Anti-rotation device for cable stringing

The invention claimed is: 1. A process for producing an anti-rotation device to resist twisting of a cable or wire as it is strung through a transmission/distribution network and over a sheave in the transmission/distribution network, said device comprising a tow component having at least one tail storage channel formed therein and connectable to the cable or wire at one end, and at least one tail component suspended from the tow component, wherein the at least tail component includes weighted tail sections removably connected end-to-end to one another and at least one electrically insulated tail section pivotally mounted end-to-end to the weighted tail sections between the tow component and the weighted tail sections, and positioned along the tow component so that the at least one tail component is completely nested in and along the at least one tail storage channel as the tow component and the at least one tail component are pulled through the sheave during the stringing of the cable, wherein said device is produced the process comprising: a) determining a peak rotational force twisting moment of the cable or wire as it is strung through the transmission/distribution network; b) determining a length and distributed weight requirement for the at least one tail component to produce a counter-moment, substantially more than or equal to and counter to the peak rotational force twisting moment of the cable or wire; c) providing (i) a number of the weighted tail sections determined to meet the length and distributed weight requirement of the at least one tail component, wherein the length requirement of the at least one tail component is constrained by the length of the at least one tail storage channel which extends between adjacent tail components of the at least one tail component mounted on the tow component, and the width is constrained by the width of the at least one tail storage channel, wherein the constrained length and width of the least one tail component, and the material and hence weight of each weighted tail section is determined by the distributed weight requirement to produce the required counter-moment produced by the at least one tail component, and wherein the weighted tail sections are adapted for end-to-end connection to one another, and (ii) the at least one electrically insulated tail channel adapted for end-to-end connection to the weighted tail sections, wherein the at least one electrically insulated tail section is of a lower density than the weighted tail sections and is comprised of materials selected from the group of dielectric compositions which include plastics, fibreglass, ceramic, aramid fibres, and d) connecting the weighted tail sections and the at least one electrically insulated tail section so as to form the at least one tail component, and connecting the at least one tail component to the tow component, wherein the pivotal end-to-end mounting between the weighted tail sections and the at least one electrically insulated tail section is configured to constrain articulation of the at least one tail component to solely within a single plane of bending of the tow component to thereby cause the at least one tail component to remain aligned with the tow component and the at least one tail storage channel during the pulling through the sheave. 2. The process of claim 1 , wherein the tow component is comprised of a plurality of tow sections, releasably and pivotally connected to one another, and constrained by hinged connections for rotation relative to one another only in the single plane of bending of the tow component, and wherein the at least one tail component is a plurality of tail components, spaced apart in a spaced array along the tow component, each of the tail components of the plurality of tail components constrained by hinged connections between the weighted tail sections and the at least one electrically insulated tail section for rotation relative to one another and to the tow component only in the single plane of bending. 3. The process of claim 1 , wherein the at least one electrically insulated tail section is located immediately adjacent and adjoined to the tow component. 4. The process of claim 1 , wherein the at least one electrically insulated tail section has a cumulative insulated length and the weighted tail sections have a cumulative weighted length, and wherein the ratio of cumulative insulated length to cumulative weighted length is 4:1. 5. The process of claim 1 , further comprising connecting a dog leg connector between the at least one electrically insulated tail section and the tow component. 6. An anti-rotation device for resisting rotational twisting of a cable or wire as it is strung in a stringing direction, from an upstream end to a downstream end, through a transmission/distribution network and over a sheave in the transmission/distribution network, the device comprising: a) a tow component adapted to be connected to the cable or wire wherein the tow component includes a plurality of tow sections; and b) a plurality of elongate tail components suspended from and pivotally mounted to the tow component in a spaced apart array along the tow component, for pivotal rotation of the plurality of elongate tail components between a suspended position, suspended below the tow component, and a pivoted position flush along the tow component, wherein each of the tail components includes: (i) at least one weighted tail section; and (ii) at least one electrically insulated tail section connected end-to-end to the at least one weighted tail section, between the at least one weighted tail section and the tow component, wherein the at least one electrically insulated tail section is of a lower density than the at least one weighted tail section and is comprised of materials selected from the group of dielectric compositions which include plastics, fibreglass, ceramic, aramid fibres; and wherein the tail components are spaced along the tow component such that a first length of the tow component between adjacent first and second tail components is at least equal in length to a length of the first tail component, and wherein the first tail component is adapted to be downstream of the second tail component in the stringing direction, and wherein each tow section of the plurality of tow sections has a storage channel formed along the undersides thereof so as to collectively form a linear tail storage channel having a width and a length under and along the tow component, and wherein the width of each tail component is constrainable by the width of the storage channel extending between the adjacent first and second tail components so that the first tail component is snugly received in the storage channel as the tow component and first tail component pass over the sheave, and wherein the constrained length and width of each tail component, and the material of each tail component determines its weight distribution and the amount of counter-moment produced by each tail component, and wherein the spaced apart array of tail components are adapted to provide a counter-moment, counter to the rotational twisting of the cable or wire, and wherein the end-to-end connection between the at least one weighted tail section and the at least one electrically insulated tail section is configured to constrain articulation of each of the tail components to solely within a single plane of bending of the tow component to thereby cause each of the tail components to remain aligned with the tow component and the tail storage channel during the pulling through the sheave. 7. The anti-rotation device of claim 6 , wherein the plurality of tow sections are releasably and pivotally connected end-to-end to one another for rotation relative to one another only