NZ731557B2 - Method and apparatus for supporting a permanent cable splice during cable installation - Google Patents

Abstract

device for supporting a permanent cable splice during installation of one or more connected electrical transmission cables is disclosed. In the installation or stringing of electrical transmission cables, lengths of cable, commonly provided on a reel, are pulled under tension into position over one or more cable supports, or sheaves. Commonly, multiple reel lengths of cable are connected together to make up the total length needed for installation. A splice is typically used to connect a second end of a first cable to a first end of a second cable. However, most permanent splices are not rated for the tension and flexibility required to pull the length of cable through the feed reel and over the sheaves and into a permanent, finished position. The disclosed device supports a permanent cable splice and the corresponding ends of the electrical transmission cables held within the cable splice in withstanding tension and bending forces when the cables and permanent cable splice are being pulled into place for installation, thus allowing a permanent splice rather than a temporary splice to be used during installation. The device includes an elongate hollow resilient liner (2) adapted to be mounted over a cable splice (18). A sleeve (32, 33) is mountable over at least a portion of the liner. e or more cable supports, or sheaves. Commonly, multiple reel lengths of cable are connected together to make up the total length needed for installation. A splice is typically used to connect a second end of a first cable to a first end of a second cable. However, most permanent splices are not rated for the tension and flexibility required to pull the length of cable through the feed reel and over the sheaves and into a permanent, finished position. The disclosed device supports a permanent cable splice and the corresponding ends of the electrical transmission cables held within the cable splice in withstanding tension and bending forces when the cables and permanent cable splice are being pulled into place for installation, thus allowing a permanent splice rather than a temporary splice to be used during installation. The device includes an elongate hollow resilient liner (2) adapted to be mounted over a cable splice (18). A sleeve (32, 33) is mountable over at least a portion of the liner.

Description

METHOD AND APPARATUS FOR SUPPORTING A PERMANENT CABLE SPLICE DURING CABLE INSTALLATION Cross Reference to Related Application This application claims priority from United States Provisional Patent Application No. 62/064,843 filed October 16, 2014 entitled Device And Method For Connecting And Installing Cable.

Field of the Invention The present disclosure relates to devices and methods for connecting lengths of ical transmission cable and installing connected s of cables on cable supports; and in ular to a method and apparatus for supporting and protecting a permanent cable splice at its junction with the exposed ends of the spliced cables held within the splice during installation of the cables.

Background of the Invention In the installation or stringing of electrical transmission cables, lengths of cable, commonly provided on a reel, are pulled under tension into on over one or more cable supports, or sheaves. While it is desirable to maximize the length of cable to be led, a number of limitations dictate the practical reel length of cable that can be used. Such limitations include terrain, angles at which the cable is pulled at, pulling capacity of the pulling equipment, both in terms of length and n and capacity of the cable reels provided for the project.

Electrical ission cables can include high voltage power line conductor, overhead static wire, and optical ground wire (OPGW). Cable properties, including the maximum bend angle and tension that a cable can handle, will also limit a maximum reel length of cable that may be deployed. ly, multiple reel lengths of cable are connected together to make up the total length needed for installation. A splice is typically used to connect a second end of a first cable to a first end of a second cable. However, most ent splices are not rated for the tension and flexibility required to pull the length of cable through the feed reel and over the sheaves and into a permanent, finished position. In such cases, temporary splices are conventionally used for the installation. Once the temporary splices are installed between the reel lengths of cable, the spliced cable is pulled into position. After pulling the cable into position, crews must remove the temporary splices and install permanent splices in their place.

A need therefore exists for a method and apparatus for protecting and supporting a permanent cable splice during cable installation.

It is an object of at least preferred embodiments of the present invention to s at least some of the aforementioned disadvantages. An onal or alternative object is to at least provide the public with a useful choice.

Summary of the Invention The present invention may be characterized in its various aspects as a device, a system and a method of using the device and system.

In accordance with an aspect of the invention, a device is provided for ting a permanent cable splice and the ends of a pair of electrical transmission cables held in the splice, and as part of the splice, during installation of the electrical transmission cables along a travel path which includes a forced curvature of the cables such as over sheaves. The splice is conventionally rigid and has opposite ends so as to form a junction at each of the opposite ends of the splice n the splice and the corresponding exposed ends of the cables held in the splice. The device in one aspect includes an te, , resilient liner and an te sleeve, wherein the liner is advantageously longer than the sleeve. The sleeve is adapted to be snugly mounted over and along the liner. At least one end of the sleeve is inset along the liner from at least one corresponding end of the liner so long as the sleeve is mounted over at least one junction when the liner is mounted over the cable splice so as to position the cable splice within the hollow cavity of the liner. When the liner and the sleeve are so mounted on the cable splice, the sleeve compresses the liner against the cable splice at the corresponding junction whereby a stress concentration at the junction upon a bending of the cables relative to the splice during the forced curvature of the cables is distributed away from the junction.

In accordance with a further aspect of the invention, an apparatus is provided for protecting an electrical conductor having a ent cable splice. The apparatus includes: an elongate, resilient cylindrical liner defining a longitudinal through hole and a first circumferential groove; a first sleeve that resides within the first circumferential groove and around a circumference of the liner; and a first taper located at a first end of the liner, wherein one end of the first taper abuts the first sleeve. The liner may be substantially rical and e a pair of opposed-facing half-pipes ble to each other in opposed-facing relation so as to define the longitudinal through hole therethrough. The liner may have a second circumferential groove, spaced from the first circumferential groove along the liner. A second sleeve resides in the second circumferential groove. ageously, a second taper is located at a second end of the liner te the first end so that a base end of the second taper abuts the body of the liner, and may abut the first sleeve if there is only one sleeve on the liner, or may abut the second sleeve if there are two sleeves on the liner.

In preferred embodiments, the liner is longer than the sleeve, or cumulative length of the sleeves if more than one sleeve is employed.

A cable splice is d within the through hole of the liner. When the liner and the sleeve or sleeves are mounted on the cable splice, the sleeve or sleeves compress the liner against the cable splice. Advantageously, the sleeves are rigid. The through hole is adapted for mounting over the cable splice on the electrical conductor. The liner may e at least one separate ner part mounted in the liner so as to extend along the liner and over at least opposite ends of the electrical conductor when the opposite ends of the electrical conductor are d in the cable splice and when the liner is mounted on the cable . The separate stiffener part may be one or more ner parts chosen from the group which includes: a rod, a plurality of rods, a plurality of rods in radially spaced apart array about a longitudinal axis of the liner, a split pipe, a half-pipe, a stringer. Each separate stiffener part may be elongate and substantially linear.

In accordance with a further aspect of the invention, a system is provided for ting a permanent cable splice and the ends of a pair of electrical transmission cables held in the splice during installation of the electrical transmission cables along a travel path which includes a forced curvature of the cables. The system includes: (a) a rigid cable splice having opposite ends so as to form a junction at each of the opposite ends of the splice between the splice and a corresponding exposed end of the cables held in the splice; one or more resilient liners sized to both snugly mount over at least the opposite ends of the cable splice, over the junctions and over at least a portion of the exposed ends of cables where the exposed ends of the cables extend from the ons; and, one or more removable sleeves mountable over at least a portion of each of the one or more liners and positioned on the one or more liners so as to cover the corresponding junctions. The one or more sleeves compress their ponding liners against the cable splice at a corresponding junction whereby a stress concentration at the corresponding junction is distributed from the junction upon a bending of the cables relative to the splice during the forced curvature of the cables.

A method is disclosed of installing ical transmission cable using the above bed device and system of. The method includes: a. providing a first cable having a first end and a second end; b. providing a second cable having a first end and a second end; c. installing the first cable by pulling the first cable over one or more sheaves to the second end of the first cable; d. connecting the second end of the first cable to the first end of the second cable using a permanent splice; e. affixing the one or more liners over at least a portion of the permanent cable splice to protect the permanent splice during the installation in steps (c) and (g); f. assembling the one or more sleeves over at least a portion of each of the one or more liners to compress the one or more liners against the permanent splice at a junction of the permanent splice with the first cable and at a junction of the permanent splice with the second cable; g. continuing the installation of step (c) by pulling the first cable, the ent splice and the second cable over the one or more sheaves.

As applied to the device, system and/or method: Advantageously the sleeves are rigid. The sleeves may be a single sleeve mounted on a single liner. The liner may have tapered ends at opposite ends thereof. At least one stiffener may be mounted in the liner so as to extend along the length of the liner and over at least the opposite ends of the cable splice when mounted thereon. Advantageously, the stiffeners extend over the junctions. The stiffeners may be chosen from the group comprising: a rod, a ity of rods, a plurality of rods in radially spaced apart array about a longitudinal axis of the liner, a split pipe, a half-pipe, a stringer.

In one embodiment the one or more liners and the one or more sleeves are d to be removable from the cable splice when d thereon, and the method may include the removal of the sleeves and liners after the installation of the cables.

The one or more sleeves may be a pair of sleeves mounted spaced apart along the liner. The one or more liners may be a single liner. At least one tether may be provided, tethered to each of the pair of sleeves so as to join each sleeve to the other when mounted on the liner. The tethers may be flexible.

Advantageously the liners each include at least one r recess formed therein, and in particular formed around an outer surface of the liners, each recess shaped and sized to receive mounted therein the one or more sleeves. The s may be mounted ntially flush with the outer e of the liners when the sleeves are mounted in their corresponding recesses.

In one embodiment each ner is elongate and substantially linear. Each stiffener may include a curved end which is curved over a corresponding junction when the liner is mounted over the cable splice. The curved end may extend from the junction so as to lie substantially flush onto the cable when the liner and sleeve are mounted onto the cable splice and cables.

Each one of the stiffeners may have a curved end.

In one preferred embodiment, not intended to be limiting, the liner includes a pair of opposed-facing half-pipes or such other shape so as to be mountable to each other in opposedfacing relation to thereby define an elongate hollow cavity therethrough.

Brief Description of the Drawings Figure 1 is a side elevation view of one embodiment of a liner and sleeve device installed on a permanent splice connecting two separate lengths of cable.

Figure 2 is a side sectional view of the liner of Figure 1, such as would be seen in ection along line 2-2 in Figure 6A.

Figure 3 is a partially exploded view of the liner of Figure 1, such as would be seen in cross- section along line 3-3 in Figure 6E.

Figure 4 is a side cross-sectional view of the liner and sleeve device of Figure 1 rated passing over a sheave.

Figures 5A is a side ion view of one sleeve of the device of Figure 1.

Figure 5B is a plan view of the sleeve of Figure 5A.

Figure 6A is a sectional view of the liner of Figure 2 in a plane orthogonal to the longitudinal axis of the liner.

Figure 6B is a cross-sectional diagrammatic view, not to scale, of one of the sleeves of Figure 1 in a plane orthogonal to the longitudinal axis of the sleeve.

Figure 6C is a cross-sectional view of the liner and sleeve of Figures 6A and 6B respectively with the sleeve mounted on the liner.

Figure 6D is the view of Figure 6A showing the liner assembled.

Figure 6E is the liner of Figure 6A showing the liner in a partially exploded view.

Figure 7A is a first side elevation view of a further embodiment of a sleeve, such as seen mounted on a liner in Figure 8.

Figure 7B is a second side elevation view, from a side opposite the first side elevation view of the sleeve of Figure 7A.

Figure 7C is a plan view of the sleeve of Figures 7A and 7B.

Figure 7D is a sectional view along line 7D-7D in Figure 7B showing a fastener and hinge.

Figure 8 is a side elevation view of a further embodiment of the liner and sleeve device installed on two spliced-together lengths of cable.

Figure 9 is a side cross-sectional view of the ment of the device illustrated in Figure 8, installed on two connected lengths of cable.

Figure 10 is, in side elevation view, a further embodiment of the liner and sleeve device having a single continuous sleeve encasing a single liner which extends over the entire length of the permanent cable splice.

Figure 11 is, in side ion view, the liner of Figure 10.

Figure 12 is, in partially exploded cross-sectional view, the liner of Figure 11 in cross-section along its length.

Figure 13 is a cross-sectional view of Figure 10 along the length of the liner and sleeve device showing the device mounted onto a pair of cable ends held within a permanent cable splice.

Figure 14 is, in side elevation view, the sleeve of Figure 10.

Figure 15, is, in plan view, the sleeve of Figure 14.

Figure 16 is, in side elevation view, a further embodiment of the sleeve of Figure 14 rating the use of a hinge along one side of the sleeve.

Figure 17 is, in plan view, a sleeve of Figure 16.

Figure 18 is, in side elevation view, a further embodiment of the liner and sleeve device mounted on a pair of cable ends held within a permanent cable splice.

Figure 19 is a cross-sectional view along the length of the liner and sleeve device of Figure 18 showing the use of rods embedded within the liner.

Figure 20 is a partially exploded view of the liner of Figure 19.

Figure 21 is a cross-sectional view along the length of the liner and sleeve device of Figure 18 illustrating the device mounted on the pair of cable ends held within a permanent cable .

Figure 22A is a sectional view through the liner of Figure 18 in a plane laterally cross the length of the liner illustrating the section of the liner which snugly mounts onto an exposed end of a cable.

Figure 22B is a cross-sectional view laterally across a sleeve of Figure 18.

Figure 22C is the combined cross-sectional views of Figure 22A and 22B.

Figure 22D is a cross-sectional view lly across the liner of Figure 18 at a position along the liner where the liner snugly mounts onto the ent cable splice.

Figure 22E is, in partially exploded view, the cross-sectional view of Figure 22D.

Figure 23 is, in side elevation view, yet a further embodiment of the liner and sleeve device mounted onto a pair of cable ends held within a permanent cable splice.

Figure 24 is a cross sectional view along the length of the liner and sleeve device of Figure 23 illustrating the use of the split pipe embedded within the liner.

Figure 25 is, in partially exploded view, the cross-sectional view of Figure 24.

Figure 26 is a cross-sectional view along the length of the liner and sleeve device of Figure 23 illustrating the device mounted onto a pair of cable ends held within a permanent cable .

Figure 27 is, in plan view, the split pipe embedded in the liner of Figure 24 Figure 28A is a cross sectional view through the liner of Figure 23 at a position where the liner mounts onto one of the exposed ends of cable.

Figure 28B is a cross-sectional view laterally through a sleeve of Figure 23.

Figure 28C is a combined cross-sectional view of Figure 28A and 28B.

Figure 28D is a cross-sectional view laterally through the liner of figure 23 at a position where the liner mounts onto the permanent cable splice.

Figure 28E is, in lly ed view, the cross-sectional view of Figure 28D.

Figure 29 is, in side ion view, the liner and sleeve device of Figure 18 illustrating the use of tethers between the pair of sleeves.

Figure 30 is, in side elevation view, the pair of sleeves and tethers of Figure 29.

Detailed Description of the Preferred ments The present disclosure provides a liner and sleeve device, a , and a method of using same to support a permanent cable splice and the corresponding ends of the ical transmission cables held within the cable splice in anding tension and bending forces when the cables and permanent cable splice are being pulled into place for lation, thus allowing a permanent splice rather than a temporary splice to be used during installation. The present liner and sleeve device can be used with conventional permanent splices commonly available, thereby avoiding the need for the installation and removal of temporary splices.

The present liner and sleeve device serves to withstand, transfer and distribute bending loads and stresses that tend to concentrate at the splice-cable on at each end of the permanent cable splice during tension and bending of the cable as it is installed. The present liner and splice device deflects and distributes these stress concentrations from the splice-cable junctions to the sleeve and liner adjacent; that is, in the area surrounding each of the splicecable junctions, thereby reducing and helping to prevent damage to either the permanent cable splice or the cable during installation of the cable.

The present liner and splice device r allows for a permanent splice to be installed at the tensioning site during the installation process, without the need for a temporary splice that later requires removal and replacement with a permanent splice. Once the cable is led, the present liner and sleeve device may be removed. Such removal is quicker and easier than removing a temporary splice and installing a permanent .

With nce to the s, the present liner and sleeve device includes a generally cylindrically shaped hollow liner 2, which may be two separate pieces that, when installed, surrounds a permanent cable splice 18. Splice 18 splices together, and electrically joins, in a linear array the ends of a first cable 8 and a second cable 10. One or more sleeves 32, 33 are sized so as to compress liner 2 when mounted thereon. Preferably, liner 2 may be made of a semi-rigid, resilient material that may be moulded to form an inner channel 34 of shape and size so as to snugly fit the cable splice 18 and cables 8, 10 mounted journalled therein. Liner 2 and the compression of liner 2 provided by the one or more sleeves 32, 33 serve to receive the stress concentrations experienced at the junctions n the cable splice 18 and each of the cables 8, 10 and distribute these es through the liner 2 to t the mechanical integrity of the splice 18 and cables 8, 10, and in particular the junctions therebetween, during installation of the cables into position onto electrical transmission towers, for example.

The liner 2 may be ctured from a material that may be both semi-rigid and resiliently compressible, such as for example, without intending to be limiting in any way: rubber, a flame retardant polymer, or a ite material such as a rubber compound. Liner 2 may exhibit elastic properties so as to restore or return itself to its non-deformed geometric shape after deployment over a sheave (Figure 4). Liner 2 may incorporate separate, le reinforcement or strengthening materials or structures made of, for example, steel, titanium, or fiberglass or aramids or polymers as such structures are described below by way of example. It will be understood by a person ordinarily skilled in the art that various types of als, including composite materials, may be suitable for the manufacture of the liner 2, wherein such materials may be semi-rigid or resiliently bendable and compressible. As seen in Figures 3 and 6e, in one embodiment the liner 2 may be made of two mating semi-cylindrical pieces resembling half-pipes that are fastened together in opposed facing relation along their long edges 16. Such fastening may take any form well known in the art, including but not limited to the use of adhesives, separate fasteners such as screws, bolts, or pins, or by mating es formed on the long edges 16 of each liner piece that ate with one another to fasten the liner pieces to each other. Such mating profiles can include tongue 24 and groove 25 profiles as rated in Figures 6 A, C, D and E, although it would be well understood by a person of skill in the art that other profiles are also possible and encompassed within the scope of the present teaching.

The liner 2 may advantageously, although not necessarily, have one or more r grooves or recesses 12 formed on or around an outer surface thereof. es 12, which may also be a circumferential recess, are sized to accommodate each of the one or more sleeves 32, 33 such that, for example, an outer surface of each sleeve 32, 33 lies substantially flush, or flush, with the outer surface of liner 2, so as to be mounted therein flush with or slightly raised from the outer e of the liner 2. This not only secures each sleeve on the liner in its desired position on or adjacent the junction between cable splice 18 and the d ends of the cables 8, 10, but also may inhibit ding edges of sleeves 32, 33 from catching on for example a traveller 35, sheaves or reels during stringing of the cables 8, 10 through the traveller, sheaves or reels. Preferably, the liner 2 may have tapers 14 that taper at their distal ends so as to be flush or near flush with the cables 8, 10. The ends of the liner 2 are thus less likely to catch on the traveller 35, sheaves or reels during stringing of the cable. Furthermore, tapers ends 14 facilitate smooth, initial t with a surface of traveler 35. The base ends of tapers 14, opposite their distal ends, abut the corresponding ends of the cylindrical body of liner 2, and from part thereof to assist in distributing the stress concentrations throughout the liner 2. This helps the liner 2 to bend more easily at its ends around the circumference of the cylindrical surfaces of the traveler 35 and the reels as the cables 8, 10 are pulled under tension from the reels and through travellers 35 during installation along a travel path which includes such forced curvature.

With reference to Figures 5A through 7D, in one embodiment the sleeves 32, 33 may be made up of two mating half-pipes that, when mounted on splice 18 and cables 8, 10, mate together in an opposed-facing, snug ssion fit around the liner 2 to y compress the liner 2 radially ly; that is, radially inwardly relative to the longitudinal axis A (Fig. 3) of the liner. Sleeves 32, 33 also protect the junctions 40, 42 between the permanent splice 18 and each of the exposed ends of cables 8, 10. The two half-pipes of each sleeve 32, 33 are preferably fastened by means of one or more fasteners 22 that are inserted or threaded through one or more openings 20 in each half-pipe of the sleeve. Other means of joining the sleeve half-pipes are also contemplated, such as application of adhesive or machining or otherwise forming the sleeve components to form cooperating protrusions-and-indents for example -and-groove, etc., that will frictionally or otherwise interfit when brought together. However, fasteners 22 provide the advantage that they may be tightened to provide a desired level of compression of the liner 2 onto the splice 18 and the spliced cables 8, 10 within the liner 2. Fasteners 22 may also be easily removed after installation. Alternatively, each sleeve 32, 33 may consist of two halves that open in a clam-shell ement about hinge 26, thereby requiring the use of fasteners 22 or other joining means along only one side of the sleeve 32 that may be opposite hinge 26 (Fig. 7D).

Preferably the s 32, 33 are rigid. For example, without intending to be limiting, the sleeves 32, 33 may be manufactured from steel, titanium, or composites or other suitably rigid material. Further preferably, the sleeves 32, 33 may be made to a rd length and may accommodate standard fasteners 22, such that the s 32, 33 can be used in a ude of cable connection and installation applications.

In some cases, for example where splice 18 is rced, encasement in liner 2, or within a liner 2 and sleeves 32, 33 along the entire length of splice 18 may not be required. In such cases, where splice 18 may be reinforced by an insert such as a steel insert (not shown) as rated in Figures 8 and 9 a first liner 28 is mounted over junction 40 between splice 18 and an nt exposed end of the first cable 8, and a second liner 30 is mounted over the junction 42 between the splice 18 and an adjacent exposed end of the second cable 10. In such cases, the two liners 28, 30 are still sized according to the diameters of the permanent splice 18 and cables 8, 10, so as to mount substantially flush thereon but the length of the liners 28, 30 may be standardized such that the liners 28, 30 are adaptable to multiple splicing applications. In such cases, only one sleeve 32, 33 may preferably be required per liner 28, 30 respectively. A single liner and sleeve is thus used for each junction 40, 42 separately.

In a typical use, a first end of first cable 8 is pulled off of the reel and installed in n over one or more sheaves. Once the second, opposite, end of the first cable 8 is reached, it is connected by ent cable splice 18 to a first end of the second cable 10, which may be stored on another reel. ting may be done during the installing process while the cables are under tension. One or more liners 2 are assembled over the permanent cable splice 18 and the adjacent d ends of the cables 8, 10. The liner 2 may be assembled by mounting the two half-pipe pieces of the liner 2 together along their long edges 16. In the embodiment illustrated in Figure 4, one liner 2 is assembled over the permanent cable splice 18 and extends over each of the junctions 40, 42. Alternatively, as illustrated in Figure 9, two liners 28, 30 may be used, in which case a liner 28, 30 is assembled over each of the corresponding junctions 40, 42. Next, one or more sleeves 32, 33 are installed over the liner 2 or liners 28, 30, as the case may be, and over the junctions 40, 42, to compress liner 2 or liners 28, 30 and to encase and thereby protect the ons 40, 42. Installation of the connected cables 8, 10 over one or more sheaves, such as sheaves mounted on electrical transmission towers, is then continued under tension. The liner and sleeve pairs protect the permanent splice and serve to transfer stress concentration from the junctions 40, 42 and distribute the stress concentrations h the liner 2 or liners 28, 30 and through the sleeves 32, 33 to reduce the ed effect of shearing, tension and bending forces experienced at the junctions 40, 42 during installation of the cables 8, 10.

As a second, opposite, end of the second cable 10 is reached, it too may be connected to a further (i.e. third) cable by a second permanent splice and the second permanent splice may be encased by assembly of another of the present liner and sleeve devices to the second ent splice and cable junctions. The process of pulling cable, installing under n, splicing and protecting the splice and adjacent exposed ends of the cables with the present liner and sleeve device may be repeated until a full installation of the desired length of electrical transmission cable is complete. Then, optionally, the liner and sleeve devices may be removed from the permanently d and installed electrical transmission cable by removing sleeves 32, 33 and then removing the one or more liners 2 or 28, 30 as the case may be.

In a further embodiment such as seen in Figures 10 -17, a single, long sleeve 32’ extends over a corresponding length of liner 2 from a first junction 40 between splice 18 and the exposed end of cable 8 to a second junction 42 between splice 18 and the exposed end of cable . Sleeve 32 and liner 2 further extend to cover at least an adjacent portion of the exposed ends of each of the cables 8, 10, adjacent junctions 40, 42. Thus sleeves 32, 33 (Fig. 8) may be replaced by a single sleeve 32’ so as to encase splice 18 and the corresponding length of liner 2, again, with the ends of liner 2 and sleeve 32’ extending beyond junctions 40, 42 so that stress concentrations due to a g applied to the cables and splice at those junctions are relieved by liner 2 and sleeve 32’. The sleeve 32’ may be removably secured onto liner 2 by the same means described above in on to s 32, 33 Thus for example, sleeve 32’ may se two, separate, non-connected, opposing-facing half-pipes and fasteners 22 may be employed in er openings 20. Alternatively, sleeve 32’ may include a hinge or hinges 26 to provide for clamshell g of the sleeve around liner 2. Liner 2 may be shaped to flush mount sleeve 32’ flush along the length of the liner so as to mate sleeve 32’ in an extended annular recess 12’. Again, tapers 14 may advantageously be provided on opposite ends of liner 2 for ease of contacting and passing the liner and sleeve device over for example a traveller 35.

In the embodiments of Figures 18 – 21, and Figures 22A -22E, liner 2 is reinforced with stiffeners such as rcing rods 44. One or more reinforcing rods 44 may be employed, preferably embedded within liner 2. As illustrated, a plurality, shown as six, rods 44 may be embedded in liner 2 so as to extend along the length of liner 2 in radially spaced apart array about and substantially parallel to the longitudinal axis A of liner 2 (Fig. 19). Rods 44 are preferably semi-rigid or may be resilient or elastic to a ermined value so as to assist in resisting or assist in withstanding the bending moment applied to liner 2 and the corresponding sleeve or sleeves at junctions 40, 42 when splice 18, which is d in a liner and sleeve or sleeves, passes over (e.g. completely over and past) for example traveller 35. Rods 44 may be linear, at least for example over the length of splice 18, and may advantageously also include curved ends such as flush-mounting curved ends 44a which extend so as to mount down flush onto the outer surface of the adjacent ends of cables 8, 10. Thus as seen in the side elevation cross-sectional view of Figure 21, rods 44 may be mounted almost flush along the exterior e of splice 18, and curved ends 44a may curve over the ends of splice 18 at junctions 40, 42 and extend so as to lie flush along the adjacent d ends 8a, 10a of conductor cables 8, respectively. The ends of rods 44 may, as illustrated in at least Figs. 19-21, extend beyond the ends of the sleeve or sleeves so as to extend under at least a portion of tapered ends 14 of liner 2.

The embodiments of Figures 22A – 22E, although diagrammatically illustrated, show how the dimensions of the liner 2 and sleeve 32’ or sleeves 32, 33 may be varied so that, as shown, the sleeves and liners may be relatively walled. In the embodiment of Figures 18 – 21 the sleeves and liner are relatively thin-walled as compared to the diameter of the cables and splice. If the sleeve or sleeves and liner are thick-walled, better protection from ng and stress loading upon g is potentially obtained at the junctions 40, 42 as compared to thin-walled sleeves and liner, given the same material for the sleeves and liner. However the thick-walled sleeves and liner may have more difficulty passing over for example a traveller 35.

An optimized balance of wall thickness and protection from shearing and bending stresses is preferred that will distribute the stress loading at the junctions 40, 42 during bending so as to reduce stress concentrations and still allow passage h traveller 35 or through other forced curvature travel paths while stringing the conductor.

Figures 23 -27 and Figures 28A – 28E illustrate a further embodiment where, instead of rods 44, a segment or segments of split pipe 46 (e.g. completely separate, non-connected sections) are employed to reinforce liner 2 and bute the stress concentrations around junctions 40, 42 into liner 2. Thus, as with rods 44, the ends of split pipe 46 extend cantilevered along liner 2 from the ends of splice 18 at junctions 40, 42. Split pipe 46 may include a generally cylindrical, semi-rigid, or ent, pipe which is split or otherwise formed into separate halves along its length. Each half is d into a corresponding half -pipe of liner 2 so that the halves of both the split pipe 46 and liner 2 may be mounted flush against one r in opposed facing relation as shown by way of example in Figures 28A and 28E. Thus, as with the use of rods 44, as seen in Figure 26 split pipe 46 may be d in liner 2 so as to extend along, substantially flush against the exterior surface of splice 18 and then contiguously extend as flush-mounting ends 46a away from junctions 40, 42 substantially flush along the corresponding adjacent exposed ends 8a, 10a of conductor cables 8, 10. The distal ends of flush-mounting ends 46a, distal from splice 18, may extend into tapers 14. As with the use of rods 44, the use of split pipe 46 is not limited to the illustrated embodiment where a plurality of sleeves, for example sleeves 32, 33, are employed, but may also be used in the embodiment of Figure 10 where only one sleeve 32’ is employed. Further, as seen diagrammatically in Figures 28A – 28E, the sleeve or sleeves and liner may be vely walled and split pipe 46 may for example generally bi-sect the radial thickness of liner 2, measured in a direction radial from longitudinal axis A. Bi-secting of the thickness of liner 2 may thus form an inner half-pipe 2a and an adjacent outer half-pipe 2b.

As will be understood, the description of rods 44 and split-pipe 46 are intended to merely be non-limiting examples of strengthening ners or stringers or the like that may be embedded in liner 2 that serve to distribute stress loading at the ends of splice 18 upon forced curvature of the cable ends and ent splice as when passing the splice through a traveller for e. Similar to using rods 44, the use of split-pipe 46 may provide resistance to bending and provide a restoring force to liner 2 when liner 2 is subjected to a g moment by traveller 35. It is also intended to be within the scope of the present invention to use multiple liners 2, for example nested or separate, or any combination thereof, instead of a single liner 2 to protect a single permanent splice 18. Further, although described herein as being both removable and intended to be removed upon completion of the conductor stringing operation, it may be that it is impractical to ately or ever remove the sleeves and liners from the splices. As is common with electrical transmission lines, such as with high-voltage electrical transmission lines, the span of the strung electrical conductors can be over relatively great distances and thus the locations of the splices may be in ons which are very difficult or ise very expensive or dangerous to physically reach, or virtually impossible for a lineman to ally access to remove the sleeves and liners. Thus it is intended to be within the scope of the present invention that the sleeve and liner ements bed herein may be installed without necessarily being easily removable from the splice, and thus more permanent means for holding the encasing of the sleeves and liners about the splices may be employed.

As seen in s 29 and 30, in embodiments employing multiple sleeves, such as the pair of sleeves 32, 33, tethers 48 may be mounted across a span 2a of liner 2 extending between the sleeves. Tethers 48 may be lengths of flexible wire for example which are riveted or otherwise fastened at their ends to the pair of sleeves on either end of span 2a. Tethers 48 serve to hold in place the sleeves and ponding sections of liner 2 sandwiched between the sleeves and splice 18. Thus for e in the event that liner 2 fails in tension along its longitudinal axis A, for example span 2a splits while being pulled around a forced curvature in the conductor stringing travel path, tethers 48 will hold the sleeves and liner in place.

This detailed description of the present devices and s is used to illustrate certain embodiments of the present teaching. It will be nt to a person skilled in the art that various modifications can be made and various alternate embodiments may be utilized without departing from the scope of the present ation, which is limited only by the appended claims.

Claims (56)

Claims 1.

1. A device for protecting a permanent cable splice and the ends of a pair of electrical ission cables held in the splice during installation of the electrical transmission 5 cables along a travel path which es a forced ure of the , and wherein the splice is rigid and has opposite ends so as to form a junction at each of the opposite ends of the splice between the splice and the corresponding exposed ends of the cables, the device comprising an elongate, hollow, resilient liner and an elongate sleeve, wherein the liner is longer than the sleeve, and the sleeve is adapted to be snugly mounted over 10 and along the liner, inset along the liner from at least one end of the liner and over at least one on when the liner is mounted over a cable splice so as to position the cable splice within a hollow cavity in said liner, wherein, when the liner and the sleeve are so mounted on the cable splice, the sleeve compresses the liner against the cable splice at the corresponding junction whereby a stress concentration at the junction upon 15 a g of the cables relative to the splice during the forced curvature of the cables is distributed away from the junction.

2. The device of claim 1 wherein said one or more sleeves are rigid.

3. The device of claim 2 wherein said one or more s is a single sleeve.

4. The device of claim 1 wherein said liner has tapered ends at opposite ends thereof. 20

5. The device of claim 4 further comprising at least one stiffener mounted in said liner so as to extend along said liner and over at least said opposite ends of said cable splice when mounted thereon.

6. The device of claim 5 wherein said at least one stiffener extends over said junctions.

7. The device of claim 5 wherein said at least one stiffener is chosen from the group 25 comprising: a rod, a plurality of rods, a plurality of rods in radially spaced apart array about a longitudinal axis of said liner, a split pipe, a half-pipe, a stringer.

8. The device of claim 1 wherein said one or more liners and said one or more sleeves are adapted to be removable from the cable splice when mounted n.

9. The device of claim 1 wherein said one or more sleeves are a pair of sleeves mounted spaced apart along said liner. 5

10. The device of claim 9 wherein said one or more liners is a single liner.

11. The device of claim 10 further comprising at least one tether tethered to each of said pair of sleeves so as to join by said at least one tether each sleeve to the other of said pair of sleeves when mounted on said liner.

12. The device of claim 11 wherein said at least one tether is flexible. 10

13. The device of claim 1 wherein said one or more liners each include at least one r recess formed therein shaped and sized to receive mounted therein said one or more sleeves.

14. The device of claim 13 wherein said sleeves are mounted substantially flush with an outer surface of said liner when mounted in corresponding said recesses.

15 15. The device of claim 7 wherein each said at least one stiffener is elongate and substantially linear.

16. The device of claim 15 wherein at least one end of said at least one stiffener includes a curved end curved over said junction.

17. The device of claim 16 wherein said curved end s from said junction so as to lie 20 substantially flush onto the cable when said at least one liner and sleeve are mounted onto the cable splice and .

18. The device of claim 17 wherein each one of said at least one stiffener has said curved end.

19. The device of claim 8 wherein said liner includes a pair of opposed-facing half-pipes mountable to each other in opposed-facing on so as to define an elongate hollow cavity therethrough when so mounted.

20. An apparatus for protecting an electrical conductor having a permanent cable splice, the 5 apparatus comprising: an elongate resilient liner defining a udinal through hole and a first ferential groove; a first sleeve that resides within said first circumferential groove and around a circumference of said liner; 10 and a first taper located at a first end of said liner, wherein said first taper has a base end which abuts said first sleeve.

21. The apparatus of claim 20 wherein said liner is substantially cylindrical.

22. The apparatus of claim 21, n said liner is a pair of opposed-facing half-pipes mountable to each other in opposed-facing relation so as to define said longitudinal 15 through hole when so mounted.

23. The apparatus of claim 20, wherein said liner has a second circumferential , spaced from said first circumferential groove along said liner, and further comprises a second sleeve, and wherein said second sleeve resides in said second circumferential groove. 20

24. The apparatus of claim 20, further comprising a second taper located at a second end of said liner opposite said first end, wherein a base end of said second taper abuts said first sleeve.

25. The apparatus of claim 23, r comprising a second taper located at a second end of said liner opposite said first end, wherein a base end of said second taper abuts said 25 second sleeve so that said first and second tapers are tely disposed.

26. The apparatus of claim 20, wherein said liner is longer than said first sleeve.

27. The tus of claim 23, wherein said liner is a pair of liners and wherein each liner of said pair of liners is longer than any one of said first sleeve or said second sleeve.

28. The tus of claim 23, wherein said liner is longer than combined lengths of said first and second s. 5

29. The apparatus of claim 24, wherein said sleeve is mounted over and along said liner so as to contact said liner and said base ends of said first and second .

30. The apparatus of claim 20, wherein said cable splice is located within said through hole of said liner, wherein when said liner and said sleeve are mounted on said cable splice, said sleeve compresses said liner against said cable splice. 10

31. The apparatus of claim 23, wherein, said first sleeve, and said second sleeve are rigid.

32. The apparatus of claim 20, wherein said through hole is d for mounting over said cable splice on the electrical conductor, said liner further comprising at least one separate stiffener part mounted in said liner so as to extend along said liner and over at least opposite ends of the electrical conductor when the opposite ends of the electrical 15 conductor are mounted in said cable splice and when said liner is mounted on the cable splice.

33. The apparatus of claim 32, wherein said at least one separate stiffener part is chosen from said group comprising: a rod, a plurality of rods, a plurality of rods in radially spaced apart array about a udinal axis of said liner, a split pipe, a half-pipe, a stringer. 20

34. The apparatus of claim 32, wherein each said at least one separate stiffener part is elongate and substantially linear.

35. A system for protecting a permanent cable splice and the ends of a pair of electrical ission cables held in the splice during installation of the electrical ission cables along a travel path which includes a forced curvature of the cables, the system 25 comprising a rigid cable splice having opposite ends so as to form a junction at each of the opposite ends of the splice between the splice and a corresponding exposed end of the cables held in the splice, one or more ent liners sized to both snugly mount over at least the opposite ends of the cable splice and over the junctions and over at least a n of the exposed ends of cables where the exposed ends of the cables extend from the junctions, and one or more removable sleeves mountable over at least 5 a portion of each of the one or more liners and positioned on the one or more liners so as to cover the corresponding junctions, wherein the one or more sleeves compress their corresponding liners against the cable splice at a corresponding junction y a stress concentration at the corresponding junction is distributed from the junction upon a bending of the cables relative to the splice during the forced curvature of the 10 .

36. The system of claim 35 wherein said one or more sleeves are rigid.

37. The system of claim 36 wherein said one or more sleeves is a single sleeve.

38. The system of claim 35 wherein said liner has tapered ends at opposite ends thereof.

39. The system of claim 38 further comprising at least one ner mounted in said liner so 15 as to extend along said liner and over at least said opposite ends of said cable splice when mounted n.

40. The system of claim 39 wherein said at least one stiffener s over said junctions.

41. The system of claim 39 wherein said at least one stiffener is chosen from the group comprising: a rod, a plurality of rods, a plurality of rods in radially spaced apart array 20 about a longitudinal axis of said liner, a split pipe, a half-pipe, a stringer.

42. The system of claim 35 wherein said one or more liners and said one or more sleeves are adapted to be removable from the cable splice when mounted thereon.

43. The system of claim 35 wherein said one or more sleeves are a pair of sleeves mounted spaced apart along said liner. 25

44. The system of claim 43 wherein said one or more liners is a single liner.

45. The system of claim 35 further comprising at least one tether tethered to each of said pair of sleeves so as to join by said at least one tether each sleeve to the other of said pair of sleeves when mounted on said liner.

46. The system of claim 45 wherein said at least one tether is flexible. 5

47. The system of claim 35 wherein said one or more liners each include at least one annular recess formed therein shaped and sized to receive mounted therein said one or more sleeves.

48. The system of claim 47 wherein said sleeves are mounted ntially flush with an outer e of said liner when mounted in corresponding said recesses. 10

49. The system of claim 41 wherein each said at least one stiffener is elongate and substantially linear.

50. The system of claim 49 wherein at least one end of said at least one stiffener includes a curved end curved over said on.

51. The system of claim 50 wherein said curved end extends from said junction so as to lie 15 substantially flush onto the cable when said at least one liner and sleeve are mounted onto the cable splice and cables.

52. The system of claim 51 wherein each one of said at least one stiffener has said curved end.

53. The system of claim 42 n said liner includes a pair of opposed-facing half-pipes 20 mountable to each other in d-facing relation so as to define an te hollow cavity therethrough when so mounted.

54. The device of claim 1 substantially as herein described with reference to figures 1 – 30 and/or examples.

55. The apparatus of claim 20 substantially as herein described with reference to figures 1 – 25 30 and/or examples.

56. The system of claim 35 substantially as herein described with reference to s 1 – 30 and/or examples.