U.S. patent application number 13/863476 was filed with the patent office on 2013-09-12 for crimped or swaged couplings for cable reinforced hoses.
This patent application is currently assigned to The Gates Corporation. The applicant listed for this patent is THE GATES CORPORATION. Invention is credited to Lance D. Miller, Jonathan Clark Swift, Ron Trujillo.
Application Number | 20130232767 13/863476 |
Document ID | / |
Family ID | 44351489 |
Filed Date | 2013-09-12 |
United States Patent
Application |
20130232767 |
Kind Code |
A1 |
Trujillo; Ron ; et
al. |
September 12, 2013 |
CRIMPED OR SWAGED COUPLINGS FOR CABLE REINFORCED HOSES
Abstract
A hose coupling for fitment to an end of a cable reinforced hose
includes a unitary stem having a cable trap groove portion having
an outside diameter greater than an inside diameter of a tube of
the hose and less than an inside diameter of the hose with the tube
skived from the hose. A unitary ferrule defines at least one cable
trap rib corresponding to the cable trap groove and having an
inside diameter less than the outside diameter of the cable
reinforced hose and greater than an outside diameter of the hose
with material covering the cable skived from the hose. The groove
width is at least the width of the rib plus twice the diameter of
cable reinforcing the hose. Epoxy may be disposed between the hose
tube and the stem for sealing or injected between the ferrule and
the stem permeating the cable.
Inventors: |
Trujillo; Ron; (Highlands
Ranch, CO) ; Swift; Jonathan Clark; (Cambridge,
GB) ; Miller; Lance D.; (Highlands Ranch,
CO) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
THE GATES CORPORATION |
Denver |
CO |
US |
|
|
Assignee: |
The Gates Corporation
Denver
CO
|
Family ID: |
44351489 |
Appl. No.: |
13/863476 |
Filed: |
April 16, 2013 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
12803096 |
Jun 18, 2010 |
8439405 |
|
|
13863476 |
|
|
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Current U.S.
Class: |
29/505 |
Current CPC
Class: |
F16L 33/01 20130101;
F16L 33/2073 20130101; Y10T 29/49908 20150115; F16L 33/00
20130101 |
Class at
Publication: |
29/505 |
International
Class: |
F16L 33/00 20060101
F16L033/00 |
Claims
1. A method comprising: skiving layers of a cable reinforced hose
covering the cable reinforcement from an end portion of said cable
reinforced hose; skiving a tube from inside a distal portion of
said end portion of said cable reinforced hose; disposing a unitary
stem having an inner bore, a termination portion for attaching to a
fixture, a cable trap groove portion and an insert portion, with
said insert portion inserted inside said tube of said cable
reinforced hose and with said cable trap groove inserted inside
said distal portion of said end portion of said hose; disposing a
unitary ferrule having a plurality of ridges inter-indexing with
lands defined on an outside of said insert and with at least one
cable trap rib corresponding to the cable trap groove over said end
portion of said hose; and compressing said ferrule resulting in
said ridges compressing said hose to seal said tube in said lands
and said rib forcing said cable into said groove.
2. The method of claim 1, wherein said compressing distorts a
plurality of cables reinforcing said hose between said cable trap
rib and said cable trap groove.
3. The method of claim 1 wherein said coupling further comprises a
weephole connecting the space occupied by the hose between said
ferrule and said stem to the outside.
4. The method of claim 1, wherein said compressing is swaging.
5. The method of claim 1, wherein said compressing is crimping.
6. The method of claim 1, further comprising welding said ferrule
to said stem, prior to said disposing steps.
7. The method of claim 6, wherein said welding comprises welding
said ferrule on said stem with said termination portion of said
stem extending from said ferrule and said cable trap groove and
said insert of said stem disposed in said ferrule.
8. The method of claim 1, further comprising disposing epoxy
between said tube and said stem, prior to said compressing wherein
said compressing causes said epoxy to seal the tube of the hose
against the stem.
9. The method of claim 1, further comprising injecting low
viscosity epoxy through a weephole to in between said ferrule and
said stem, following said compressing.
10. The method of claim 1, wherein said hose is a blow out
preventer hose.
11. Method of claim 2 wherein said weephole passes through a
circular plate securing said ferrule to said stem.
12. A method comprising: skiving layers of a cable reinforced hose
covering the cable reinforcement from an end portion of said cable
reinforced hose; skiving a tube from inside a distal portion of
said end portion of said cable reinforced hose; disposing a unitary
stem having an inner bore, a termination portion for attaching to a
fixture, a cable trap groove portion and an insert portion, with
said insert portion inserted inside said tube of said cable
reinforced hose and with said cable trap groove inserted inside
said distal portion of said end portion of said hose; disposing a
unitary ferrule having a plurality of ridges inter-indexing with
lands defined on an outside of said insert and with at least one
cable trap rib corresponding to the cable trap groove over said end
portion of said hose; and compressing said ferrule resulting in
said ridges compressing said hose to seal said tube in said lands
and in said rib forcing said cable into said groove and in
distorting a plurality of cables reinforcing said hose between said
cable trap rib and said cable trap groove; wherein said coupling
further comprises a weephole connecting the space occupied by the
hose between said ferrule and said stem to the outside.
13. Method of claim 12 wherein said weephole passes through a
circular plate securing said ferrule to said stem.
14. The method of claim 13, further comprising injecting low
viscosity epoxy through said weephole to in between said ferrule
and said stem, following said compressing.
Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of the Invention
[0002] This invention relates generally to reinforced hose, more
particularly to crimped or swaged couplings for reinforced hose,
and specifically to crimped or swaged couplings for cable or wire
rope reinforced hoses.
[0003] 2. Description of the Prior Art
[0004] Typically, blow out preventers (BOPS) are used when oil or
gas wells are drilled. Blowout preventers are hydraulically
controlled valves used to control well kicks and prevent blowouts.
A single well may have three or more preventers, stacked one on top
of the other. On a land rig, the stack is located beneath the rig
floor at ground level. On an offshore rig the BOP may be located on
the seafloor. The top preventer on a stack is usually an annular
preventer. The annular preventer may be used to completely seal off
the drill well annulus (the space between the drill pipe and the
borehole). It also can seal off a drill hole that has no pipe.
Below the annular preventer are additional controls called ram
preventers. The ram preventers are designed to fit around various
sizes of drill pipe to hold, close or seal the mud return annulus.
Blind rams are used to seal off an open hole. Pipe rams can seal
off the drill pipe and the hole.
[0005] Rock formations may contain pockets of oil, gas or water
under extremely high pressures. A drilled hole may intersect any of
these. When any of these high-pressure fluids enter the hole it is
referred to as a "kick." When a well kicks, there are several
options for handling the kick. The resulting downhole pressure can
be cycled out through the BOP system's manifolds at the surface.
Alternatively, an attempt can be made to force the downhole fluid
back into the formation, such as by pumping drilling fluid under
high pressure into the hole through a choke and kill line. Choke
and kill hose is used for this purpose. A final option is to pump
in cement, seal off the hole and abandon the drilling
operation.
[0006] Flexible reinforced pipes and hoses are currently used in
Choke and Kill applications on oil rigs. These hoses/pipes and
couplings are designed to act as a conduit for the pumping of mud
(drilling waste) back down into a well head to block the well head
fluid against oil, methane gas and noxious chemicals such as
Hydrogen Sulphide, at extreme temperatures and pressures. These
hoses typically comprise a rubber polymeric tube and are reinforced
using multiple layers of "close wound", high tensile plated steel
cables (or wire rope) to withstand flexing and high pressures
encountered in oil field and offshore operations. This cable
reinforcement is typically wire stranded rope, which is typically
interchangeably referred to as "cable" and/or "wire rope." These
hoses also typically include multiple layers of fabric
reinforcement disposed under the hose cover, which may be a
modified nitrile resistant to abrasion, corrosion, cutting,
gouging, oil and weather.
[0007] Prior crimped or swaged couplings 100 for choke and kill
hose applications typically employ ridged ferrule 101 and barbed
stem fitting 102, such as shown in prior art FIG. 1. This ferrule
and stem are typically welded together (103), leaving an opening,
which accepts hose 105. Baldwin, et al., U.S. Pat. No. 7,338,090,
employs a "waved" ferrule and stem that joins an end connector to
the coke and kill hose. This ferrule and stem are also welded
together at the coupling end, leaving an opening, which accepts the
reinforced hose. However, in Baldwin, et al., the lands of the
ferrule and high points of the stem have a sinusoidal shape,
providing the aforementioned "wave." This wave bends the cable/wire
rope reinforcement in the hose but does not significantly distort
the cables. The stem is designed to support the hose which is
inserted over it and under the ferrule. The ferrule is swaged or
crimped down onto the hose to provide compressive forces, sealing
the hose against the stem and retaining the hose in the coupling.
For use with this sort of coupling the cover of the hose is skived
(i.e. stripped away) so that the ferrule is able to press down on
the cable reinforcement, directly, without the need to penetrate
the rubber cover. Still, in designs like Baldwin coupling retention
is dependent upon the properties of the rubber to provide a
reaction force to compression preventing the cable reinforced hose
slipping out of the couplings, such designs may lose their
capability at elevated or reduced temperatures where the properties
of the rubber layers change and may provide less support.
[0008] Other approaches to retaining a fitting on a cable
reinforced hose call for unraveling reinforcement cable extending
from an end of the hose and welding individual elements (cables) to
a coupling. Problematically, such approaches are time consuming,
expensive and require qualified welders.
[0009] API (American Petroleum Institute) 16 C standards testing
includes testing such as a thirty-day exposure test at 20,000 psi
working pressure, at elevated temperature, for choke and kill hose
assemblies. When choke and kill hose assemblies employing the
above-described couplings are exposed to theses conditions it was
found that the hose-coupling interface is susceptible to
temperature extremes. The properties of the rubber material change
at elevated temperature and as a result the rubber can flow and
allow the compressive forces in the coupling ferrule to drop. This
can result in loss of coupling retention which is not acceptable in
choke and kill, or similar, applications.
SUMMARY
[0010] The present invention is directed to systems and methods of
crimped or swaged couplings for cable or wire rope reinforced hoses
where rubber material properties are taken out of the coupling
retention mechanism. In order to achieve this, a short length of
the internal tube and external cover of the hose is skived. The
result of this short length of skiving is that the wire/cable
reinforcement can be gripped alone without a need to compress and
penetrate the tube or cover. With a relatively short length of
cable exposed, a stem and ferrule of the present invention, which
forms a reinforcement cable (or wire rope) trap, can be swaged or
crimped onto the hose end, gripping the hose without reliance upon
rubber properties. In particular, the cable reinforcement is
preferably trapped directly between the stem and the ferrule.
Specifically, the cable is retained between a raised portion of the
stem which incorporates a depression and a serration in the
ferrule. Unlike prior approaches, rather than merely bending the
cable, maintaining its integrity, the short length of skived cable
is squeezed between stem and ferrule in the present systems and
methods. This results in distortion of the cable, providing a
mechanical lock between the coupling and the hose. Additional
retention may be achieved by using a more aggressive ferrule design
where the ferrule is forced to flow around the cable when the
connection is swaged or crimped.
[0011] In accordance with various embodiments of the present
invention a hose coupling for fitment to an end of a cable
reinforced hose, such as a blowout preventer choke and kill hose,
might include a unitary stem and a unitary ferrule, which may be
welded, staked or otherwise secured together. Various embodiments
of the stem have an inner bore and a termination portion for
attaching the coupling and hose on which it is swaged or crimped,
such as by welding to a flange, or the like. The stem preferably
defines a cable trap groove, which may have a generally
trapezoidal, or other polygonal, shape. The root of this groove
preferably has an outside diameter that is greater than an inside
diameter of a tube of the hose. The outside diameter of the groove
root is also preferably less than an inside diameter of the hose
with the tube skived from the hose, that is less than the inside
diameter of the cable reinforcement layer of the hose. An insert
portion of the stem is adapted for insertion into the tube of the
hose. The insert preferably defines a plurality of external lands
and has an outside diameter generally corresponding to an inside
diameter of the tube of the hose.
[0012] The unitary ferrule has an outer surface and a first and
second inside diameter. The first inside diameter of an unstaked or
uncrimped ferrule, is preferably greater than an outside diameter
of the wire stranded cable reinforced hose. The second inside
diameter of the unstaked, uncrimped or unswaged ferrule may be less
than the outside diameter of the cable reinforced hose, but greater
than an outside diameter of the hose with material covering the
cable skived from the hose, that is greater than the outside
diameter of the cable reinforcing layer of the hose. An inner
surface portion of the ferrule has a portion that has the first
diameter. This portion defines a plurality of ridges, positioned to
inter-index with the lands of the stem. Another portion of the
inner surface of the ferrule defines at least one generally cable
trap rib, shaped and positioned to correspond to the cable trap
groove in the stem. This cable trap rib has the second inside
diameter and is narrower than the groove. Preferably, the groove
has a width that is at least the width of the rib plus twice the
diameter of a cable reinforcing the hose and the width of the rib
is greater than a diameter of a cable reinforcing the hose, such as
on the order of multiple diameters of the cable reinforcing the
hose. When the ferrule is secured to the stem, such as by welding
or staking the termination portion of the stem preferably extends
from the ferrule and the cable trap groove and the insert of the
stem are disposed in the ferrule.
[0013] In accordance with the present invention prior to
disposition of the ferrule of the coupling over an end of the hose,
the outside layers of the hose covering the cable reinforcement
portion is skived from a distal extent of the end of the hose. The
stem is disposed with the insert inserted inside the tube of the
hose and the cable trap groove is inserted inside the distal extent
of the hose with the tube skived away from the distal extent of the
hose.
[0014] Accordingly, various embodiments of methods for securing a
fitting to the end of a cable reinforced hose, such as a blowout
preventer choke and kill hose, in accordance with the present
invention calls for skiving layers of the hose covering the cable
reinforcement from a distal end portion of the end of the hose and
skiving a tube from inside the distal end portion of the hose. The
unitary stem having an inner bore, a termination for attaching to a
fixture, a cable trap groove and an insert portion is inserted into
the skived hose with the insert portion inserted inside the tube of
the cable reinforced hose and with the cable trap groove inserted
inside the skived distal end portion of the hose. The unitary
ferrule is preferably deployed over the end of the hose and the
stem with the ridges inter-indexing with lands defined on an
outside of the insert and with at least the cable trap rib
corresponding to the cable trap groove. Such deployment of the
ferrule and the stem may occur generally simultaneously if the
ferrule is welded to the stem, prior to disposition. Regardless,
following disposition of the ferrule and the stem the ferule is
compressed, such as by swaging or crimping, resulting in the ridges
compressing the hose to seal the tube in the lands and the rib
forcing the cable into the groove, trapping the cable reinforcement
in the skived area and thereby securing the coupling to the hose in
a manner that does not depend on gripping rubber or polymeric
material.
[0015] Thus, in accordance with various embodiments of the present
invention a hose assembly, such as a blowout preventer choke and
kill hose assembly, may be made up from a length of hose having an
inner tube, one or more layers of cable reinforcement and one or
more layers of rubber covering the reinforcement, wherein the inner
tube and the one or more layers of rubber covering are skived from
an end portion of the hose. A coupling, such as discussed above, is
preferably swaged or crimped on the end portion and a further
length of the hose. In accordance with such embodiments, the
coupling comprises a unitary ferrule disposed over the end portion
of the hose and the further length of the hose. The ferrule has a
first inside diameter greater than an outside diameter of the hose
and a second inside diameter that may be less than the outside
diameter of the hose, but is greater than an outside diameter of
the end portion of the hose with the rubber covering skived from
the hose. The ferrule defines an inner surface having a plurality
of ridges having the first diameter and disposed over the further
length of the hose. The ferrule inner surface also preferably
defines at least one cable trap rib having the second inside
diameter and disposed over the skived end portion of the hose. The
coupling also, as discussed above has a unitary stem, which may be
secured to or unitary with the ferrule. The stem is preferably
disposed in the end portion of the hose and on into the further,
unskived length of the hose. The stem comprises a termination
portion for attaching to a fixture (such as a flange, or the like)
a cable trap groove, and an insert defining a plurality of lands
inter-indexing with the ferrule ridges. The insert has an outside
diameter generally corresponding to an inside diameter of the tube
of the hose and is inserted into the further portion of the hose
from which the tube has not been skived. The cable trap groove
corresponds to the cable trap rib and is preferably disposed under
the end portion. The groove has a diameter greater than an inside
diameter of a tube of the hose, but less than an inside diameter of
the hose with the tube skived from the hose. Also, the groove
preferably has a width that is at least the width of the rib, plus
twice the diameter of cable reinforcing the hose.
[0016] In accordance with various embodiments, epoxy may be
disposed between the tube and the stem, prior to compression of the
ferrule, to aid in sealing the tube of the hose against the stem
following compression of the ferrule. Alternatively, or
additionally, low viscosity epoxy may be injected into the fitting,
such as through a weephole, to in between the ferrule and the
cable, after compression.
[0017] Advantageously, the present invention provides better
coupling retention, resistance to extreme temperatures and
separation of retention from sealing because rubber material
properties are taken out of the coupling retention mechanism.
Further, in contrast to prior systems, since the diameter of the
reinforcing wire rope may slightly expand at elevated temperatures,
the cable trap provided by the rib and groove described above
bearing directly on the bare cable as a result of skiving of both
the cover and the tube preferably tightens.
[0018] The foregoing has outlined rather broadly the features and
technical advantages of the present invention in order that the
detailed description of the invention that follows may be better
understood. Additional features and advantages of the invention
will be described hereinafter which form the subject of the claims
of the invention. It should be appreciated by those skilled in the
art that the conception and specific embodiment disclosed may be
readily utilized as a basis for modifying or designing other
structures for carrying out the same purposes of the present
invention. It should also be realized by those skilled in the art
that such equivalent constructions do not depart from the scope of
the invention as set forth in the appended claims. The novel
features which are believed to be characteristic of the invention,
both as to its organization and method of operation, together with
further objects and advantages will be better understood from the
following description when considered in connection with the
accompanying figures. It is to be expressly understood, however,
that each of the figures is provided for the purpose of
illustration and description only and is not intended as a
definition of the limits of the present invention.
BRIEF DESCRIPTION OF THE DRAWINGS
[0019] The accompanying drawings, which are incorporated in and
form part of the specification in which like numerals designate
like parts, illustrate embodiments of the present invention and
together with the description, serve to explain the principles of
the invention. In the drawings:
[0020] FIG. 1 is a fragmented, generally sectional view of a
crimped or swaged prior art coupling installed on a cable
reinforced hose ;
[0021] FIG. 2 is a fragmented, generally quarter sectional view of
an embodiment of a coupling of the present invention;
[0022] FIG. 3 is a fragmented, generally quarter sectional view of
the embodiment of the coupling of FIG. 2 deployed, uncompressed, on
a cable reinforced hose;
[0023] FIG. 4 is a fragmented, generally quarter sectional view of
the embodiment of the coupling of FIGS. 2 and 3 installed,
compressed, on a cable reinforced hose shown in FIG. 3; and
[0024] FIG. 5 is an enlarged, fragmented, generally sectional view
of the embodiment of a coupling of FIGS. 2-4 shown installed,
compressed, on the hose as shown in FIG. 4.
DETAILED DESCRIPTION
[0025] As noted, FIG. 2 is a quarter sectional view of an
embodiment of coupling 200 of the present invention. In FIG. 3
coupling 200 is deployed, uncompressed, on cable reinforced hose
305, which may be a blowout preventer choke and kill hose, or the
like. Hose coupling embodiment 200 includes unitary stem 202 and
unitary ferrule 201, which may be welded (203), staked or otherwise
secured together, such as through the use of circular plate 204, or
similar mechanism.
[0026] Various embodiments of stem 202 may have inner bore 210 and
termination structure portion 212 for attaching coupling 200 and
hose 305 on which it is swaged or crimped to a fixture, such as a
flange, or the like. Termination structure 212 may take the form of
a bud, or the like, that may be welded to a flange or the like for
fitment using a hammer union, or the like. Stem 202 preferably
defines cable trap groove 215, which is illustrated in FIGS. 2
through 5 as generally trapezoidal in shape. However, such cable
trap grooves may, in accordance with the present invention, be of a
number of different shapes, such as, generally rounded,
chevron-shaped, generally rectangular, etc. Root 216 of groove 215
preferably has a diameter that is greater than an inside diameter
of inner tube 317 of hose 305. The diameter of groove root 216 is
also preferably less than an inside diameter of the hose with inner
tube 317 skived from the hose, that is less than the inside
diameter of cable reinforcement layer 320 of hose 305, as may best
be seen in FIG. 3. An insert portion 225 of the stem is adapted for
insertion into inner tube 317 of hose 305. Insert portion 225
preferably defines a plurality of external lands 227 and has an
outside diameter generally corresponding to an inside diameter of
inner tube 317 of the hose 305. When ferrule 201 is secured to stem
202, such as by welding or staking as discussed above, termination
portion 212 of stem 202 preferably extends from ferrule 201 and
cable trap groove 215 and insert 225 of stem 202 are disposed in
ferrule 201.
[0027] Unitary ferrule 201 has an outer surface 230 and an inside
having a number of diameters defining a number of features, but
primarily a first and second inside diameters, defining a plurality
of ridges 232 and a cable trap rib 236. The first inside diameter
of unstaked or uncrimped ferrule 201, such as shown in FIGS. 2 and
3 is preferably greater than an outside diameter of wire stranded
cable reinforced hose 305, as best seen in FIG. 3. The second
inside diameter of unstaked or uncrimped ferrule 201 may be less
than the outside diameter of cable reinforced hose 305, but is
preferably greater than an outside diameter of hose 305 with
material covering cable reinforcement 320, such as cover 333,
skived from the hose. In other words the second inside diameter of
the ferrule is preferably greater than the outside diameter of
cable reinforcing layer 320 of hose 305, but may be less than the
outside diameter of the hose overall. Preferably, ridges 232 are
positioned to generally inter-index with lands 227 of stem 202.
Another portion of the inner surface of the ferrule defines at
least one cable trap rib 236, positioned to correspond to cable
trap groove 215 in stem 202. Cable trap rib 236 has the second
aforementioned inside diameter and is preferably narrower than
groove 215. Preferably, groove 215 has a width that is at least the
width of rib 236 plus at least, or about, twice the diameter of a
cable reinforcing hose 305. Also, preferably, the width of rib 236
is greater than the diameter of a cable reinforcing hose 305, such
as on the order of multiple diameters of the cable reinforcing hose
305.
[0028] The embodiment illustrated in FIGS. 2 through 5 has a single
cable trap groove, 215 and a single rib, 216. However, any number
of cable traps can be employed on a coupling in accordance with the
present invention. For example, a plurality of cable trap ribs may
be employed in conjunction with a corresponding number of cable
trap grooves.
[0029] In accordance with various embodiments for securing a
fitting, such as fitting 200, to the end of a cable reinforced
hose, such as hose 305, which may be a blowout preventer choke and
kill hose, or the like, layer(s) 333 of hose 305 covering cable
reinforcement 320 are skived from an end portion of hose 305 and
inner tube 317 is skived from an inside distal extent of the end
portion of hose 305. Generally, this distal extent from which the
tube is skived is only a portion of the end of the hose from which
the cover is skived. Unitary stem 202, having inner bore 210,
termination 212 for attaching to a fixture, cable trap groove 215
and insert portion 225, is inserted into the skived hose. Insert
portion 225 is inserted inside (unskived) inner tube 317 of cable
reinforced hose 305, with cable trap groove 215 inserted inside the
skived distal extent of hose 305. Unitary ferrule 201 is preferably
deployed over the end of the hose 305 and stem 202, with ridges 232
of ferrule 201 inter-indexing with lands 227 defined on an outside
of insert 225 and with cable trap rib 236 corresponding with, that
is generally aligning with, cable trap groove 215. Such deployment
of ferrule 201 and stem 202 may occur generally simultaneously if
ferrule 201 is welded to stem 202 prior to disposition. Following
disposition of ferrule 201 and stem 202, ferule 201 is compressed,
such as by swaging or crimping, resulting in ridges 232 compressing
the end of hose 305 to seal hose inner tube 317 against lands 227
and resulting in rib 236 forcing cable reinforcement 320 into
groove 215. Preferably, this traps cable reinforcement in the
double-skived area between rib 236 and groove 215. Also, in
accordance with various embodiments, at least some of the
individual cables making up cable reinforcement 320 are deformed by
the compression of the cable trap rib, particularly compression of
the cable trap rib, with respect to the uncompressed cable trap
groove. This deformation of individual cables is best seen in
enlarged FIG. 5. Entrapment of the cable by the compressed cable
trap, comprised of rib 236 and groove 215, secures coupling 200 to
hose 305 in a manner that does not depend on gripping rubber or
polymeric material, such as cover 333 and/or inner tube 317.
[0030] Thus, in accordance with various embodiments of the present
invention, a resulting hose assembly 400 (FIGS. 4 and 5) may be
made up from a length of hose 305 having inner tube 317 and rubber
covering 333 skived out of and off of end portions of hose 305 and
coupling 200, such as discussed above swaged or crimped on the end
of hose 305.
[0031] In accordance with some embodiments, epoxy (not shown in
Figures for sake of clarity) may be disposed between tube 227 and
stem 202, prior to compression of ferrule 201 to enhance sealing,
and/or injected after compression of ferrule 201 to permeate cable
reinforcement 320 with the epoxy in the areas where cover 333
and/or inner tube 317 is skived away to provide improved bonding of
hose 305 and coupling 100.
[0032] For example, in some embodiments, a high temperature epoxy,
such as epoxy 4525 from Cotronics Corporation, may be applied to
stem 202 prior to insertion in hose 305. Since the epoxy is in two
parts, the epoxy resin and the amine hardener cure in place
regardless of the environment, i.e. oxygen, humidity, heat, etc.
The epoxy may be placed on two lands 227 of insert 202, near the
end of stem to prevent excess epoxy from entering into the stem or
hose tube. Compression of ferrule 201 distributes the epoxy. In
particular swaging advantageously moves the adhesive further into
tube 227, along stem 202. Adding heat may facilitate set-up of the
epoxy making the hose useable in a relatively short time frame.
[0033] In accordance with other embodiments, a high viscosity
epoxy, such as epoxy 4461 from Cotronics Corporation, may be
injected through weephole 235 to penetrate the interstices of the
cables as well as any additional areas between the cable and stem
202. By filling the coupling and thus gaining access into very
small cavities the epoxy will have increased contact surface area,
and thus, increased bond strength, as well as enhanced sealing
functionality. Advantageously, such low viscosity epoxy may be
injected through weephole 235 after compression of ferrule 201, or
before.
[0034] Although the present invention and its advantages have been
described in detail, it should be understood that various changes,
substitutions and alterations can be made herein without departing
from the scope of the invention as defined by the appended claims.
Moreover, the scope of the present application is not intended to
be limited to the particular embodiments of the process, machine,
manufacture, composition of matter, means, methods and steps
described in the specification. As one of ordinary skill in the art
will readily appreciate from the disclosure of the present
invention, processes, machines, manufacture, compositions of
matter, means, methods, or steps, presently existing or later to be
developed that perform substantially the same function or achieve
substantially the same result as the corresponding embodiments
described herein may be utilized according to the present
invention. Accordingly, the appended claims are intended to include
within their scope such processes, machines, manufacture,
compositions of matter, means, methods, or steps.
* * * * *