ITRM20120508A1 - SLEEVE WITH VARIABLE GEOMETRY FOR COATING TERMINALS FOR CABLES FOR THE TRANSPORT AND DISTRIBUTION OF MEDIUM AND HIGH VOLTAGE ELECTRIC ENERGY ON OUTDOOR AIR LINES. - Google Patents

Description

DESCRIPTION

The present invention refers to a covering sleeve for cable terminals for the transport and distribution of medium and high voltage electrical energy on outdoor overhead lines.

More specifically, the invention refers to the structure of a sleeve, to be mounted on the terminal of an outdoor electric cable, configured in such a way that, when subjected to atmospheric agents (wind, ice, rain, fog, pollution), does not undergo permanent deterioration that would affect its functional characteristics.

The sleeves for terminals of medium and high voltage electric cables are manufactured products composed of elastomeric, thermoplastic, glass, porcelain, etc. materials, having geometric characteristics similar to a solid of revolution.

The termination must resist the same electrical stress as the cable and, for the so-called â € œout doorâ € versions, also withstand atmospheric agents.

One of the materials, for example polymers, often used as a coating is silicone rubber which has the important characteristic of being hydrophobic.

On a hydrophobic surface, water is found in the form of drops spaced apart.

Hydrophobicity is a very appreciated property because it improves the behavior of the insulation against pollution.

On a surface devoid of hydrophobicity, the water wets the entire surface which, together with contaminating elements, forms a conductive layer.

High voltage insulators are subjected to electrical stresses which vary in relation to atmospheric conditions and the place where they are installed.

Pollution conditions can vary widely from one place to another, depending on the characteristics of the region under consideration.

The designer tends to use the most suitable material combined with the geometric shape to have the best performance against atmospheric agents, in relation to the region of use.

Maintenance of the isolators is necessary to prevent problems due to pollution. This generally involves cleaning the outer surface of the terminal insulation, for example, by using high-pressure washing water.

The main cause of flashover (a phenomenon that involves the initiation and propagation of a surface electric discharge in the medium surrounding an insulating structure, placed between two metal walls under tension) in high voltage insulators is the presence of pollutants in the ™ atmosphere, with a significant impact on the reliability of the electricity supply system.

The accumulation of contaminants on the surface of the insulator transforms the layer of contaminants deposited on the surface of the insulator into a conductive film, thus allowing a current to flow through it.

The deterioration of the performance of external insulation, under the stress of the rated voltage, therefore facilitates the conditions of passage of current as a consequence of a decrease in the resistance of the insulating surface.

The passage of current on the surface of the insulators can lead to corrosion and erosion of the insulation, with consequent deterioration of operation.

The terminals have different shapes which also take into account the environmental conditions of installation.

Traditional outdoor terminals are generally characterized by a cylindrical shaft with the addition of â € œcampanatureâ €; the finning or camber is used in practice to increase the shorter surface distance between the point under tension and the mass.

A problem with said terminals constituted by cambering is that, in conditions of low temperature, the formation of ice is uncontrolled and present in a massive and random way on the edge of the bells.

It is evident that the massive presence of ice involves problems of passage of eddy electric currents and problems of a structural nature.

In other embodiments, the terminal has a truncated cone-shaped shaft with the addition of a helical thread that develops without interruption for the entire height of the product.

The object of the present invention is to provide a covering sleeve for cable terminations for electric lines having a particular geometry capable of improving its behavior against atmospheric agents.

Said sleeve for terminals has optimal characteristics against atmospheric agents thanks to the maximum design flexibility offered in appropriately choosing a conformation with independent modules, having different geometry and location.

The use of appropriate geometric solutions also allows the terminal to have, when hit by masses of moving air produced by the wind, limited areas of fluid stagnation, thus reducing the areas subject to accumulation of solid polluting particles present in the atmosphere .

The reduction of these accumulation areas therefore avoids the creation of conductive layers on the surface of the insulation which favor the passage of eddy electric currents which, by producing surface electric discharges, determine the erosion of the insulating substrate. Furthermore, the particular shape of the sleeve means that, in conditions of low temperature, the formation of ice stalactites occurs only in certain points (at the extremity of the fillet sections).

The specified purposes are substantially achieved by the covering sleeve for terminals of electric cables according to the present invention, the characteristics of which are set out in the attached claims.

Further characteristics and advantages of the present invention will become clearer from the detailed description of a preferred but not exclusive embodiment of the sleeve, illustrated in the attached drawings which respectively describe:

figure 1 - an axonometric view of the sleeve, with a corrugated core, made up of five pairs of symmetrical modules with variable geometry specularly arranged from the ends to the median zone;

figure 2 - a side view of the sleeve of figure 1;

figure 3 - the longitudinal section of the sleeve of previous figures;

figure 4 - an isometric, side (a), cross section (b) and longitudinal section (c) view of one of the two modules, with a corrugated surface, located at each of the two ends of the sleeve;

figure 5 - an isometric, side (a), front (b) and longitudinal section (c) view of one of the two modules, with discontinuous projections, adjacent to each of the two modules of figure 4;

Figure 6 - an axonometric, lateral (a), front (b) and longitudinal section (c) view of one of the two modules, with four successive threads, adjacent to each of the two modules of Figure 5;

figure 7 - an axonometric, side (a), front (b) and longitudinal section (c) view of one of the two modules, with six threads, interposed between one of the two modules of figure 6 and one of the two central modules of the sleeve ;

figure 8 - an isometric, side (a), front (b) and longitudinal section (c) view of one of the two central modules of the sleeve;

figure 9 - a side view of another execution of the sleeve according to the previous figures, provided with an uncorrugated core;

figure 10 - a side view of the sleeve of figure 9, before the assembly of the intermediate modules, ie provided only with the end modules;

figure 11 - representation of the flow of a fluid acting transversely on the module of an article having a geometry according to the known technique:

to. fluid dynamic scheme,

b. speed range,

c. detail of the speed field;

figure 12 - representation of the flow of a fluid acting transversely on the two-start helical thread module of a variable geometry product according to the present invention:

to. fluid dynamic scheme,

b. speed range,

c. detail of the speed field.

The variable geometry sleeve according to the present invention is composed of several independent contiguous modules, assembled together with a relative rotation with respect to the axis of the product.

Each module is characterized by a preferably corrugated cylindrical surface (core) on which a helical thread develops with possibly corrugated thread faces. The thread in turn is made up of one or more threads (principles) each having an external diameter that can be different between one thread and another; furthermore, the fillets can be almost continuous in the module or interrupted at intervals.

Another type of module can have projections obtained as a solid of revolution having a generating surface with cusps.

The projections are not continuous but are obtained by removing several portions from the solid, each at an appropriate angle, offset from each other in a complementary manner.

More in detail, the terminal illustrated in a preferred embodiment in the overall views of figures 1, 2 and 3, is composed of five pairs of modules of various geometry which form the entire product.

The module 1, located at each of the two ends of the sleeve, illustrated in the different views of figure 4, does not have a helical thread but is characterized by a surface 1.1 that is corrugated in its longitudinal direction.

The module 2, shown in axonometry, front, side and longitudinal section view in Figure 5, has instead two projections 2.1, 2.2 obtained as a solid of revolution having a generating surface with two cusps; the projections, of identical diameter and perimetrically corrugated, are not continuous but are obtained by removing from the solid two portions each of 90 ° and offset from each other in a complementary manner.

In another version of the module, the perimeter of the ridges is smooth.

Each of the two modules 2, with discontinuous projections, are contiguous to said corrugated modules 1, and have a core 2.3 with a corrugated surface.

The module 3 adjacent to the module 2, illustrated in the views of figure 6, has a thread made up of four threads (start) 3.1, interrupted in pieces; the core 3.2 of the module has a corrugated surface.

In another execution, said module 3 has six threads (principles), interrupted at intervals.

Module 4, illustrated in the preferred embodiment of figure 7, has a thread made up of six threads (start) interrupted in sections having different diameters: three threads 4.1 of greater diameter, the other three 4.2 of smaller diameter respectively interleaved.

The core of module 4 has a corrugated surface.

In another execution, said module 4 has six threads (start), interrupted at intervals, having further different diameters three by three equal but interspersed with each other.

A pair of modules is arranged centrally to the sleeve, each one illustrated in the different views of figure 8, characterized by a thread with two threads (principles) 5.1, 5.2, each having a different external diameter, and with corrugated thread faces; the core 5.3 has a corrugated surface.

Figure 9 shows a side view of another execution of the sleeve according to the previous figures, however, provided with a smooth or non-corrugated core, while figure 10 shows a side view of it, before assembling the modules intermediate, or provided only with the end modules.

The variable geometry of the sleeve according to the present invention, and various other geometries obtained by means of different combinations in the arrangement of the modules described, therefore allows an improvement of the air flow that invests it by limiting the areas of fluid stagnation in order to limit the deposit of polluting substances.

In this regard, numerical simulations of the fluodynamic phenomenon applied to some geometries of the present invention and to geometry of known technique have been carried out.

In all the models a suitable parallelepiped of fluid has been considered that surrounds the geometry of the artifact, subjected to a pressure applied to a face (input).

From the results of the simulations, it is possible to identify the areas with the best washing air flow (high speed and direction concordant with that of the air flow) and the areas where the fluid is more stagnant (low speed and direction contrary to that of the air flow). In all the output representations shown, for greater clarity of exposure, the velocity field has been represented in a vectorial manner (direction and direction) and the intensity is given by the coloring of the individual vectors according to a legend in the figure.

The models examined are the following:

A. module of an artifact with camber and geometric characteristics according to the known technique; cross wind direction.

B. module of a product with a two-start helical thread geometry according to the present invention; cross wind direction.

Figure 11 is a representation of the flow of a fluid acting on model A having a known geometry: in the leeward part, areas of fluid stagnation are evident both in correspondence with the stem (unavoidable phenomenon) and in correspondence with the bell. It follows that the whole longitudinal portion of the product does not receive adequate washing downwind.

Figure 12 is a representation of the flow of a fluid acting on model B having a known geometry: there are, in the leeward part, areas of fluid stagnation only in correspondence with the stem (unavoidable phenomenon) but not in correspondence with the thread. It follows that most of the longitudinal portion of the product receives adequate washing downwind.

The present invention has been illustrated with reference to some preferred embodiments of variable geometry modules of a sheathing sleeve for cable terminals for the transport and distribution of medium and high voltage electrical energy on outdoor overhead lines.

All the geometric details of the modules, as well as the dimensions, can be replaced by other technically equivalent geometric elements as long as they are applicable to a variable geometry sleeve, to be mounted on the terminal of an outdoor electric cable, and falling within the scope of the inventive concept which characterizes the present invention.

Claims (7)

CLAIMS 1. â € œSleeve with variable geometry for the coating of cable terminals for the transport and distribution of medium and high voltage electricity on outdoor overhead linesâ € including a cylindrical shaft characterized by assembly, by means of a relative rotation with respect to the axis of the sleeve, of at least one independent module consisting of a cylindrical surface on which at least one helical thread develops. 2. Variable geometry sleeve as per claim 1 characterized by the assembly, by means of a relative rotation with respect to the axis of the sleeve, of at least one independent module consisting of a cylindrical surface on which protrusions are developed obtained by removing one or more portions from a solid of revolution having a generating surface with cusps, said projections having an appropriate angle and being mutually offset in a complementary manner. 3. Variable geometry sleeve characterized by the assembly of two or more contiguous independent modules as per claims 1 and 2 according to various geometries obtained by means of different combinations of single or alternatively coupled and symmetrically arranged modules. 4. Variable geometry sleeve according to the preceding claims characterized in that the cylindrical surface of each module is smooth or alternatively corrugated. 5. Variable geometry sleeve according to claim 1 characterized by one or more threads, continuous or broken in pieces, with axial development having a constant or alternatively variable external diameter. 6. Variable geometry sleeve according to claim 2 characterized by one or more projections, continuous or interrupted at intervals, with axial development having a constant or alternatively variable external diameter. 7. Variable geometry sleeve according to claims 1, 2, 5 and 6 characterized in that the faces of the thread and of the projections are smooth or alternatively corrugated.