1, because a straight line
can be drawn between any two adjacent teeth 7.
[0033] In response to extraction movements of the spigot 70,
locking segment 1 will attempt to move in an extraction direction
along with spigot 70, but axial movement of the entire body of
locking segment 1 is prevented by the pressing of brake 12 against
first wall 43. Locking segment 1 then rotates such that toe 13
moves radially inwardly toward spigot 70. As the locking segment 1
of the shown embodiment rotates, the slope of brake 12 allows that
portion of locking segment 1 to slide upwards against the wall of
annular trough 47, preventing premature binding. The rotation of
locking segment 1 is caused even in the absence of a pre-existing
engagement of tooth 7 with spigot 70 due to friction between the
spigot 70 and the bulb 30 in which locking segment 1 is disposed.
If not already in biting engagement, as such rotation continues,
tooth 7 engages with spigot 70 by digging into the surface of
spigot 70. Thus the further movement of spigot 70 causes a
concomitant radially inward rotation of toe 13. Those in the art
will understand that the relationship between the force of the
axial thrust pressures on spigot 70 is by this process transferred
in part into a radially inward force between the spigot 70 and the
locking segment. The dynamic nature of the relationship results in
increased biting, or digging of tooth 7, into spigot 70 as the
pressures increase. To a point, this increasing radial pressure is
advantageous, as greater radial pressure and the bite of tooth 7
exerted thereby may be necessary in response to greater axial
extraction forces. It will be understood, however, that each spigot
70 will have a maximum sustainable radial pressure threshold, above
which radial pressures exerted by the locking segment 1 cause or
make likely a complete penetration of the spigot 70 by locking
segment 1, and thus failure of the joint. As described below, the
arrangement of locking segment 1 in concert with bell 40 prevents
exceeding such pressures in the current invention.
[0034] The brake 12 of the locking segment 1 fits within annular
trough 47 in such a manner that it has limited rotational freedom.
Upon rotation of toe 13 radially inwardly, it will be understood
that brake 12 also rotates. Due to the confines of annular trough
47, rotation of brake 12 is arrested by the muring of brake 12
between the first wall 11 and the second wall 41. For the sake of
clarity, Applicant notes that by the terms `muring` and `mures,` we
mean throughout this disclosure that the segment adopts a position
in which further rotation is constrained by the walls. As shown,
the braking elbow 2 is forced during this muring against the first
wall 43, and the forward brake 3 is forced against the second wall
41, resulting in a braked position for segment 1. It should be
understood that, while forward brake 3 and braking elbow 2 are
shown in the figures as terminating points on the inward side 14
and of the outward side 11 of brake 12, the invention is not so
limited. Either or both forward brake 3 and brake elbow 2 can be
protrusions from the respective sides, not necessarily located at
the comers, so long as they are capable of muring between the first
wall and the second wall in response to rotation. Additionally,
given the variations in spigot and bell diameters experienced in
real world applications, some configurations of brake 12 having a
more rounded profile may not have a discreet pinpointable forward
brake 3 or braking elbow 2, so long as rotation of brake 12 causes
points to mure between the first wall and the second wall. By
operation of this muring, the rotation of brake 12 is arrested; in
turn, as will now be evident, the rotation of the entire locking
segment 1 is arrested (except, perhaps, for deformation that may
occur to the locking segment 1 or to first wall 43 or second wall
41). As the rotation of locking segment 1 cannot continue, the
radial pressures exerted by toe 13 on spigot 70 will not increase,
despite an increase in axial thrust pressures. Contrast is drawn to
the continuing increase in radial pressure that would be expected
in the absence of a rotational braking mechanism. The invention may
be used to cause the plateau for this pressure line, if graphed, to
occur below a pressure at which spigot 70 is deemed likely to
fail.
[0035] As described, by means of the rotational braking, the
radially inward pressures exerted on spigot 70 may be capped. In
fact, the muring mechanism taught herein will cause a segment 1 to
cease rotation at its maximum desired rotational point even in the
absence of a spigot. Mathematically, despite the capping of radial
pressures by muring, the forces in the system must remain net zero.
In effect, the inventors believe (without wishing to be limited to
theory) that the cantilever effect of the muring multiplies the
axial forces applied by the locking segment 1 to the first wall 43
to offset the forces not transferred into radial pressures on the
spigot 70, though it is recognized that the system is sufficiently
dynamic with multiple variables that this mechanism may not always
or purely be in play.
[0036] In the shown embodiment, the profile of the brake 12 is
complimentary to the internal profile of the annular trough 47.
Those skilled in the art will understand by reference to the claims
and the preceding discussion that the profiles need not match
precisely, nor even nearly, so long as the brake 12 is fitted
within annular trough 47 in such a manner as to mure between first
wall 43 and second wall 41 upon reaching a maximum rotation.
Furthermore, those in the art will understand that while the first
wall 43 and the second wall 41 are discussed herein as if they were
discrete walls of the annular trough 47, the walls may be staggered
or may have varying radial separations. By way of example, FIG. 1
shows first wall 43 as coincident with the inner face of bell lip
44. As further shown in this figure, braking elbow 2 actually would
cantilever into a portion of the first wall 43 that is more
radially inwardly extended than any existing point on second wall
41. It is possible that a bell configuration may have a radially
extending wall offset from the annular trough 47. In such cases,
the offset radial wall will be considered an extension of the first
wall 43, even though it is offset from first wall 43 axially.
[0037] It should be noted that in the shown embodiment, the axis of
rotation of the locking segment during insertion is located in or
about insertion fulcrum 46, while the rotational axis occurs at a
different point during extraction. More particularly, the inventors
believe that the axis of rotation during extraction is a "floating"
axis that is located in the brake 12 itself. This floating
characteristic of the axis allows the locking segment to seek its
own orientation for locking spigots and bells of varying tolerances
(e.g., situations in which the annular gap 60 varies between one
joint and the next). It is possible that in some installations,
outer corner 4 may never contact any portion of annular trough 47.
Alternatively, in tighter installations (e.g., those having a
narrower annular gap 60), the outer comer 4 may contact trough
terminus 42 and may even act as a cam in some respects. In normal
operation, the shown embodiment does not take advantage of or
exhibit any cam-type action outside of the annular trough. Further,
the locking segment 1 of the current invention does not require any
bell surfaces forward of the brake 12 that exert any radially
inward pressures or that resist axially outward movement of the
locking segment 1.
Concluding Remarks
[0038] The foregoing represents certain exemplary embodiments of
the invention selected to teach the principles and practice of the
invention generally to those in the art such that they may use
their standard skill in the art to make these embodiments or
variations based on industry skill, while remaining within the
scope and practice of the invention, as well as the inventive
teaching of this disclosure. The inventor stresses that the
invention has numerous particular embodiments, the scope of which
shall not be restricted further than the claims as allowed. Unless
otherwise specifically stated, Applicant does not by consistent use
of any term in the detail description in connection with an
illustrative embodiment intend to limit the meaning of that term to
a particular meaning more narrow than that understood for the term
generally.
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