NZ725198B2 - Flexible electrical isolation device - Google Patents
Flexible electrical isolation device Download PDFInfo
- Publication number
- NZ725198B2 NZ725198B2 NZ725198A NZ72519815A NZ725198B2 NZ 725198 B2 NZ725198 B2 NZ 725198B2 NZ 725198 A NZ725198 A NZ 725198A NZ 72519815 A NZ72519815 A NZ 72519815A NZ 725198 B2 NZ725198 B2 NZ 725198B2
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- New Zealand
- Prior art keywords
- tube
- membrane
- dielectric member
- dielectric
- coupling members
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- 238000002955 isolation Methods 0.000 title description 32
- 230000008878 coupling Effects 0.000 claims abstract description 68
- 238000010168 coupling process Methods 0.000 claims abstract description 68
- 238000005859 coupling reaction Methods 0.000 claims abstract description 68
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- 229920003235 aromatic polyamide Polymers 0.000 claims description 4
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Abstract
electrical isolator includes a flexible non-electrically conductive membrane and an inelastic flexible dielectric member journalled in the membrane and extending from the first end of the membrane to the second end of the membrane. First and second coupling members are anchored to the ends of the dielectric member. The ends of the membrane are mated in sealed engagement with the coupling members so that the coupling members fluidically seal the ends of the membrane and fluidically seal the dielectric member within the membrane. The membrane is filled with a dielectric fluid so as to displace any air in the membrane and the dielectric member. The coupling members are adapted to couple to objects at opposite ends of the electrical isolator. The arrangement prevents contamination of the member by airborne particles, high humidity, or precipitation which would render the member conductive dielectric member. The ends of the membrane are mated in sealed engagement with the coupling members so that the coupling members fluidically seal the ends of the membrane and fluidically seal the dielectric member within the membrane. The membrane is filled with a dielectric fluid so as to displace any air in the membrane and the dielectric member. The coupling members are adapted to couple to objects at opposite ends of the electrical isolator. The arrangement prevents contamination of the member by airborne particles, high humidity, or precipitation which would render the member conductive
Description
FLEXIBLE ELECTRICAL ISOLATION DEVICE
TECHNICAL FIELD:
This disclosure generally relates to a flexible electrical isolation device,
one example of which is for use in replacing energized power lines or in stringing
replacement optical ground wire or static wire above energized power lines.
BACKGROUND:
There are many examples, some of which are provided herein, where
the applicant believes it to be beneficial to provide a tensile load bearing, electrically
insulating, flexible isolation member which is weather resistant and which
advantageously may also provide for rotation in the form of swivelling or other
relative motion along the length of the flexible member so as to relieve torsional
loads and/or shearing loads. One example, already mentioned, is for use in
replacing, or what applicant refers to as reconductoring or restringing of power line
conductors or static wires respectively. Other examples may include the use of the
flexible isolation member in a sling line under a helicopter, for example when used to
suspend a lineman from the helicopter for power line maintenance work.
As will be commonly known, overhead power lines use one or more
phases of conductors to transmit electricity within a transmission grid. The overhead
power lines may be used for bulk transmission from a power plant to centers of high
demand and for distribution within the centers of high demand. The conductors are
often supported above the ground by support structures. Over time the energized
transmission lines, referred to herein as energized conductors, may be exposed to
harsh weather conditions, or become overloaded. Deteriorated or overloaded
conductors must be replaced in that general process previously referred to as
reconductoring. Static wires may be strung above the conductors to shield the
energized conductors from lightning strikes. Occasionally the static wires, which
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may be conventional static wires or otherwise may be referred to as overhead
ground wire, shield wire, earth wire, etc., or which may be optical ground wire
(OPGW), collectively referred to herein as static wire, must also be replaced in a
process referred to as restringing. During the reconductoring or restringing process
it is often advantageous to use pulling wire instead of pulling rope which may melt,
break or otherwise fail if moist or dirty when exposed to a high voltage environment.
A high voltage environment occurs when pulling conductors or static wire because
each may be subjected to a significant induced voltage due to proximity to one or
more high voltage energized conductors, for example carrying 69kV or more. Thus it
is useful to use a pulling wire instead of a pulling rope. The use of pulling wire
necessitates the use of a flexible electrically isolating link between the pulling wire
and the conductor or static wire that is to be replaced.
SUMMARY:
[0004] The present invention thus includes or comprises, as those terms are
used interchangeably herein, a flexible, insulated, isolation link, member or device,
again as those terms are used interchangeably herein, to separate and electrically
isolate, in one example the old, to-be-replaced, existing conductor or static wire from
the pulling wire or wire rope, so as to eliminate the circulating current between the
old conductor or static wire and the wire rope.
The present disclosure may be summarized, in one aspect, as an
electrical isolator which includes:
a. a flexible non-electrically conductive membrane, such as a tube, having
first and second opposite ends;
b. an inelastic flexible dielectric member having first and second opposite
ends, the dielectric member journalled in the membrane and extending
from the first end of the membrane to said second end of said membrane;
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c. first and second coupling members anchored, respectively, to the first and
second ends of the dielectric member, the first and second ends of the
membrane mated in sealed engagement with the first and second coupling
members so that the first and second coupling members fluidically seal,
that is, provide a fluid tight or leak-proof seal around the first and second
ends of the membrane and fluidically seal, that is, provide a fluid tight or
leak-proof seal sealing the dielectric member within the membrane;
d. the membrane filled with a dielectric fluid so as to displace any air in the
membrane and the dielectric member;
e. the first and second coupling members adapted to couple to objects at
opposite ends of the electrical isolator.
In one example, the first and second coupling members includes an
anchor element and wherein one anchor element is inserted into each of the first and
second ends of the dielectric member so as to anchor therein the coupling members.
[0007] The anchor elements may include at least one spelter. Each a
coupling member may include at least one female spelter coupling mated with a
spelter.
The anchor element may include an elongate shaft member which is
inserted into and aligned along the length of a corresponding end of the dielectric
member when the coupling members are mounted to the ends of the dielectric
member.
The at least one spelter may include first and second spelters joined
end-to-end, or mounted on a shaft member extending between the spelters, or
otherwise located near or adjacent to one another when mounted in the ends of the
dielectric member.
In the embodiment where the spelters are mounted on a shaft member,
the shaft member has opposite first and second ends, and the first spelter is
mounted on the first end. The female spelter coupling mates onto the first spelter.
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The shaft member is inserted into the corresponding end of the dielectric member so
that the second end of the shaft member is inserted first into the end of the dielectric
member and so that the first end of the shaft member is, once inserted into the
dielectric member, adjacent a terminal end face of the corresponding end of the
dielectric member so that the corresponding end of the dielectric member is
sandwiched between the first spelter and the female spelter coupling to clamp the
corresponding end of the dielectric therebetween. The second spelter may be
mounted or formed on the second end of the shaft member.
The female spelter coupling may include a female mating collar
extending therefrom. The collar is sized to snugly fit around the membrane. The
collar may be positioned relative to the second spelter when the first spelter is the
mated in the female spelter coupling so that the female mating collar surrounds the
second spelter, wherein the dielectric member is sandwiched between the second
spelter and the female mating collar and a seal is formed between the membrane
and the female mating collar.
The dielectric member may advantageously be a dielectric synthetic
rope, for example, made from strands chosen from the group comprising: aramid,
polyester, polyethylene, nylon ™, to name examples which are not intended to be
limiting, or hybrids thereof, collectively referred to herein as synthetic rope.
[0013] The female spelter coupling has a cavity. The first spelter mates within
the cavity. The cavity may be filled with a fluid-to-solid setting compound so as to fix
the first spelter within the cavity. The setting compound may be a two part resin.
The membrane may be at least partly translucent so that the condition
of the fluid therein may be inspected from the exterior of the membrane. The
membrane may be a reinforced tube. The fluid may be oil, for example having a
viscosity of substantially 0.5 centi-stokes.
A pressure equalizing tube may be nested within the membrane or
tube and extending substantially from the first end to the second end of the
membrane or tube so as to provide fluid communication of the fluid between the first
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and second ends of the membrane or tube. The dielectric member may have a core.
The pressure equalizing tube may run along the core. The dielectric member may
advantageously substantially fill the membrane or tube.
The electrical isolator may be an isolation link electrically isolating
power line conductor or static wire from a pulling line. A method is provided that
couples the isolator between the conductor or static wire and the pulling line. The
method and apparatus also applies to other applications such as helicopter sling
lines, etc.
BRIEF DESCRIPTION OF DRAWINGS:
Various examples of the apparatus are described in detail below, with
reference to the accompanying drawings. The drawings may not be to scale and
some features or elements of the depicted examples may purposely be embellished,
or portions removed, for clarity. Similar reference numbers within the drawings refer
to similar or identical elements. The drawings are provided only as examples and,
therefore, the drawings should be considered illustrative of the present invention and
its various aspects, embodiments and options. The drawings should not be
considered limiting or restrictive as to the scope of the invention.
Figure 1 is a side elevation view of one end of an example of a flexible,
electrically insulated, isolation link.
Figure 1A is an enlarged, partially cutaway, view of a portion of Figure
Figure 2 is a partially exploded view of the portion of the isolation link of
Figure 1.
[0021] Figure 3 is a side elevation view showing an isolation link passing
through a dolly during pulling.
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Figure 4 is an assembled spelter lock as shown used in the spelter
socket in the coupling of Figure 1A.
Figure 5 is, in perspective view, an alternative embodiment of an
isolation link according to a further aspect of the invention.
[0024] Figure 6 is an enlarged view of a portion of Figure 5.
Figure 7 is an enlarged, partially cut-away view of Figure 6 showing the
swivel, ball joint and part of the spelter coupling removed.
Figure 8 is a view of the primary and secondary spelters of Figure 7.
DETAILED DESCRIPTION:
Isolation link 100 is a flexible, weather resistant and preferably
weather-proof, electrical insulator having the properties that it not only does not
conduct electric current, through its length, but also will carry a tensile loading and
also preferably allow for swivelling, rotation, or other relative movement along the
link of at least one portion of the link relative to another to relieve torque loading on
or at the end of the link due to any torque applied to the link from for example a
pulling wire or a pulling rope. For example, the isolation link 100 may be a length of
tensile and dielectrically tested insulated rope with dielectric properties, preferably
protected or shielded from the weather or other adverse elements that may
compromise its dielectric properties. The protection or shielding preferably will
protect the entire length of insulated rope. Although during reconductoring or
restringing a pulling rope may be employed in good weather instead of a pulling wire,
it is in applicant’s opinion prudent to use an isolation link in those situations also, in
case of inadvertent deterioration of the rope’s dielectric properties due to moisture,
contamination, etc. Applicant has found that high voltage levels in the energized
conductors, which have been found to induce a voltage and current in non-energized
conductors or static wires, when combined with the adverse effect on the dielectric
properties of a pulling rope due to moisture and/or dirt, etc. in or on the pulling rope,
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may cause the pulling rope to melt and break or otherwise fail. The isolation link 100
electrically isolates between a pulling wire and the associated workers and the
stringing equipment and the to-be-replaced conductor or static wire 20 as the pulling
wire is strung through the power line system
[0028] One example of an isolation link 100 proposed by the applicant uses a
length of dielectric rope which is encased in a flexible, dielectric membrane. The
membrane is filled with dielectric oil or other inert dielectric fluid, such as a dielectric
liquid or gel, so as to soak, completely bath or surround, or impregnate the dielectric
rope and exclude air in the interstices between the fibres of the dielectric rope and in
any voids between the rope and the flexible, dielectric membrane. In one
embodiment, each end of the isolation link, its length depending on the required
electrical insulation as would be known to one skilled in the art, is sealed to maintain
the oil or other dielectric in the membrane and in the rope. The ends are mounted in
a terminating device to a joint such as a ball joint and/or swivel joint, etc., so as to
relieve a torsional force applied to the link and allow relative motion between the end
of the sealed membrane/rope combination and for example the end of the pulling
wire, or end of the conductor or static wire, or end of the sling rope, as the case may
be. A description of the isolation link is provided in applicant’s United States
provisional patent application number 61/968,543, entitled Flexible Isolation Device
for Wire Stringing, filed March 21, 2014, and in applicant’s United States patent
application no. 14/633,749 entitled Stringing Procedure to Replace Existing Static
Line with OPGW, which are included herein in their entirety by reference, and to
which this application claims priority in part.
One skilled in the art will appreciate that the isolation link 100 provides
an electrically insulated connection between the old conductor or static wire (to be
replaced) and the pulling wire that breaks an electrical circuit, such as a ground
circulating current, that can circulate through the earth and along the old conductor
static wire and pulling wire. Typical lengths for isolation link 100 may be 1-2 feet for
low voltage reconductoring (e.g. less than 25kV), or in the order of 8-20 feet for high
voltage transmission reconductoring (e.g. greater than 345kV), 50-250 feet for
slinging a lineman under a helicopter.
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In the instance of a replacement wire being pulled into an occupied
wire position, the existing wire in the occupied wire position is utilized as a pulling
line by positioning it in dollies or travelers, connecting it to the new wire and pulling
the existing wire utilizing for example a v-groove or bullwheel puller. All pulling and
tensioning equipment and conductor materials are situated upon equal potential
zones (EPZ’s) at each end of the pull. A running ground is placed upon the pulling
line at the wire puller end and another running ground is placed on the new wire at
the tensioning end (payout). Close proximity stringing is executed in the same
manner, with the exception that the circuit, static, or OPGW (collectively herein static
wire) being replaced is de-energized, but is co-located with an energized circuit.
Although the wire being installed is not directly energized, such as by a
utility company in the normal course of supplying electricity, the close proximity of
the energized phases creates an energized environment which imparts an induced
voltage and current onto the pulling line and on the new wire. The running grounds
are used in order to protect the equipment and the workers who are required to be in
close proximity to the wires. However, multiple ground potential points combined
with the induced voltage and current create a ground circulating current with
unknown and unpredictable electrical forces. A single point ground will greatly
reduce this effect, but would leave one end of the entire pull operation, or simply the
pull unprotected.
As stated above, use of di-electric tested rope installed between the
pulling line and the new wire can be used to isolate the grounds, however the rope
itself poses a safety hazard due to the potential for the rope to become contaminated
by airborne particles, high humidity, or precipitation rendering the rope conductive
thereby eliminating the isolation between the pulling line and the new wire required.
The isolating insulator link or isolation link 100 may be characterized in
one aspect as including a flexible elongated tensionally-strong insulator such as a
membrane-encased dielectric flexible member having terminating couplings mounted
at either end. The couplings provide for relative torsion relief and relative bending
moment relief between, respectively, for example the pulling line at one end of the
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isolation link and the new wire at the other end of the isolation link. In one
embodiment the couplings at either end of the elongated isolating insulator link each
include a first joint allowing relative bi-directional movement between two portions,
for example two halves, of the coupling. A second joint may be provided allowing
relative rotation or swivelling about a longitudinal axis of the coupling.
The first joint may for example be a universal joint, or a ball joint, or a
tensionally strong flexible stem encased within the coupling. The second joint may
for example be a swivel. A single joint may be provided to replace the function of
both the first and second joints.
[0035] As stated above, one example of the flexible member in isolation link
100 proposed by the applicant uses a length of dielectric rope which is encased in a
flexible membrane, hose or tube (collectively herein a flexible membrane), wherein
the flexible membrane is filled with dielectric oil so as to impregnate the dielectric
rope and exclude air in the interstices between the fibres of the rope and in any voids
between the rope and the walls of the membrane. In one embodiment, each end of
the isolation link, its length depending on the required insulation between the pulling
wire and the conductor or static wire as would be known to one skilled in the art, is
sealed to maintain the oil in the membrane and rope, and mounted in a terminating
device to a joint or joints such as described above so as to resist a tensile force
applied to the isolation link and allow relative motion between the end of the flexible
member and the end of the pulling wire or end of the static wire as the case may be.
Thus, as will now be understood, elimination of the circulating current
while providing electrical protection on both ends of the pull may be accomplished by
electrically isolating the pulling line or pulling wire from the new wire using such an
isolating link. This allows the installation of running grounds on both ends of the pull
without creating a circulating current.
The flexible member is flexible or bendable or otherwise non-resiliently
deformable while resisting lengthening due to tensile loading (herein collectively
referred to as flexible) to accommodate for example the bending radius of a traveler
or dolly (as those terms are used interchangeably herein) and in one basic example
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is composed of a flexible high tensile strength, di-electric material with attachment
joints or couplings on each end. The attachment joints or couplings of the isolating
link, mounted at either end of the flexible member, are constructed in such a manner
as to, in a preferred embodiment not intended to be limiting, control both rotation
imparted by the cables and bi-directional shear induced when the connection or
attachment points pass through the dollies. The isolating link, when properly
maintained, is advantageously impervious to moisture, dirt, and airborne particles
including dust, thereby mitigating the potential for the device, and in particular the
flexible member becoming conductive during use. A reinforced composite polymer
or aramid, or combination of those or other synthetic rope fibres, for example in the
form of a composite braided rope are examples of flexible material which may be
used in the flexible member. The flexible membrane encasing the flexible member
may for example be clear or transparent for ease of inspection for the presence of air
in the tube or for the state of the rope, or may be partly clear (for example if the
membrane is a tube having an inspection window strip along its length) or
translucent. The tube may also for example be reinforced as for example found in
conventional insulated hydraulic hoses.
Thus as seen by way of example in Figures 1-4 , isolation link 100
includes attachment couplings 112 at either end of a length of a flexible member
such as flexible dielectric insulator 114. The couplings themselves are not, at least
need not be, constructed of dielectric material and may for example be made of
stainless steel. The elongate dielectric flexible insulator 114 is of sufficient length to
provide electrical isolation for the rated system voltage to which dielectric flexible
insulator 114 will be exposed without the need for the connection joints or couplings
112 to be di-electric. In the instance, without intending to be limiting, of the isolation
link 100 being used in a wire replacement procedure, couplings 112 attach the
flexible insulator 114 to the pulling wire 104 at a first coupling 112, and to the new
wire 106 at a second coupling 112, where the first and second couplings 112 are at
opposite ends of isolation link 100.
[0039] One of the couplings 112 is seen enlarged in Figure 1A. One of the
couplings 112 is seen in partially exploded view in Figure 2. Although not intending
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to be limiting, in those embodiments, torsion resulting in relative rotation in direction
B about longitudinal axis C between flexible insulator 114 and any line attached
thereto, or any wire attached thereto such as either the pulling wire 104 or the new
conductor or static wire 106, is relieved by a swivel joint within bi-directional joint
116. Swivel couplings which may be employed are known to those skilled in the art
but may for example include eye 116a rotatably mounted onto the end of shank 116b
by means of swivel mount 116c. Swivel couplings may for example also be those of
the type, such as the LH104 ™ swivel, sold by Morpac Industries ™ of Pacific,
Washington, USA, as generally represented in Figures 5-8. As would be known to
one skilled in the art, such swivel couplings may employ internal bearings, preferably
sealed or somewhat sealed to inhibit the intrusion or effect of harsh environmental
elements or factors such as moisture, grit, cold/heat, etc. Although not shown it is
understood that the use of swivels would advantageously also include the use of
such bearings so that swivelling rotation in direction B is not left solely to rotation in
direction B of ball 118a within its socket.
Bi-directional joint 116 is bi-directional in the sense that it allows for
both rotation in direction B about axis C, but also rotation in direction D, the latter
provided for example by ball joint 118 in joint 116 so as to accommodate the relative
bi-directional movement caused by shear and bending as the coupling 112 passes,
as for example in direction Z, through and over a dolly 102 as seen in Figure 3. In
the illustrated example, ball 118a is threadably mounted onto shank 116b. Ball 118a
is mounted for rotation within ball socket 120 formed within socket housing 122. In
particular, ball 118a rests against shoulder 120a in socket 120. Bi-directional joint
116 may be of various designs as would be known to one skilled in the art. For
example, and without intending to be limiting, bi-directional joint 116 may be a form
of universal joint, or such as the illustrated ball-joint and swivel combination, or may
include an encased narrow, flexible stem (not shown) having sufficient tensile
strength and which coupling joins one part of coupling 112 to the other part of
coupling 112.
[0041] As described above, flexible member 114 in one embodiment includes
a synthetic rope encased in a tube and mounted at each end thereof to a
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corresponding coupling 112. Thus as seen in Figures 1A and 2, rope 124 is snugly
shrouded in flexible tubing 126. Tubing 126 is shorter than the length of the end of
the rope 124 so as to expose the end 124a from the end of the tube. Spelter socket
128 is hollow along axis C and provides a frusto-conical wedging cavity 128a
between the threaded male end 128b and the oppositely disposed female end 128c.
Male end 128b threadably engages with the threaded female end 122a of socket
housing 122. Female end 128c engages with the end 126a of tube 126. In this
embodiment, which is not intended to be limiting, a tension load on flexible member
114 in direction E, i.e., along axis C, is to be taken up by rope 124 acting on spelter
socket 128, and not to an appreciable degree by tube 126. Tubing 126 may be
mounted into spelter socket 128, and specifically into female end 128c, in a snug
friction fit sealed by seals 130. Seals 130 may for example be o-rings or such other
seals as would be known to one skilled in the art, to create and maintain a fluidic
seal between end 126a of tubing 126 and the interior annular surface of female end
128c.
The end 124a of rope 124 is flared radially outwardly relative to axis C
as a result of, and so as to accommodate, the insertion of a conical first or primary
spelter plug 132 best seen in Figures 4 and 8, along the core of the rope 124. The
primary spelter plug 132 is provided to assist in anchoring the end 124a of rope 124
into the spelter socket 128. The spelter plugs are also referred to herein as spelters.
In the illustrated embodiment, which is not intended to be limiting, a second or
secondary spelter plug 134, which may have a small reverse taper relative to the
taper on the primary spelter plug, is also provided to also assist in anchoring the end
124a of rope 124 into the spelter socket 128 and to assist in maintaining the seating
of the seals 130 when the rope is under tensile loading. Spelter plug 134 may be
rigidly mounted to or otherwise near or adjacent spelter plug 132. The mounting
may be for example by means of a rod 136, seen in Figure 4, although it is to be
understood that the use of such a rod is not required. The ends of rod 136 may be
threaded, and the spelter plugs 132, 134 hollow so as to accommodate rod 136
journalled through the lengths of the spelter plugs and the spelter plugs anchored
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onto the rod by nuts 138. A positioning nut 138a may be used to hold spelter plug
134 in a desired position along rod 136.
Primary spelter plug 132 has a tapered or conically wedge-shaped
surface 132a which is sized so as to evenly sandwich, i.e., to substantially evenly
distribute a pressure loading to, end 124a of rope 124 between the surface of cavity
128a and the surface 132a of primary spelter plug 132 when tension is applied to
rope 124 in direction E. The taper of plug 132 is inclined relative to axis C at, for
example, the same angle relative to axis C as the surface of frusto-conical cavity
128b in spelter socket 128, although this is not intended to be limiting. Secondary
spelter plug 134 is advantageously positioned along rod 136 so that once spelter
lock 140 (in this embodiment spelters 132, 134 and rod 136) is pushed into and
along the centroidal core of the end 124a of rope 124, and the spelter lock 140 and
the end of rope 124 slid into the spelter socket 128, not only is the end 124a of the
rope 124 flared over the primary spelter 132, but the portion of the rope covering the
secondary spelter 134 is radially outwardly compressed. Thus, just as the primary
spelter compresses the end of the rope 124 against the frusto-conical cavity 128a,
the secondary spelter compresses against the interior surface of female end 128c
(herein also referred to as a female mating collar of the spelter socket or coupling)
the portion of the rope 124 and tube 126 sandwiched between the secondary spelter
134 and the interior surface of female end 128c of spelter socket 128. This radially
outward compression of the rope and tube in the female mating collar, end 128c, of
the spelter socket may assist in holding the fluidic sealing of seals 130 when rope
124 in under tension in direction E and when thus the rope may be of reduced
diameter. Such a radially outward compression also may increase the frictional
engagement of the secondary spelter in the rope 124 to assist in holding the rope in
the spelter socket 128. The secondary spelter 134 may, in alternative embodiments,
be replaced with a hydraulic hose fitting threaded or otherwise incorporated into end
128c of spelter socket 128.
The spelter lock 140 also may include a neck 142 and an annular
locking flange 144. Neck 142 is of reduced radial diameter relative to the radial
diameters of the widest end of primary spelter 132 and relative to the diameter of
C2115864.DOCX;2 C2085981.DOCX;1
locking flange 144. The length of neck 142 is such that a first di-electric clamp 146
(shown in dotted outline in Figure 2), such as a di-electric hose clamp (one example
of which being a plastic strap), may be used to pinch or compress a corresponding
annular portion 124a’ of end 124a of rope 124 into the annular channel formed
around neck 142 between primary spelter 132 and locking flange 144. This locks the
end of the rope onto the spelter lock 140. A second di-electric clamp 148 (also
shown in dotted outline) may be used to further lock a second rope portion 124a’’ of
the rope end 124a onto the spelter lock by clamping the rope portion 124a’’ down
onto the end of the rod 136 on the opposite side of locking flange 144 from neck 142.
[0045] In embodiments employing a rod 136, because rod 136 may be
metallic, as may be the primary and/or secondary spelters 132,134, and indeed all of
spelter lock 140, an electrically conductive connection should be provided, such as a
spider or star washer 150 seen in Figure 4, between rod 136 and the interior surface
of spelter socket 128 adjacent surface 128a. Spider or star washer 150 may be
separated from locking flange 144 by washer or spacer 136a. One or more set
screws 122b may advantageously be provided, acting for example between housing
122 and the male end 128b of spelter socket 128, to resist inadvertent unscrewing of
the housing 122 from the spelter socket 128.
A dielectric fluid, for example a dielectric fluid such as oil (e.g., viscosity
of about 0.5 centi-Stoke) or a viscous inert fluid or gel such as fluidic silicone, or
other dielectric fluids as would be known to one skilled in the art, is impregnated into
rope 124 and filled into the interstices between rope 124 and tube 126 so as not to
leave any air bubbles or air pockets. The dielectric fluid fills the tube and completely
impregnates between the fibres of the rope along the entire length of the rope and
tube extending between and into the couplings 112. To stop the dielectric fluid from
escaping from within cavity 128a and past the clamps 146, 148, which themselves
will act as seals inhibiting the movement of the dielectric fluid along the rope fibres
so as to leak into the cavity of housing 122, a further seal (not shown) may be
provided. One example of such a further seal, and without intending to be limiting, is
to fill the cavity in the spelter socket with epoxy resin while the resin is in its fluid
state, and let the epoxy harden while completely filling any voids in the spelter socket
C2115864.DOCX;2 C2085981.DOCX;1
cavity and for example anchoring the spelter 132 by the incursion of the resin into
the spelter via apertures 132b.
In one embodiment, hollow flexible spinal member 152 seen in dotted
outline in Figure 2, which may be a narrow diameter flexible tube, is inserted along
the length of the core of rope 124. The function of the spinal member 152 is to
recirculate the dielectric fluid from one end of the flexible member 114 to the other
end of flexible member 114 when the dielectric fluid becomes pressurized at one end
as for example when the link 100 passes over a dolly 102.
While the above disclosure describes certain examples of the present
invention, various modifications to the described examples will also be apparent to
those skilled in the art. The scope of the claims should not be limited by the
examples provided above; rather, the scope of the claims should be given the
broadest interpretation that is consistent with the disclosure as a whole.
C2115864.DOCX;2 C2085981.DOCX;1
Claims (26)
1. An apparatus for electrically isolating a power line conductor or static wire from a pulling line comprising: 5 a. a flexible non-electrically conductive tube having first and second opposite ends, b. an inelastic flexible dielectric member having first and second opposite ends, said dielectric member journalled in said tube and extending from said first end of said tube to said second end of said tube, 10 c. first and second coupling members anchored, respectively, to said first and second ends of said dielectric member, said first and second ends of said tube mated in sealed engagement with said first and second coupling members so that said first and second coupling members fluidically seal said first and second ends of said tube and fluidically seal said dielectric 15 member within said tube, d. said tube filled with a dielectric fluid so as to displace any air in said tube and said dielectric member, e. said first and second coupling members adapted to releasably couple to the power line conductor or static wire and the pulling line respectively.
2. The apparatus of claim 1 wherein said dielectric member is a synthetic rope which includes strands chosen from the group comprising: aramid, polyester, polyethylene, aliphatic polyamides, semi-aromatic polyamides.
3. The apparatus of claim 1 wherein each said coupling member has a cavity, and 25 wherein said dielectric member extends into said cavity, and wherein said cavity is filled with a fluid-to-solid setting compound so as to fix said dielectric member within said cavity. C2115864.DOCX;2 C2085981.DOCX;1
4. The apparatus of claim 3 wherein said setting compound is a two part resin.
5. The apparatus of claim 1 wherein said tube is at least partly translucent so that the condition of said fluid may be inspected from the exterior of said tube.
6. The apparatus of claim 1 wherein said tube is reinforced. 5
7. The apparatus of claim 1 wherein said fluid is dielectric oil.
8. The apparatus of claim 7 wherein said oil has a viscosity of substantially 0.5 centi-stokes.
9. An electrical isolator comprising: a. a flexible non-electrically conductive membrane having first and second 10 opposite ends; b. an inelastic flexible dielectric member having first and second opposite ends, said dielectric member journalled in said membrane and extending from said first end of said membrane to said second end of said membrane; 15 c. first and second coupling members anchored, respectively, to said first and second ends of said dielectric member, said first and second ends of said membrane mated in sealed engagement with said first and second coupling members so that said first and second coupling members fluidically seal said first and second ends of said membrane and fluidically 20 seal said dielectric member within said membrane; d. said membrane filled with a dielectric fluid so as to displace any air in said membrane and said dielectric member; e. and wherein said first and second coupling members are adapted to couple to objects at opposite ends of said electrical isolator. C2115864.DOCX;2 C2085981.DOCX;1
10. The electrical isolator of claim 9 wherein said dielectric member is a synthetic rope which includes strands chosen from the group comprising: aramid, polyester, polyethylene, aliphatic polyamides, semi-aromatic polyamides .
11. The electrical isolator of claim 9 wherein each said coupling member has a 5 cavity, and wherein said dielectric member extends into said cavity, and wherein said cavity is filled with a fluid-to-solid setting compound so as to fix said dielectric member within said cavity.
12. The electrical isolator of claim 11 wherein said setting compound is a two part 10 resin.
13. The electrical isolator of claim 9 wherein said membrane is at least partly translucent so that the condition of said fluid may be inspected from the exterior of said membrane.
14. The electrical isolator of claim 9 wherein said membrane is reinforced.
15 15. The electrical isolator of claim 9 wherein said fluid is dielectric oil.
16. The electrical isolator of claim 15 wherein said oil has a viscosity of substantially 0.5 centi-stokes.
17. The apparatus of claim 1 further comprising a pressure equalizing tube nested within said tube and extending substantially from said first end to said second 20 end of said tube so as to provide fluid communication of said fluid between said first and second ends of said tube.
18. The apparatus of claim 17 wherein said dielectric member has a core, and wherein said pressure equalizing tube runs along said core.
19. The apparatus of claim 1 wherein said dielectric member substantially fills said 25 tube.
20. The electrical isolator of claim 9 further comprising a pressure equalizing tube nested within said membrane and extending substantially from said first end to C2115864.DOCX;2 C2085981.DOCX;1 said second end of said membrane so as to provide fluid communication of said fluid between said first and second ends of said membrane.
21. The electrical isolator of claim 20 wherein said dielectric member has a core, and wherein said pressure equalizing tube runs along said core. 5
22. The electrical isolator of claim 9 wherein said dielectric member substantially fills said membrane.
23. A method for electrically isolating an energized power line conductor or static wire from a pulling line comprising: a. providing an electrical isolator comprising: 10 i. a flexible non-electrically conductive tube having first and second opposite ends, ii. an inelastic flexible dielectric member having first and second opposite ends, said dielectric member journalled in said tube and extending from said first end of said tube to said second end of said 15 tube, iii. first and second coupling members anchored, respectively, to said first and second ends of said dielectric member, said first and second ends of said tube mated in sealed engagement with said first and second coupling members so that said first and second 20 coupling members fluidically seal said first and second ends of said tube and fluidically seal said dielectric member within said tube, said tube filled with a dielectric fluid so as to displace any air in said tube and said dielectric member, iv. said first and second coupling members adapted to releasably 25 couple to the power line and the pulling line respectively, C2115864.DOCX;2 C2085981.DOCX;1 b. coupling said first coupling member to an end of said power line conductor or static wire, and coupling said second coupling member to an end of said pulling line.
24. The apparatus of claim 1 substantially as herein described with reference to 5 figures 1 – 8 and/or examples.
25. The electrical isolator of claim 9 substantially as herein described with reference to figures 1 – 8 and/or examples.
26. The method of claim 23 substantially as herein described with reference to figures 1 – 8 and/or examples. C2115864.DOCX;2 C2085981.DOCX;1
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| NZ762658A NZ762658A (en) | 2014-03-21 | 2015-03-20 | Flexible electrical isolation device |
Applications Claiming Priority (5)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US201461968543P | 2014-03-21 | 2014-03-21 | |
| US61/968,543 | 2014-03-21 | ||
| US14/633,749 US20150249325A1 (en) | 2014-02-28 | 2015-02-27 | Method for stringing replacement optical ground wire or static wire near energized power lines |
| US14/633,749 | 2015-02-27 | ||
| PCT/US2015/021876 WO2015143402A1 (en) | 2014-03-21 | 2015-03-20 | Flexible electrical isolation device |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| NZ725198A NZ725198A (en) | 2021-05-28 |
| NZ725198B2 true NZ725198B2 (en) | 2021-08-31 |
Family
ID=
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