IT201800003942U1 - Construction System Relating to a Through Insulator - Google Patents

Description

DESCRIPTION of the invention having as title:

"Construction System Relating to a Through Insulator"

Field of Invention

The present invention relates to a constructive system relating to a bushing insulator, preferably indicated for electrical transformers, electrical substations and other similar structures, suitable for detecting the electric field generated by the voltage connection bar of the bushing insulator, for the purpose, for example, to be able to determine the voltage value of the same connecting bar in relation to the detected electric field.

More particularly, the present invention relates to a bushing insulator of the aforesaid type, suitable for detecting the electric field generated by the connecting bar without being affected by any surrounding electric fields, such as, for example, the fields generated by other conductors arranged in the vicinity. .

Background of the Invention

Construction systems of the aforesaid type afferent through insulators are currently known, but they have a series of drawbacks.

A first drawback is due to the fact that said known systems do not allow to detect the electric field generated by the connecting bar without being influenced by any surrounding fields.

A second drawback is due to the fact that said known systems have very large overall dimensions.

A third drawback is due to the fact that said known systems do not allow to obtain measurements of the electric field and / or quantities relating thereto with adequate levels of accuracy.

-A fourth drawback is due to the fact that said known systems are not immune to the surrounding electric fields generated, for example, by other conductors arranged nearby.

A fifth drawback is due to the fact that said known systems do not allow to obtain measurements of the electric field and / or quantities relating thereto with adequate levels of accuracy when the temperature varies.

_A sixth drawback is due to the fact that said known systems do not maintain over time the technical characteristics necessary to perform their function and / or to maintain the required safety level (partial discharges, detachments, rapid aging, etc.).

A seventh drawback is due to the fact that said known systems are laborious and expensive to produce.

An eighth drawback is due to the fact that in said known systems the resin of dielectric material arranged around the components of the system includes vacuoles (air bubbles) with consequent phenomena of undesirable partial discharges.

A ninth drawback is due to the fact that in said known systems the same resin is detached with respect to the elements that make up the capacitive sensor with consequent phenomena of undesirable partial discharges.

_A tenth drawback is due to the fact that in said known systems the aforementioned resin is not perfectly adherent and / or not perfectly gripped and / or constrained with respect to the components that form the system and, therefore, as a result of aging, detachments occur between said resin and said members, with consequent phenomena of unwanted partial discharges. -This drawback is particularly present when the system is used in an environment where the operating temperature (hot / cold) varies cyclically.

Exhibition of the Invention

The purpose of the present invention is therefore to solve the aforementioned drawbacks.

_The invention, which is characterized by the claims, solves the problem of creating a constructive system afferent to a through insulator, in which said system extends along a first longitudinal axis, in which said system comprises: _ a connecting bar which extends longitudinally along a respective second longitudinal axis; _a tubular body extending longitudinally along a third longitudinal axis; _a mass of dielectric material able to at least partially incorporate the components of the system; wherein said tubular body is positioned coaxially around said connecting bar; wherein said tubular body is radially spaced with respect to said central connecting bar; in which said system is characterized in that said tubular body comprises a first tubular section comprising: a first self-supporting tubular laminar element made of insulating material; a first thin layer of electrically conductive material applied to one or more internal faces of said first self-supporting tubular laminar element; a second thin thin layer of electrically conductive material applied to one or more external faces of said first self-supporting tubular laminar element; wherein said first self-supporting tubular laminar element is able to perform the function of support structure; wherein said first thin layer of electrically conductive material is adapted to perform the function of an electric field sensor; wherein said second thin thin layer of electrically conductive material is adapted to perform the function of electrical shield; wherein said system further comprises a second tubular section, wherein said second tubular section is positioned axially to the side of a first axial end of the first tubular section; and in which said second tubular section is adapted to perform the function of an electric screen.

Brief description of the Drawings

Further characteristics and advantages of the present invention will be more evident from the following description of some of its preferred practical embodiments, given here purely by way of non-limiting example, made with reference to the figures of the attached drawings in which:

Figure 1 schematically illustrates a first embodiment of the system object of the present invention;

Figure 1A schematically illustrates the flat development of the tubular body of the embodiment of Figure 1;

Figure 2 schematically illustrates a second embodiment of the system object of the present invention;

Figure 2A schematically illustrates the flat development of the tubular body of the embodiment of Figure 2;

Figure 3 schematically illustrates a third embodiment of the system object of the present invention;

Figure 3A schematically illustrates the tubular body of the embodiment of Figure 3 as a plane development;

Figure 4 schematically illustrates a fourth embodiment of the system object of the present invention;

Figure 4A schematically illustrates the flat development of the tubular body of the embodiment of Figure 4;

Figure 5 schematically illustrates a fifth embodiment of the system object of the present invention;

Figure 5A schematically illustrates the flat development of the tubular body of the embodiment of Figure 5.

Description of Some Preferred Forms of Realization

With reference to the attached figures 1 to 5, the construction system object of the present invention extends along a first longitudinal axis Y1 and substantially comprises: a connecting bar B which extends longitudinally along a respective second longitudinal axis Y2; a tubular body extending longitudinally along a third longitudinal axis Y3; a mass of dielectric material 40.1 / 40.2 / 40.3 / 40.4 / 40.5 able to at least partially incorporate the components of the system, in which said tubular body is positioned coaxially around said connecting bar B and also radially spaced with respect to said central bar B link.

_Also with reference to figures 1 to 5 attached hereto, said tubular body comprises a first tubular section 10.1 / 10.2 / 10.3 / 10.4 / 10.5 which substantially comprises: a first self-supporting tubular laminar element 11.1 / 11.2 / 11.3 / 11.4 / 11.5 made of insulating material; a first thin layer of electrically conductive material 12.1 / 12.2 / 12.3 / 12.4 / 12.5 applied to one or more internal faces of said first self-supporting tubular laminar element 11.1 / 11.2 / 11.3 / 11.4 / 11.5; a second thin layer of electrically conductive material 13.1 / 13.2 / 13.3 / 13.4 / 13.5 applied to one or more external faces of said first self-supporting tubular laminar element 11.1 / 11.2 / 11.3 / 11.4 / 11.5.

_the first self-supporting tubular laminar element 11.1 / 11.2 / 11.3 / 11.4 / 11.5 is able to perform the function of support structure and, more particularly, the function of tubular element capable of not undergoing deformations during the resin casting and support for layers of conductive material.

_the first thin thin layer of electrically conductive material 12.1 / 12.2 / 12.3 I 12.4 I 12.5 is able to perform the function of an electric field sensor and, more particularly, to form a first electrode for a capacitive coupling having the bar as a second electrode central B.

_the second thin thin layer of electrically conductive material (13.1 / 13.2 / 13.3 / 13.4 / 13.5) is able to perform the function of an electrical shield and, more particularly, by being connected to earth or to a known potential, an electrical shield able to shield the electric field sensor formed by the first thin thin layer of electrically conductive material 12.1 / 12.2 / 12.3 / 12.4 / 12.5.

With reference to the tubular body of the system, it can further comprise a second tubular section 20.1 / 20.2 / 20.3 / 20.4 / 20.5; wherein said second tubular section 20.1 / 20.2 / 20.3 / 20.4 / 20.5 is positioned axially to the side of a first axial end 10sx of the first tubular section 10.1 / 10.2 / 10.3 / 10.4 / 10.5; wherein said second tubular section 20.1 / 20.2 / 20.3 / 20.4 / 20.5 is adapted to perform the function of an electric shield, by means of its connection to earth or to a reference potential, as will be better understood hereinafter.

Still with reference to the tubular body of the system, it can also further comprise a third tubular section 30.1 / 30.2 / 30.3 / 30.4 / 30.5; wherein said third tubular section 30.1 / 30.2 / 30.3 / 30.4 / 30.5 is positioned axially to the side of a second axial end 10dx of the first tubular section 10.1 / 10.2 / 10.3 / 10.4 / 10.5; in which said third tubular section 30.1 / 30.2 / 30.3 / 30.4 / 30.5 is adapted to perform the function of an electric shield, by means of its connection to earth or to a reference potential, as will be better understood hereinafter.

_ Said second tubular section 20.1 / 20.2 / 20.3 / 20.4 / 20.5 and / or said third tubular section 30.1 / 30.2 / 30.3 / 30.4 / 30.5 can also perform the function of an electric field sensor, in order to detect the presence or non-presence of tension on the connecting bar B, as will be better understood later.

_ Again with reference to the attached figures, said second tubular section 20.1 / 20.2 / 20.3 / 20.4 / 20.5 and / or said third tubular section 30.1 / 30.2 / 30.3 / 30.4 / 30.5 are associated and / or constrained to said first tubular section 10.1 / 10.2 / 10.3 / 10.4 / 10.5.

_Preferably said first tubular section 10.1 / 10.2 / 10.3 / 10.4 / 10.5 and / or said second tubular section 20.1 / 20.2 / 20.3 / 20.4 / 20.5 and / or said third tubular section 30.1 / 30.2 / 30.3 / 30.4 / 30.5 comprises one or more first through openings 14.1 / 14.2 / 14.3 / 14.4 / 14.5 / 21.1 / 21.2 / 21.3 / 21.4 / 21.4 / 31.1 / 31.2 / 31.3 / 31.4 / 31.5, which have such a width as to allow a resin of dielectric material in its liquid / pasty state of passing through said first through openings 14.1 / 14.2 / 14.3 / 14.4 / 14.5; 21.1 / 21.2 / 21.3 / 21.4 / 21.5; 31.1 / 31.2 / 31.3 / 31.4 / 31.4 / 31.5.

_ With reference to figures 1 and 1A, said first tubular section 10.1 can be made by means of a double-sided conductive vetronite base (for example a copper-plated double-sided vetronite base - PCB) comprising a self-supporting sheet of insulating material 11.1 suitable for carrying out the supporting function, a first thin internal layer 12.1 of conductive material electrically disconnected with respect to the other layers of conductive material applied on said self-supporting sheet of insulating material 11.1 and a first thin external layer 13.1 of conductive material applied on said self-supporting sheet of insulating material 11.1 ; wherein the first thin inner layer 12.1 is adapted to perform the function of an electric field sensor, that is, to form a capacitive coupling with the bar B; and in which the first thin outer layer 13.1 is adapted to perform the function of an electrical shield, by means of, for example, its connection to earth.

Preferably, the first thin inner layer 12.1 of conductive material has an axial extension D1.1 lower than the axial extension D2.1 of the first thin outer layer 13.1 of conductive material and, preferably but not limitatively, as illustrated in Figure 1A.

_With reference to the aforementioned structural description, said first tubular section 10.1 is made by means of a single base of double-sided conductive vetronite (for example base of double-sided copper-plated vetronite - PCB), carved for example by photoengraving or mechanical milling and wound in the same manner of tubular. _ Again with reference to Figures 1 and 1A, said second tubular section 20.1 and / or said third tubular section 30.1 can be made by means of a metal mesh, preferably electrically disconnected with respect to other conductive elements, in which said metal mesh can be connected to earth in order to perform the function of electric shield, and in which, if desirable, said metal mesh can form a capacitive coupling with the bar B in order to be able to detect the presence or absence of voltage on the same bar B.

With reference to Figures 2 and 2A, said system and, more particularly said tubular body comprising said first, second and third tubular section, 20.2_10.2_30.2, can comprise: a self-supporting sheet of insulating material 23.2_11.2_33.2 suitable to perform the support function; a first thin inner layer 12.2 of conductive material electrically disconnected with respect to the other layers of conductive material applied on said self-supporting sheet of insulating material 23.2_11.2_33.2; a first thin outer layer 25.2 of conductive material applied on said self-supporting sheet of insulating material 23.2_11.2_33.2; a second thin outer layer 13.2 of conductive material applied on said self-supporting sheet of insulating material 23.2_11.2_33.2; a third thin outer layer 35.2 of conductive material applied on said self-supporting lamina of insulating material 23.2_11.2_33.2, in which said layers have certain axial extensions and, preferably but not limitatively, as illustrated in Figure 2A.

the first thin inner layer 12.2 is adapted to perform the function of an electric field sensor, that is, to form a capacitive coupling with the bar B; the first thin outer layer 25.2 is able to perform the function of electrical shield, for example by means of its connection to earth, and / or the function of detecting the presence or non-presence of voltage on the bar B; the second thin outer layer 13.2 is able to perform the function of an electrical shield, for example by means of its connection to earth; the third thin outer layer 35.2 is able to perform the function of electrical shield, for example by means of its connection to earth, and / or the function of detecting the presence or absence of voltage on the bar B.

_Preferably, with reference to the aforementioned structural description, said first tubular section 10.2, said second tubular section 20.2 and said third tubular section 30.2 are made by means of a single base of double-sided conductive glass (for example base of double-sided copper-plated glass - PCB) , carved for example by photoengraving or mechanical milling, and wound like a tubular.

With reference to Figures 3 and 3A, said system and, more particularly said tubular body comprising said first, second and third tubular section, 20.3_10.3_30.3, can comprise: a self-supporting sheet of insulating material 23.3_11.3_33.3 suitable to perform the function of support foil; a first thin inner layer 24.3 of conductive material applied on said self-supporting sheet of insulating material 23.3_11.3_33.3; a second thin inner layer 12.3 of conductive material electrically disconnected with respect to the other layers of conductive material applied on said self-supporting sheet of insulating material 23.3_11.3_33.3; a third thin inner layer 34.3 of conductive material applied on said self-supporting sheet of insulating material 23.3_11.3_33.3; a first thin outer layer 13.3 of conductive material applied on said self-supporting lamina of insulating material 23.3_11.3_33.3; in which said layers have certain axial extensions and, preferably but not limitatively, as illustrated in Figure 3A.

The first thin internal layer 24.3 is able to perform the function of an electrical shield, for example by means of its connection to earth, and / or the function of detecting the presence or absence of voltage on the bar B.

The second thin inner layer 12.3 is adapted to perform the function of an electric field sensor, that is to form a capacitive coupling with the bar B.

The third thin inner layer 34.3 of conductive material can perform the function of an electrical shield, for example by means of its connection to earth, and / or the function of detecting the presence or absence of voltage on the bar B.

The first thin outer layer 13.3 is able to perform the function of an electrical screen by, for example, connecting it to earth.

_Preferably, with reference to the aforementioned structural description, said first tubular section 10.3, said second tubular section 20.3 and said third tubular section 30.3 are made by means of a single conductive double-sided fiberglass base (for example copper-plated double-sided fiberglass base - PCB) , carved for example by photoengraving or mechanical milling, and wound like a tubular.

With reference to Figures 4_4A and 5_5A, the second tubular section 20.4 / 20.5 and / or said third tubular section 30.4 / 30.5 comprises one or more cantilevered tabs 22.4, 32.4 / 22.5, 32.5.

More particularly, with reference to Figures 4_4A and 5_5A, the construction system object of the present invention, in which said system extends along a first longitudinal axis Y1, in which said system comprises: a connecting bar B which extends longitudinally along a respective second longitudinal axis Y2; a tubular body extending longitudinally along a third longitudinal axis Y3; a mass of dielectric material 40.4 / 40.5 able to at least partially incorporate the components of the system; wherein said tubular body is positioned coaxially around said connecting bar B; in which said tubular body is radially spaced with respect to said central connecting bar B, it has a tubular body comprising one or more cantilevered tabs 22.4, 32.4 / 22.5, 32.5.

Said tongues 22.4, 32.4 / 22.5, 32.5 are preferably axially oriented Y4, in order to configure with their free ends 23.4, 33.4 / 23.5, 33.5 at least one axial end of said tubular body and thus configure axial ends having the shape of a battlements.

_Always preferably, two or more tabs 22.4, 32.4 / 22.5, 32.5 are provided, positioned side by side, side by side, in which the axial edge of a first tab 22.4 / 22.5 is spaced D4.4 / D4.5 circumferentially with respect to the edge axial of a second tongue 22.4 / 22.5 positioned to the side of said first tongue 22.4 / 22.5, in order to form axial through openings 21.4 / 21.5.

With reference to said through openings 21.4 they have a width such as to allow a resin of dielectric material in its liquid / pasty state to pass through said first through openings 21.4.

_ Again preferably, said tabs 22.4, 32.4 / 22.5, 32.5 are flexible and, more particularly, have a degree of flexibility selected in relation to the shrinkage characteristics of the resin used for casting, in order to allow the same tabs to flex during the phases shrinkage of the resin that occur during the solidification of the same resin.

With reference to figures 4 and 4A, said system and, more particularly said tubular body comprising said first, second and third tubular section, 20.4_10.4_30.4, can comprise: a self-supporting sheet of insulating material 23.4_11.4_33.4 suitable to perform the support function; a first thin inner layer 12.4 of conductive material electrically disconnected with respect to the other layers of conductive material applied on said self-supporting sheet of insulating material 23.4_11.4_33.4; a first thin outer layer 25.4 of conductive material applied on said self-supporting sheet of insulating material 23.4_11.4_33.4; a second thin outer layer 13.4 of conductive material applied on said self-supporting lamina of insulating material 23.4_11.4_33.4; a third thin outer layer 35.4 of conductive material applied to said self-supporting sheet of insulating material 23.4_11.4_33.4.

The first thin inner layer 12.4 is adapted to perform the function of an electric field sensor, that is to form a capacitive coupling with the bar B.

The first thin outer layer 25.4 is able to perform the function of an electrical shield, for example by means of its connection to earth, and / or the function of detecting the presence or absence of voltage on the bar B.

The second thin outer layer 13.4 is able to perform the function of an electrical shield, for example by means of its connection to earth.

The third thin outer layer 35.4 is able to perform the function of an electrical shield, for example by means of its connection to earth, and / or the function of detecting the presence or absence of voltage on the bar B.

Preferably, with reference to the aforementioned structural description, said first tubular section 10.4, said second tubular section 20.4 and said third tubular section 30.4 are made by means of a single copper-plated double-sided vetronite base (PCB), carved for example by photoengraving or mechanical milling, and wrapped like a tubular.

With reference to figures 5 and 5A, said system and, more particularly said tubular body comprising said first, second and third tubular section, 20.5_10.5_30.5, can comprise: a self-supporting sheet of insulating material 23.5_11.5_33.5 suitable to perform the support function; a first thin outer layer 13.5 of conductive material applied on said self-supporting sheet of insulating material 23.5_11.5_33.5; a first thin internal layer 24.5 of conductive material applied on said self-supporting sheet of insulating material 23.5_11.5_33.5; a second thin inner layer 12.5 of conductive material applied to said self-supporting sheet of insulating material 23.5_11.5_33.5; and a third thin inner layer 34.5 of conductive material applied to said self-supporting lamina of insulating material 23.4_11.4_33.4.

The first thin outer layer 13.5 is able to perform the function of an electrical shield, for example by means of its connection to earth.

The first thin internal layer 24.5 is able to perform the function of an electrical shield, for example by means of its connection to earth, and / or the function of detecting the presence or absence of voltage on the bar B.

The second thin inner layer 12.5 is adapted to perform the function of an electric field sensor, that is to form a capacitive coupling with the bar B.

The third thin inner layer 34.5 can perform the function of an electrical shield, for example by means of its connection to earth, and / or the function of detecting the presence or absence of voltage on the bar B.

Preferably, with reference to the aforementioned structural description, said first tubular section 10.5, said second tubular section 20.5 and said third tubular section 30.5 are made by means of a single copper-plated double-sided vetronite base (PCB), carved for example by photoengraving or mechanical milling, and wrapped like a tubular.

The description of the construction system is given purely by way of non-limiting example and, therefore, all those modifications or variants suggested by practice and / or falling within the scope of the following claims can be applied to said system. _The following claims are also an integrative part of the above description.

Claims (1)

Claims 01) _Construction system afferent to a through insulator, in which said system extends along a first longitudinal axis (Y1), in which said system comprises: a connecting bar (B) extending longitudinally along a respective second longitudinal axis (Y2) ; a tubular body extending longitudinally along a third longitudinal axis (Y3); a mass of dielectric material (4.1 / 40.2 / 40.3 / 40.4 / 40.50) able to at least partially incorporate the components of the system; wherein said tubular body is positioned coaxially around said connecting bar (B); wherein said tubular body is radially spaced with respect to said central connecting bar (B); characterized in that said tubular body comprises a first tubular section (10.1 / 10.2 / 10.3 / 10.4 / 10.5) comprising: a first self-supporting tubular laminar element (11.1 / 11.2 / 11.3 / 11.4 / 11.5) made of insulating material; a first thin thin layer of electrically conductive material (12.1 / 12.2 / 12.3 / 12.4 / 12.5) applied to one or more internal faces of said first self-supporting tubular laminar element (11.1 / 11.2 / 11.3 / 11.4 / 11.5); a second thin thin layer of electrically conductive material (13.1 / 13.2 / 13.3 / 13.4 / 13.5) applied to one or more external faces of said first self-supporting tubular laminar element (11.1 / 11.2 / 11.3 / 11.4 / 11.5); due to the fact that said first self-supporting tubular laminar element (11.1 / 11.2 / 11.3 / 11.4 / 11.5) is able to perform the function of support structure; due to the fact that said first thin thin layer of electrically conductive material (12.1 / 12.2 / 12.3 / 12.4 / 12.5) is able to perform the function of an electric field sensor; due to the fact that said second thin layer of electrically conductive material (13.1 / 13.2 / 13.3 / 13.4 / 13.5) is able to perform the function of an electric screen; by further comprising a second tubular section (20.1 / 20.2 / 20.3 / 20.4 / 20.5); due to the fact that said second tubular section (20.1 / 20.2 / 20.3 / 20.4 / 20.5) is positioned axially to the side of a first axial end (10sx) of the first tubular section (10.1 / 10.2 / 10.3 / 10.4 / 10.5); and due to the fact that said second tubular section (20.1 / 20.2 / 20.3 / 20.4 / 20.5) is adapted to perform the function of an electric screen. 02) System according to claim 1, characterized in that it further comprises a third tubular section (30.1 / 30.2 / 30.3 / 30.4 / 30.5); due to the fact that said third tubular section (30.1 / 30.2 / 30.3 / 30.4 / 30.5) is positioned axially to the side of a second axial end (10dx) of the first tubular section (10.1 / 10.2 / 10.3 / 10.4 / 10.5); and due to the fact that said third tubular section (30.1 / 30.2 / 30.3 / 30.4 / 30.5) is adapted to perform the function of an electric screen. 03) _System according to claim 1 or 2, characterized in that said second tubular section (20.1 / 20.2 / 20.3 / 20.4 / 20.5) and / or said third tubular section (30.1 / 30.2 / 30.3 / 30.4 / 30.5) is suitable to perform the function of an electric field sensor able to detect the presence of voltage on the connecting bar (B). 04) _System according to claim 1 or 2, characterized in that said second tubular section (20.1 / 20.2 / 20.3 / 20.4 / 20.5) and / or said third tubular section (30.1 / 30.2 / 30.3 / 30.4 / 30.5) are associated to said first tubular section (10.1 / 10.2 / 10.3 / 10.4 / 10.5). 05) _System according to one of the preceding claims, characterized in that said first tubular section (10.1 / 10.2 / 10.3 / 10.4 / 10.5) and / or said second tubular section (20.1 / 20.2 / 20.3 / 20.4 / 20.5) and / or of said third tubular section (30.1 / 30.2 / 30.3 / 30.4 / 30.5) comprises one or more first through openings (14.1 / 14.2 / 14.3 / 14.4 / 14.5; 21.1 / 21.2 / 21.3 / 21.4 / 21.5; 31.1 / 31.2 / 31.3 / 31.4 / 31.4 / 31.5) and the fact that said first through openings (14.1 / 14.2 / 14.3 / 14.4 / 14.5; 21.1 / 21.2 / 21.3 / 21.4 / 21.5; 31.1 / 31.2 / 31.3 / 31.4 / 31.4 / 31.5) have a amplitude such as to allow a resin of dielectric material in its liquid / pasty state to pass through said first through openings (14.1 / 14.2 / 14.3 / 14.4 / 14.5; 21.1 / 21.2 / 21.3 / 21.4 / 21.5; 31.1 / 31.2 / 31.3 / 31.4 / 31.4 / 31.5). 06) - System according to one of claims 1 to 5, characterized in that said first tubular section (10.1) is made by means of a double-sided conductive fiberglass base (for example a copper-plated double-sided vetronite base - PCB). 07) System according to claim 7, characterized in that said second tubular section (20.1) and / or said third tubular section (30.1) are made by means of a metal mesh. 08) System according to one of claims 1 to 5, characterized in that it comprises: a self-supporting sheet of insulating material (23.2_11.2_33.2) adapted to perform the supporting function; a first thin inner layer (12.2) of conductive material electrically disconnected with respect to the other layers of conductive material applied on said self-supporting sheet of insulating material (23.2_11.2_33.2); a first thin outer layer (25.2) of conductive material applied on said self-supporting sheet of insulating material (23.2_11.2_33.2); a second thin outer layer (13.2) of conductive material applied on said self-supporting sheet of insulating material (23.2_11.2_33.2); and a third thin outer layer (35.2) of conductive material applied on said self-supporting sheet of insulating material (23.2_11.2_33.2). 09) _System according to claim 8, characterized in that the first thin inner layer (12.2) is able to perform the function of sensor of the electric field generated by the connecting bar (B), the first thin outer layer (25.2) is able to perform the function of electric shield, the second thin outer layer (13.2) is able to perform the function of electric shield; and the third thin outer layer (35.2) is able to perform the function of an electrical shield. 10) _System according to claim 8 or 9, characterized in that the first thin outer layer (25.2) and / or the third thin outer layer (35.2) is able to detect the presence or absence of voltage on the connecting bar (B ). 11) _System according to one of claims 8 to 10, characterized in that said first tubular section (10.2), said second tubular section (20.2) and said third tubular section (30.2) are made by means of a double-sided conductive fiberglass base (for example copper-plated double-sided vetronite base - PCB), System according to one of claims 1 to 5, characterized in that it comprises: a self-supporting sheet of insulating material (23.3_11.3_33.3) suitable to perform the function of support sheet; a first thin inner layer (24.3) of conductive material applied on said self-supporting sheet of insulating material (23.3_11.3_33.3); a second thin inner layer (12.3) of conductive material electrically disconnected with respect to the other layers of conductive material applied on said self-supporting sheet of insulating material (23.3_11.3_33.3); a third thin inner layer (33.3) of conductive material applied on said self-supporting sheet of insulating material (23.3_11.3_33.3); a first thin outer layer (13.3) of conductive material applied on said self-supporting sheet of insulating material (23.3_11.3_33.3). 13) _System according to claim 12, characterized in that the first thin inner layer (24.3) is able to perform the function of electrical shield, the second thin inner layer (12.3) is able to perform the function of sensor of the generated electric field from the connecting bar (B), the third thin inner layer (34.3) is able to perform the function of electric shield, the first thin outer layer (13.3) is able to perform the function of electric shield. 14) _System according to claim 12 or 13, characterized in that the first thin inner layer (24.3) and / or the third thin inner layer (34.3) is able to detect the presence or absence of voltage on the connecting bar (B ). System according to one of claims 12 to 14, characterized in that said first tubular section (10.3), said second tubular section (20.3) and said third tubular section (30.3) are made by means of a double-sided conductive glass base (for example copper-plated double-sided vetronite base - PCB), System according to one of claims 1 to 5, characterized in that said second tubular section (20.4 / 20.5) and / or said third tubular section (30.4 / 30.5) comprises one or more tabs (22.4, 32.4 / 22.5, 32.5) supported cantilevered. 17) .. Construction system afferent to a through insulator, in which said system extends along a first longitudinal axis (Y1), in which said system comprises: a connecting bar (B) extending longitudinally along a respective second longitudinal axis ( Y2); a tubular body extending longitudinally along a third longitudinal axis (Y3); a mass of dielectric material (40.4 / 40.5) able to at least partially incorporate the components of the system; wherein said tubular body is positioned coaxially around said connecting bar (B); wherein said tubular body is radially spaced with respect to said central connecting bar (B); characterized in that said tubular body comprises one or more cantilevered tabs (22.4, 32.4 / 22.5, 32.5). 18) _System according to claim 16 or 17, characterized in that said tabs (22.4, 32.4 / 22.5, 32.5) are axially oriented (Y4) in order to configure with their free ends (23.4, 33.4 / 23.5, 33.5) at least one axial end of the tubular body. 19) System according to claim 16 or 17, characterized in that it comprises two or more tabs (22.4_22.4, 32.4_32.4 / 22.5_22.5, 32.5_32.5) side by side. 20) System according to claim 19, characterized in that the axial edge of a first tab (22.4) is spaced (D4.4) circumferentially with respect to the axial edge of a second tab (22.4) positioned to the side of said first tab ( 22.4) in order to form axial through openings (21.4,). 21) A system according to claim 20, characterized in that said through openings (21.4) have a width such as to allow a resin of dielectric material in its liquid / pasty state to pass through said first through openings (21.4). 22) - System according to one of claims 16 to 21, characterized in that said tabs (22.4, 32.4 / 22.5, 32.5) are flexible. 23) _System according to claim 22, characterized in that said tabs (22.4, 32.4 / 22.5, 32.5) have a degree of flexibility selected in relation to the shrinkage characteristics of the resin used for casting, in order to allow the same tabs to flex during the resin shrinkage phases that occur during the solidification of the same resin. 24) A system according to one of claims 01 to 23, characterized in that at least one axial end of said tubular body has the shape of a battlement. 25) A system according to one of claims 16 to 24, characterized in that it comprises: a self-supporting sheet of insulating material (23.4_11.4_33.4) suitable to perform the supporting function; a first thin inner layer (12.4) of conductive material electrically disconnected with respect to the other layers of conductive material applied on said self-supporting sheet of insulating material (23.4_11.4_33.4); a first thin outer layer (25.4) of conductive material applied on said self-supporting sheet of insulating material (23.4_11.4_33.4); a second thin outer layer (13.4) of conductive material applied on said self-supporting sheet of insulating material (23.4_11.4_33.4); a third thin outer layer (35.4) of conductive material applied to said self-supporting sheet of insulating material (23.4_11.4_33.4). 26) _System according to claim 25, characterized in that the first thin inner layer (12.4) is able to detect the electric field generated by the connecting bar (B), the first thin outer layer (25.4) is able to perform the function of electric shield, the second thin outer layer (13.4) is able to perform the function of electric shield, the third thin outer layer (35.4) is able to perform the function of electric shield. 27) _System according to claim 25 or 26, characterized in that the first thin outer layer (25.4) is able to detect the presence or absence of voltage on the connecting bar (B), the third thin outer layer (35.4) it is possible to detect the presence or absence of voltage on the bar B. 28) - System according to one of claims 25 to 27, characterized in that said first tubular section (10.4), said second tubular section (20.4) and said third tubular section (30.4) are made by means of a single double-sided fiberglass base auburn. 29) A system according to one of claims 16 to 24, characterized in that it comprises: a self-supporting sheet of insulating material (23.5_11.5_33.5) suitable to perform the supporting function; a first thin outer layer (13.5) of conductive material applied on said self-supporting sheet of insulating material (23.5_11.5_33.5); a first thin inner layer (24.5) of conductive material applied on said self-supporting sheet of insulating material (23.5_11.5_33.5); a second thin inner layer (12.5) of conductive material applied on said self-supporting sheet of insulating material (23.5_11.5_33.5); a third thin inner layer (34.5) of conductive material applied on said self-supporting sheet of insulating material (23.4_11.4_33.4). 30) _System according to claim 29, characterized in that the first thin outer layer (13.5) is able to perform the function of an electrical shield, the first thin inner layer (24.5) is able to perform the function of an electrical shield, the second thin inner layer (12.5) is able to detect the electric field generated by the connecting bar B, the third thin inner layer 34.5 is able to perform the function of electric shield. 31) _System according to claim 29 or 30, characterized in that the first thin inner layer (24.5) and / or the third thin inner layer 34.5 is able to detect the presence or absence of voltage on the connecting bar (B) . 32) _System according to one of claims 29 to 31, characterized in that said first tubular section (10.5), said second tubular section (20.5) and said third tubular section (30.5) are made by means of a double-sided conductive fiberglass base (for example copper-plated double-sided vetronite base - PCB), 33) System according to one of the preceding claims and substantially as described and illustrated in the figures of the attached drawings and for the purposes specified above.