ITMI20102427A1 - ISOLATOR FOR ELECTRIC TRANSFORMERS, IN PARTICULAR POWER OR DISTRIBUTION TRANSFORMERS - Google Patents

Description

DESCRIPTION

Attached to a patent application for an INDUSTRIAL INVENTION PATENT entitled:

"ISOLATOR FOR ELECTRIC TRANSFORMERS, IN PARTICULAR POWER OR DISTRIBUTION TRANSFORMERS"

FIELD OF THE TROVATO

The present invention relates to an insulator for electrical power or distribution transformers.

By insulator, hereinafter we mean the assembly of the porcelain insulator (insulating element) with the active part (through or conducting body including bar and flange).

The invention is used in particular to allow the passage of electric energy without dispersion from a source (for example an electric line) to a transformer or vice versa. The present invention relates in detail to a bushing insulator for the transfer of low or medium voltage electrical energy to and from the electrical transformer.

In particular, the low voltage in the applications of interest can be considered included in a range from 1 to 5 kV, while the medium voltage can be considered in the range 10-52 kV.

As is known there are and are widely used bushing insulators for transformers capable of allowing the passage of electrical energy at a certain voltage / current value from an electrical line to the transformer and, once processed, from the transformer to an electrical network to a different voltage / current value.

These insulators perform the main function of insulating the conductor to avoid dispersion and loss of electrical power during the transfer.

A first example of such devices currently in use relates to transformer insulators used to transfer medium-high voltage current to or from the transformer. The latter consist of a first metal bar connected to the transformer and a second metal bar connected to the first and connected to the electrical network. The second bar, made by molding, has a flange positioned at one end and is equipped with an anti-rotation element; the flange has a threaded axial hole that allows the mutual constraint of the two bars by screwing a threaded end of the first bar into the axial threaded hole of the second. The second bar having the flange and the anti-rotation element constitutes a single solid body; the flange defines the axial abutment surface in a situation of engagement with the porcelain insulator and, at the same time, the anti-rotation element avoids relative movements between the bars and the insulator.

The known device described above generally has a poor operating flexibility linked to the structure of the bars and to the type of coupling mentioned above.

In fact, the second bar equipped with the flange defines the relative coupling position with the insulator and therefore determines, depending on the relative dimensions, the positioning of the entry portion of the bar itself, or the configuration of the area of engagement of the device with the external cable.

It is evident that insulators of non-standard dimensions or particular needs that impose modifications of the coupling configuration require the realization of at least a second bar with a different geometry (length), sometimes requiring the preparation of a new and different mold with a consequent increase in costs and production times.

In addition to the scarce flexibility, the product in use involves an expensive production process, in particular in that it requires a step of molding or melting at least one component of the metallic conductor.

A second example of transformer isolator in use today is an isolator used for low voltage voltage / current transfer. The latter consists of a suitable insulator, an axially shorter threaded bar, but with larger transversal dimensions, compared to that of the medium-high voltage pass-throughs, and a threaded ring nut. The ring nut is finally screwed onto the bar and acts as a relative positioning element of the insulating element (axial stop and anti-rotation stop). In this second example, the production process involves the creation of a mold or a shell for casting to define the ring nut, while the bar is made by extrusion and the threads by means of a process for material removal. This last production system sees a lowering of costs and a slightly greater flexibility of the product even if limited to low voltage energy transfers.

Although the invention described in the second example involves an optimization of the product and the manufacturing process, it does not find any useful application in the isolation and transfer of medium voltages due to the different geometries involved; moreover, the latter product could also require an additional welding step necessary to avoid, in working conditions, any rotations, and therefore unscrewing, of the ring nut from the bar.

SUMMARY OF THE INVENTION

A 1st aspect provides an insulator (1) for electrical transformers, in particular for power or distribution transformers, comprising:

at least one insulating element (2) having a through cavity (3) extending between an inlet (4) and an outlet (5),

a conducting body (9) comprising:

at least one conduction bar (10) arranged inside said through cavity (3) of said insulating element (2), said bar (10) extending along a prevalent development direction (12) and presenting an initial portion (13 ), a final portion (14) and an intermediate portion (15) connected with said initial (13) and final (14) portions, said initial (13) and final (14) portions being respectively at said outlet (5) and of said inlet (4), said bar (10) comprising at least one coupling area (16) arranged on said intermediate portion (15),

at least one flange (11) comprising a seat (17) configured to engage with said coupling area (16), said flange (11) having an upper surface (18) and a lower surface (19), said seat (17) extending from said upper surface (18) to said lower surface (19) along a development axis (20) which in engagement conditions is aligned with the prevailing development direction (12) of said bar (10), characterized in that the seat (17) has, in a transverse section with respect to the axis of development (20), a bulkiness greater than that of the transverse section of at least one of said portions (13, 14, 15) of said bar (10).

A 2nd aspect in accordance with the 1st provides an insulator according to claim 1, in which said flange (11) is configured to engage with said coupling area (16) through a transverse movement to the prevailing development direction (12) of said bar (10).

A 3rd aspect in accordance with the previous one provides for an insulator, in which said flange (11) is configured to engage with said coupling area (16) through a first positioning step in which the flange (11) is movable relative to the bar (10) by axial sliding along the prevailing development direction (12) of said bar (10), said seat (17) of said flange (11) being configured to pass through said initial portion (13) and said intermediate portion (15) until in correspondence with the coupling area (16) of said bar (10), and a subsequent coupling step between the flange (11) and the bar (10) which occurs with motion transversal to the prevailing direction of development (12) of said bar (10).

A 4th aspect in accordance with the 1st provides an insulator, in which said flange (11) is configured to engage with said coupling area (16) by means of an exclusively axial movement along the prevailing development direction (12) of said bar (10).

A 5th aspect in accordance with any of the preceding aspects provides for an insulator, in which said bar (10) has an axial abutment surface (21) located in correspondence with the coupling area (16), the seat (17) comprising a coupling portion (22) provided with a corresponding abutment surface (23) adapted to abut the axial abutment surface (21) of the bar (10) in conditions of engagement of the bar (10) and flange (11).

A 6th aspect in accordance with the previous one provides for an insulator, in which said bar (10) has an auxiliary axial abutment surface (24) placed in correspondence with the coupling area (16) and axially opposite to the axial abutment surface (21). ), the coupling portion (22) of the seat (17) being provided with a corresponding auxiliary abutment surface (25) adapted to abut the auxiliary axial abutment surface (24) of the bar (10) in conditions of bar engagement ( 10) and flange (11).

A 7th aspect in accordance with the 5th aspect provides an insulator, in which the axial abutment surface (21) of the bar (10) and the axial abutment surface (23) of the coupling portion (22) of the seat (17 ) are configured to allow relative sliding transversal to the prevailing development axis (12) of the bar (10).

An 8th aspect according to any one of the preceding aspects provides for an insulator, in which the intermediate portion (15) of the bar (10) has a circular cross-section, and in which the coupling area (16) has at least one recess (26) adapted to receive a portion of said seat (17).

A 9th aspect according to the previous aspect provides for an insulator, in which said recess (26) is delimited by an axial abutment surface (21), by a connection surface (27) emerging from the axial abutment surface (21) and an auxiliary axial abutment surface (24) emerging from the connecting surface (27) and facing the axial abutment surface (21).

A 10th aspect according to the previous aspect provides for an insulator, in which the seat (17) of the flange (11) comprises a coupling portion (22) having an axial abutment surface (23), a connection surface (28) emerging from the axial abutment surface (23) and an auxiliary axial abutment surface (25) emerging from the connecting surface (28) and facing away from the axial abutment surface (23).

An 11th aspect according to the previous aspect provides for an insulator, in which in conditions of engagement between the bar (10) and the flange (11) the axial abutment surface (23) of said seat (17) faces the axial abutment surface (21) of the bar (10), the connecting surface (28) of said seat (17) faces the connecting surface (27) of the bar (10) and the auxiliary axial abutment surface (25) of said seat ( 17) faces the auxiliary axial abutment surface (24) of the bar (10).

A 12th aspect according to the preceding aspect provides an insulator, in which said seat (17), in view along the prevailing development axis (20), has an open profile defining a radial insertion opening which allows engagement with said coupling zone (16) in a direction (T) transversal to the prevailing development direction (12).

A 13th aspect according to the previous aspect provides for an insulator, in which said profile has two access lips (29) connected to a connecting section (30).

A 14th aspect according to the previous aspect provides an insulator, in which said access lips (29) are counter-shaped to the corresponding portions of the profile of the coupling area (16) of said bar (10), optionally said connection portion (30 ) being substantially counter-shaped to the corresponding profile portion of the profile of the coupling area (16) of said bar (10).

A 15th aspect according to the 13th or 14th aspects provides an insulator, in which the access lips (29) are substantially rectilinear, in particular parallel, optionally the connecting portion (30) being curved in particular in a circular arc.

A 16th aspect according to any of the preceding aspects provides for an insulator, in which said seat (17), in view along the prevailing development axis (20), has a profile, in particular closed, delimiting a first and a second area (31, 32), said first area (31) having a larger size than the second area (32), said first area (31) having a bigger size than the corresponding size of the initial portion (13) of said bar (10 ) to allow relative sliding between flange (11) and bar (10), the second zone (32) having a smaller size than the corresponding size of the initial portion (13) of said bar (10) to prevent relative axial sliding between flange ( 11) and bar (10).

A 17th aspect according to the previous aspect provides an insulator, in which the first zone (31) of the profile comprises at least one curved portion, in particular an arc of a circle, the second zone (32) of the profile has two access lips ( 33) connected to a connecting section (34), said access lips (33) being connected to said curved section of said first zone (31).

An 18th aspect according to the preceding aspect provides an insulator, in which said access lips (33) are counter-shaped to the corresponding portions of the profile of the coupling area (16) of said bar (10), optionally said connection portion (34 ) being substantially counter-shaped to the corresponding profile portion of the profile of the coupling area (16) of said bar (10).

A 19th aspect according to the 17th or 18th aspects provides an insulator, in which the access lips (33) are substantially rectilinear in particular parallel, optionally the connecting section (34) being curved in particular in a circular arc.

A 20 ° aspect according to the 17 ° or 18 ° or 19 ° aspects comprises an insulator, in which the circular arc defining the connecting portion (34) of the second zone (32) has a radius smaller than the radius of the circle of the first zone (31) of the profile.

A 21 ° aspect according to aspect 4 provides an insulator, in which said seat (17) has, according to a view in the direction of extension (20) of the seat (17), a substantially circular profile, said profile being, for at least a portion, counter-shaped to the profile of said intermediate portion (15).

A 22 ° aspect according to the 10 ° aspect provides an insulator, in which the flange (11) comprises locking means (40) configured to cooperate with said intermediate portion (15) of said bar (10) allowing engagement with said coupling area (16), optionally in which said locking means (40) comprise screws and / or keys and / or tabs and / or welds and / or grains.

A 23rd aspect according to any of the preceding aspects provides for an insulator, in which said coupling area (16) has at least one recess (26) which allows coupling with the seat (17) of the flange (11), optionally called coupling area (16) presenting a plurality of notches angularly offset from each other with reference to the prevailing development direction (12).

A 24th aspect according to any of the preceding aspects provides an insulator, in which said initial portion (13) and / or said final portion (14) have a respective engagement thread.

A 25th aspect according to any of the preceding aspects provides for an insulator, in which said seat (17) is delimited by a surface (20a) extending in the direction of the prevailing development axis (20), only a part of said surface (20a ) being in contact with the corresponding contact surface of the bar (10), in particular said part of the surface (20a) in contact being at most 80% of the total surface.

A 26th aspect according to any one of the preceding aspects provides for an insulator, in which said bar (10) comprises a plurality of notches (26) subsequently arranged on said bar (10) according to the prevailing development direction (12), said plurality of slots (26) being configured to allow engagement of said flange (11) according to a plurality of axially offset operating positions.

A 27th aspect according to any one of the preceding aspects provides an insulator, in which said insulating element (2) develops along an axis of extension (6), in particular presenting a cylindrical symmetry with respect to said axis of extension (6).

A 28th aspect according to the preceding aspect provides an insulator, in which said insulating element (2) comprises a plurality of radially emerging portions (7) and a plurality of central portions (8) axially interposed with the radially emerging portions (7), and in which said radially emerging portions (7) have a larger radial size than the central portions (8), and in which said radially emerging portions (7) are alternated with cylindrical portions (8) along the extension axis (6) of the insulating element (2).

A 29th aspect according to any of the preceding aspects precedes an insulator, wherein said flange (11) comprises at least one anti-rotation element (35) configured to cooperate with at least one locking element of said insulating element (2), said element anti-rotation (35) and said locking element, in engagement conditions, being configured to prevent a relative rotary movement between the conducting body (9) and the insulating element (2).

A 30th aspect according to any of the preceding aspects provides an insulator, in which said insulating element (2) is made of porcelain.

A 31st independent aspect provides an electric power distribution system comprising: at least one transformer, a plurality of conducting cables and at least one transformer insulator (1) according to any one of the preceding claims.

An independent 32nd aspect provides a process for the realization of an insulator comprising the steps of:

> providing at least one insulating element (2) having a through cavity (3) extending between an inlet (4) and an outlet (5);

> to realize, in particular by extrusion, a bar (10) extending along a prevalent development direction (12) and having an initial portion (13), a final portion (14) and an intermediate portion (15) connected to said initial portion (13) and final (14), said bar (10) comprising at least one coupling area (16) arranged on said intermediate portion (15);

> to realize, in particular by extrusion, an auxiliary bar with a transversal dimension greater than the transversal dimension of the bar (10);

> machining said auxiliary bar through a process for example of material removal, molding or casting, to define a flange (11) comprising a seat (17) configured to engage with said coupling area (16), said flange (11 ) having an upper surface (18) and a lower surface (19), said seat (17) extending from said upper surface (18) to said lower surface (19) along an axis of development (20) which in conditions of engagement is aligned with the prevailing development direction (12) of said bar (10);

> coupling said flange (11) to said intermediate portion (15) of said bar (10) to define a conducting body (9);

> insert said conducting body (9) in said through cavity (3) of the insulating element (2) to position the initial (13) and final (14) portions at said outlet (5) and inlet (4).

An independent 33 ° aspect provides an isolator (100) for electrical transformers, comprising:

at least one insulating element (200) having a through cavity (300) extending between an inlet (400) and an outlet (500), said insulating element (200) comprising at least an anchoring portion (117) which has an upper surface (118) and a lower surface (119), said anchoring portion (117) extending from said upper surface (118) to said lower surface (119) along a development axis (120),

at least one conducting body (90) comprising at least one conducting bar (110) arranged inside said through cavity (300), said bar (110) extending along a prevalent development direction (112) and presenting an initial portion (113 ), a final portion (114), an intermediate portion (115) connected with said initial (113) and final (114) portion, said initial (113) and / or final (114) portions being at said entrance (400 ) and / or said outlet (500), said bar (110) comprising at least one coupling area (116) arranged on said intermediate portion (115), said anchoring portion (117) being configured to engage with said coupling area (116) of said bar (110) which in engagement condition has the prevailing development direction (112) substantially aligned with the development axis (120) of the anchoring portion (117),

characterized in that the through cavity (300) has, in a transverse section with respect to the development axis (120), an overall dimensions greater than that of the transverse section of at least one of said portions of said bar (110). A 34 ° aspect according to the previous aspect provides an insulator, in which said anchoring portion (117) of said insulating element (200) is configured to engage with said coupling area (116) through a transverse movement to the prevailing development direction (112) of said bar (110).

A 35th aspect according to any one of the aspects 33 or 34 provides an insulator, in which said anchoring portion (117) is configured to engage with said coupling zone (116) through a first positioning step in which the insulating element ( 200) is movable relative to the bar (110) by sliding axially along the prevailing development direction (112) of said bar (110), said through cavity (300) being configured to pass through said initial portion (113) and said intermediate portion ( 115) up to the coupling area (116) of said bar (110), and a subsequent coupling step between the insulating element (200) and the bar (110) which occurs with motion transversal to the prevailing development direction ( 112) of said bar (110). A 36 ° aspect according to any of the preceding aspects provides for an insulator, in which said bar (110) has an axial abutment surface (121) located in correspondence with the coupling area (116), the anchoring portion (117) comprising a coupling portion (122) provided with a corresponding abutment surface (123) able to abut the axial abutment surface (121) of the bar (110) in conditions of engagement of the bar (110) and insulating element (200).

A 37th aspect according to the previous aspect provides an insulator, in which said bar (110) has an auxiliary axial abutment surface (124) located in correspondence with the coupling area (116) and axially opposite to the axial abutment surface (121 ), the coupling portion (122) of the anchoring portion (117) being provided with a corresponding auxiliary abutment surface (125) adapted to abut the auxiliary axial abutment surface (124) of the bar (110) in conditions of engagement of bar (110) and insulating element (200).

A 38 ° aspect according to the preceding aspect provides an insulator, in which the axial abutment surface (121) of the bar (110) and the axial abutment surface (123) of the coupling portion (122) of the anchoring portion (117 ) are configured to allow relative sliding transversal to the prevailing development axis (112) of the bar (110).

A 39th aspect according to any of the preceding aspects provides an insulator, in which the intermediate portion (115) of the bar (110) has a circular cross-section, in which the coupling area (116) has at least one recess (126) suitable for to receive a portion of said anchoring portion (117).

A 40 ° aspect according to the previous aspect provides an insulator, in which said recess (126) is delimited by an axial abutment surface (121), by a connecting surface (127) emerging from the axial abutment surface (121) and an auxiliary axial abutment surface (124) emerging from the connecting surface (127) and facing the axial abutment surface (121).

A 41 ° aspect according to aspects 39 or 40 provides an insulator, in which said coupling area (116) has a plurality of notches (126) angularly offset from each other with reference to the prevailing development direction (112). A 42 ° aspect according to the previous aspect provides an insulator, in which the coupling portion (122) of the anchoring portion (117) has an axial abutment surface (123), a connection surface (128) emerging from the axial abutment (123) and an auxiliary axial abutment surface (125) emerging from the connecting surface (128) and facing away from the axial abutment surface (123).

A 43 ° aspect according to the previous aspect provides an insulator, in which in conditions of engagement between the bar (110) and the insulating element (200) the axial abutment surface (123) of the anchoring portion (117) faces the surface of axial abutment (121) of the bar (110), the connecting surface (128) of the anchoring portion (117) faces the connecting surface (127) of the bar (110) and the auxiliary axial abutment surface (125) of the anchoring portion (117) faces the auxiliary axial abutment surface (124) of the bar (110).

A 44 ° aspect according to any of the preceding aspects, provides an insulator, in which said anchoring portion (117), in view along the prevailing development axis (112), has a closed profile delimiting a first and a second area (131, 132), said first area (131) having a larger size than the second area (132), said first area (131) having a bigger size than the corresponding size of the initial portion (113) of said bar (110) to allow the relative sliding between the insulating element (200) and the bar (110), the second zone (132) having a smaller size than the corresponding dimensions of the initial portion (113) of said bar (110) to prevent relative axial sliding between the insulating element (200) and bar (110).

A 45 ° aspect according to the previous aspect provides an insulator, in which the first zone (131) of the profile includes at least one curved portion, in particular an arc of a circle, the second zone (132) of the profile has two access lips ( 133) connected to a connecting portion (134), said access lips (133) being connected to said curved portion of said first zone (131). A 46 ° aspect according to the preceding aspect provides an insulator, in which said access lips (133) are counter-shaped to the corresponding portions of the profile of the coupling area (116) of said bar (110), optionally said connection portion (134 ) being counter-shaped to the corresponding profile portion of the profile of the coupling area (116) of said bar (110).

A 47th aspect according to aspect 45 or 46 provides an insulator, in which the access lips (133) are substantially straight in particular parallel, optionally the connecting section (134) being curved in particular in a circular arc.

A 48 ° aspect according to aspects 45 or 46 or 47 provides for an insulator, in which the arc of the circle defining the connecting portion (134) of the second zone (132) has a radius less than the radius of the arc of the first area (131) of the profile.

A 49th aspect according to any of the preceding aspects provides an insulator, in which said initial portion (113) and / or said final portion (114) have a respective engagement threads.

A 50th aspect according to any one of the preceding aspects provides for an insulator, in which said bar (110) comprises a plurality of notches (126) subsequently arranged on said bar (110) according to the prevailing development direction (112), said plurality of notches (126) being configured to allow engagement of the insulating element (200) and constraining the insulating element (200) in the engagement position.

A 51st aspect according to any one of the preceding aspects provides an insulator, in which said insulating element (200) develops along an axis of extension (60), in particular it has a cylindrical symmetry with respect to said axis of extension (60).

A 52 ° aspect according to the preceding aspect provides an insulator, in which said insulating element (200) comprises a plurality of radial portions (70) and cylindrical portions (80), in which said radial portions (70) have a larger radial dimension with respect to the cylindrical portions (80), and in which said radial portions (70) are alternated with cylindrical portions (80) along the extension axis (60) of the insulating element (200).

A 53rd aspect according to any one of the aspects 33 to 53 provides an insulator, wherein said insulating element (200) comprises at least one main insulating element (210) and an auxiliary insulating element (220), said main insulating elements (210) and auxiliaries (220) being engaged on said intermediate portion (115) of said bar (110) and subsequently arranged with respect to each other along the prevailing development direction (112) of said bar (110). A 54th aspect according to the previous aspect provides an insulator in which at least one main insulating element (210) is spaced from said auxiliary insulating element (220).

A 55th aspect according to any one of aspects 33 to 54 provides an insulator, wherein the insulating element (200) comprises at least one, selected from the group, of the following materials: porcelain, plastic, rubber, ...

A 56th aspect according to any one of the aspects 33 to 53 provides an insulator, wherein the main insulating element (210) is made of plastic material. An independent 57th aspect provides an electrical power distribution system comprising: at least one transformer, a plurality of conductor cables to at least one transformer insulator (100) according to any one of claims 33 to 56.

An independent 58th aspect provides a method for making an insulator (100) comprising the steps of: making, in particular by molding, at least one insulating element (200) having a through cavity (300) extending between an inlet (400) and an outlet (500) and comprising at least an anchoring portion (117) which extends along a prevalent development axis (120), said anchoring portion (117) comprising at least an upper surface (118) and a lower surface (119); realize, in particular by extrusion, a bar (110) extending along a prevalent development direction (112) and having an initial portion (113), a final portion (114), an intermediate portion (115) connected with said initial portion ( 113) and final (114); making, in particular by removing material, said at least one coupling area (116) arranged on the intermediate portion (115) of said bar (110); insert said bar (110) into said through cavity (300) of the insulating element (200) to position the initial (130) and / or final (140) portions at said inlet (400) and / or said outlet ( 500); coupling said bar to said anchoring portion by means of a translation with respect to the prevailing development axis of the bar.

PURPOSE OF THE FIND

A first object of the present invention is to solve one or more of the limitations and drawbacks described above.

A further object is to provide a conducting body for transformers which is simple to manufacture and easy to assemble and therefore easy and economical to install.

One goal is also to provide an isolator that allows greater operational flexibility, allowing for easier management of any dimensional changes in the finished product or the creation of special products.

An additional object is to provide a conducting body having the same assembly steps for use in low, medium and high voltage.

BRIEF DESCRIPTION OF THE DRAWINGS

Some embodiments and some aspects of the invention will be described hereinafter with reference to the accompanying drawings, provided for illustrative and therefore non-limiting purposes only, in which:

Figure 1 is a perspective view showing a bushing insulator for transformers;

Figure 2 is a perspective view of a conducting body forming part of a bushing insulator for transformers according to a first embodiment;

Figure 3 is an exploded view of the conducting body of Figure 2;

Figure 4 shows, according to a side view, the conducting body of Figure 2;

Figure 5 is a sectional view of the conducting body of Figures 2, 4 and 5; Figure 6 is a partially top perspective view of the flange of Figures 2, 3, 4 and 5;

Figure 7 is a partially bottom perspective view of the flange of Figures 2, 3, 4 and 5;

Figure 8 is a perspective view of the conducting body in a second embodiment;

Figure 9 shows, according to a side view, the conducting body of Figure 8;

Figure 10 is a sectional view of the conducting body of Figure 9;

- Figure 11 is a front view of the conducting body of Figures 9 and 10 during the coupling phase between the bar and the flange

Figure 12 is a partially top perspective view of the flange of Figures 8-11;

Figure 13 is a partially bottom perspective view of the flange of Figures 8-11;

Figure 14 is a perspective view of an embodiment of the conducting body in a third embodiment

Figure 15 shows, according to a side view, a fourth embodiment of the conducting body;

Figure 16 is a sectional view of the conducting body of Figure 15;

Figure 17 shows, according to a side view, a fifth embodiment of the conducting body;

Figure 18 is a sectional view of the conducting body of Figure 17; Figure 19 is a perspective view of the conducting body according to a further embodiment.

- Figure 20 is a perspective view of an additional embodiment of a distribution insulator;

Figure 20A is a perspective view of the bar;

Figure 21 is a front view of an insulating element of Figure 20;

- Figure 22 is a sectional view of the insulating element of Figure 21;

- Figure 23 is a perspective view of the auxiliary insulating element;

- Figure 24 is a perspective view of the main insulating element;

- Figure 25 is a front view of the insulator of Figure 20;

- Figure 26 is a sectional view of the insulator of figures 20 and 25;

- Figure 26A is a detail of the section of Figure 26.

DETAILED DESCRIPTION

With reference to the accompanying figures, 1 generally indicates an insulator 1 for electrical transformers, in particular for power or distribution transformers.

The insulator 1 first of all comprises at least one insulating element 2 (see Figure 1), having a through cavity 3 extending between an inlet 4 and an outlet 5. At the inlet and outlet, in conditions of use of the insulator, there are, respectively, the connection points between the transformer and the conducting element arranged in the through cavity and between the cables of the electrical network and the conducting element itself.

In other words, a first end of a conducting element will emerge below the insulating element to define a portion of engagement with the transformer, the other end will emerge vice versa from the upper portion to allow the electrical connection to the network cable.

The input 4 and the output 5 of the insulating element 2 are arranged at opposite ends of the insulating element along an axis of its extension 6 with respect to which the insulating element 2 has a cylindrical symmetry.

The insulating element 2 is also equipped with a plurality of radially emerging extended portions 7, alternating with cylindrical central portions 8 having a smaller footprint than the radial portions 7. The radially emerging portions 7 are arranged in succession along the development axis 6 of the element. insulator 2 alternating with the central portions 8 and are generally but not necessarily different in shape from each other.

Portions 7 define radially extended elements which, in case of rain, avoid the formation of privileged water outflow routes which would constitute preferential lines of electrical dispersion. In addition, their inclined upper surface allows the water to remove any dirt / pollution that may deposit on the elements themselves and which reduces the electrical insulating capacity of the insulator itself.

The insulating element 2 is made, in a non-limiting way, of porcelain and is glazed on the top; optionally the same could also include parts made of different materials selected for example in the group comprising: ceramic, plastic, rubber, sintered materials, ...

Arranged inside the insulating element 2 there is then a conducting body 9 comprising a conducting bar 10 and a flange 11 (see for example Figure 2).

The conductive bar 10 also extends along a prevalent development direction 12 (which in conditions of mutual engagement between the bar 10 and the insulating element 2 coincides with the development axis 6) and has an initial portion 13, a final portion 14 and an intermediate portion 15 connected with the initial 13 and final portion 14. The final and initial portions, in conditions of engagement between the conducting body 9 and the insulating element 2, correspond, respectively, to the inlet 4 and to the output 5 of the insulating element 2. The initial portion 13 and the final portion 14 have a respective engagement thread which respectively allows direct connection with the transformer and with the external conductor cable (or with one of its interfaces). The thread is visible, for simplicity of representation, only in some of the figures, while it has been omitted only for clarity in the other tables. In any case, other and different systems of engagement of the conductor element to the transformer and to the external cable may possibly be adopted alternatively or in combination. The engagement between the bar 10 and the flange 11 takes place in correspondence with a coupling area 16 arranged on the intermediate portion 15 of the bar 10.

In particular, the flange 11 comprises a seat 17 (fig. 3), configured to engage with the coupling area 16 of the bar 10. The seat 17 extends along a development axis 20 which in engagement conditions is aligned with the direction of prevalent extension 12 of the bar 10 from an upper surface 18 to a lower surface 19 of the flange that are flat and parallel to each other.

By further detailing the configuration of the seat 17, as can be seen, for example, from Figures 5, 10, 16 and 18, it comprises, in a cross section with respect to the development axis 20, an overall dimensions greater than that of the cross section of at least one of the portions of the bar 10.

In other words, a portion of the bar can, in at least one condition, be inserted by sliding (radially as in figs. 5 and 10, or axially as in figs.

16 and 18) in seat 17.

In particular, it is then possible to note that the seat 17 is delimited by a surface 20a (for example figs. 6, 7 and 12, 13) extending in the direction of the development axis 20, and that only a part of this surface 20a is at contact with the corresponding contact surface of the bar 10 in conditions of assembly of the conducting element 10. The part of the surface 20a in contact with the contact surface of the bar (in conditions of engagement between the two elements) is in some embodiments ( the form and the second form realized va) at most 80% of the overall surface of the seat 17 and in general corresponds to less than 50%.

This mainly derives from the fact that the embodiments referred to in figures 3 and 8 require a sliding transversal to the development axis 12, 20 to ensure the engagement of the flange and bar.

The seat 17 and the coupling area 16 are in fact (in these embodiments) configured in such a way as to engage through a movement T transversal to the prevailing development direction 12 of the bar 10.

The embodiment of figures 2-7 is intended to allow engagement between the flange II and the bar 10 by means of a reciprocal movement defined by a translation according to the direction T which brings the seat 17 to be fitted on a portion of the bar 10 of reduced section.

In other embodiments the translation according to the direction T is preceded by other relative movements.

According to the latter case and as can be seen for example in Figure 14, it is possible to have a configuration of the flange 11 (and in particular of the seat 17) in which the latter, in the first phase of relative engagement, is movable relative to the bar 10 for axial sliding A along the prevailing development direction 12 of the bar 10. In particular, the seat 17 is configured to (i.e. has overall dimensions of at least a portion thereof such as to) pass through the initial portion 13 and the intermediate portion 15 up to correspondence of the coupling area 16. The seat 17 is also configured to allow a subsequent coupling step between the flange 11 and the bar 10 which occurs transversely to the prevailing development direction 12 of the bar 10 (see for example the direction T or that of the arrow 41 in figure 11 to indicate this commitment phase).

A further embodiment of the flange 11 shown in figures 15 and 16 provides that the engagement of the seat 17 with the coupling area 16 occurs through a preventive axial movement A along the prevailing development direction 12 of the bar 10.

The element that makes it possible to position the flange 11 on the bar 10 is in this case represented by an axial abutment surface 21 located in correspondence with the coupling area 16. The seat comprises a coupling portion 22 equipped with a corresponding abutment surface 23 adapted to abut the axial abutment surface 21 of the bar 10 once the flange has reached the correct coupling position.

In other words, the seat (in this case for example circular) has a size such that it can be fitted onto the bar 10 and can slide freely along the axis of the latter until it reaches a portion with an increased section which defines the abutment surface 21 and determines an axial stop with respect to further sliding in the same direction. In a less advanced and not illustrated embodiment, the flange 17 could slide axially on the bar in a totally free way; once it has been brought to the desired position, it can be bound there by means of a welding or suitable glue.

Alternatively (fig. 18) the engagement can more simply be ensured by locking means 40 such as a tightening screw or a dowel.

Returning to the description of the main embodiments of figures 2-14, it can be noted that the latter also have the axial abutment surface 21 located in correspondence with the coupling area 16.

The seat 17 comprises the relative coupling portion 22 provided with a corresponding abutment surface 23 able to abut the axial abutment surface 21 of the bar 10.

In addition to the previous surfaces, the bar 10 has an auxiliary axial abutment surface 24 located in correspondence with the coupling area 16 and axially opposite the axial abutment surface 21. As regards the coupling portion 22 of the seat 17, it is equipped with a corresponding auxiliary abutment surface 25 able to abut the auxiliary axial abutment surface 24 of the bar 10 in conditions of engagement of the bar 10 and flange 11.

The axial abutment surface 21 of the bar and the axial abutment surface 23 of the coupling portion 22 of the seat 17 are configured to allow relative sliding transversal to the prevailing development axis 12 of the bar 10 along the direction T.

As can be seen in the embodiment of the conducting body of figures 3 and 8, the intermediate portion 15 of the bar 10 has a circular cross-section while the coupling area 16 has at least one recess 26 suitable for receiving the coupling portion 22 of the seat 17 .

In the latter case, the recess 26 is delimited by the axial abutment surface 21, by a connecting surface 27 emerging from the axial abutment surface 21 and by the auxiliary axial abutment surface 24 emerging from the connecting surface 27 and facing the abutment surface axial 21. A different embodiment, visible in figure 14, provides for the use of a plurality of grooves 26 on the bar which could be angularly offset from each other and / or subsequently arranged along the prevailing development axis 12. This allows to have available a bar designed to receive a flange at different heights along the axis according to requirements.

The coupling portion 22 also has a connecting surface 28 emerging from the axial abutment surface 23 and an auxiliary axial abutment surface 25.

In conditions of engagement between the bar 10 and the flange 11, as shown in the figures, the axial abutment surface 23 of the seat 17 faces the axial abutment surface 21 of the bar 10, the connection surface 28 of the seat faces the connection surface 27 of the bar and the auxiliary axial abutment surface 25 of the seat faces the auxiliary axial abutment surface 24 of the bar.

As can be seen from Figure 5, the seat of the flange 11 of the first embodiment has an open profile defining a radial insertion opening. The through opening allows engagement with the coupling zone 16 in the direction T transverse to the prevailing development direction 12.

More specifically, it can be seen that it has two access lips 29 connected to a connecting portion 30. The access lips 29 are substantially counter-shaped to the corresponding portions of the profile of the bar coupling area. The connecting portion 30 may or may not be counter-shaped to the corresponding portion of the profile of the coupling area of said bar.

As can also be seen from Figure 5, the access lips 29 are substantially rectilinear, optionally parallel to each other. Also visible in Figure 5, the connecting portion 30 is curved, optionally in the form of an arc of a circle. In a further configuration visible in Figures 10 and 11, the seat 17, seen along the prevailing development axis 12, has a preferably closed profile. The profile comprises a first and a second zone 31, 32. The first zone 31 has a passage of greater bulk than the second zone 32, furthermore the first zone 31 has a passage of greater bulk than the corresponding bulk of the initial portion 13 of the bar 10 thus allowing the sliding and consequent positioning of the flange 11 in the coupling area 16 of the bar 10 (see figure 8 or figure 14, axial translation along the direction 12 - arrow A). The second zone 32, on the other hand, is configured to prevent, in working conditions of bar 10 and flange 11, the relative axial and rotary movement between flange 11 and bar 10.

In a first particular case, the first zone 31 of the closed profile comprises at least one curved portion 42, optionally in the form of an arc of a circle.

Note that this section 42 is closed, ie it does not open the seat 17 to the outside; however, in a possible variant embodiment not shown, the portion 42 could have an opening towards the outside, for example of such dimensions as not to allow the exit of the initial and terminal portions 13, 14 of the bar 10 during the sliding phases of which for example in figure 13.

In other words, in this further embodiment, the engagement sequence would remain unaltered (axial sliding along the direction A to reach the engagement zone 16 and subsequently transversal sliding along the direction T to allow the axially integral engagement of the bar 10 and flange 11), even in the presence of an open profile of the seat 17.

The second zone 32 of the profile comprises two access lips 33 connected to the curved section of the first zone 32 and a connecting section 34. The access lips can be counter-shaped to the corresponding sections of the profile of the coupling zone 16, optionally they can be substantially straight .

Also for the connecting portion 34 it is possible to have a first situation in which the portion is counter-shaped to the corresponding portion of the profile of the coupling area 16 of the bar 10, optionally the connecting portion is substantially an arc of a circle.

The arc of a circle defining the connecting portion of the second zone 32 has a radius less than the radius of the arc of the first zone 31 of the profile to allow the aforementioned relative movements and locking between bar and flange.

Differently, the further embodiment of the seat 17 shown in Figures 15 to 19 shows the seat 17 provided with a substantially circular and generally closed profile, which for at least a portion is counter-shaped to the profile of the intermediate zone 15 of the bar 10 .

The flange may comprise locking means 40 configured to cooperate with the intermediate portion 15 of the bar, allowing engagement with said coupling area 16. In particular, said locking means 40 are used when the engagement of the flange on the bar provides only relative motion of the axial type and in which the seat has a circular profile.

For the latter case described, the seat 17 and the bar 10 are configured to be coupled together by means of screws, keys, tabs or welding.

Figure 18 shows a bar 10 and a flange 11 with screw locking.

As can be seen in the figures, the flange 11 also comprises at least one anti-rotation element 35 configured to cooperate with a corresponding locking element (for example a suitable seat - not shown) defined inside the through cavity 3 of the insulating element 2. The anti-rotation element 35 and the locking element, in conditions of engagement, cooperate and prevent relative rotation between the conducting body 9 and the insulating element 2.

In the embodiments shown by way of example, the anti-rotation element consists of one or two teeth emerging from a surface 18, 19 of the flange along the direction 20.

The description of the process for manufacturing / assembling an insulator 1 for transformers of the type described above is briefly reported below.

A first step includes the preparation of at least one insulating element 2 presenting the aforementioned through cavity 3 which extends between the inlet 4 and the outlet 5;

A further step comprises the production, in particular by extrusion, of the bar 10 which, as described, extends along the prevailing development direction 12 and has an initial portion, a final portion and an intermediate intermediate portion. The bar comprises the coupling area 16 arranged in correspondence with the intermediate portion 15.

A further step comprises the production, in particular by extrusion, of an auxiliary bar having a transverse dimension greater than the transversal dimension of the bar.

Subsequently, the auxiliary bar is machined by means of a material removal process, for example turned. The machining serves to define the flange 11 provided (at least) with the seat 17 configured to engage with the coupling area 16. The seat 17 of the flange 11 extends between an upper surface 18 and a lower surface 19 along the development axis 20 , which in engagement conditions is aligned with the prevailing development direction 12 of the bar.

Alternatively, the auxiliary bar could be obtained by casting or by molding with known techniques.

A subsequent step involves making the cutout (s) 26 on the bar 10 by removing material (for example by milling).

A subsequent step provides for the coupling of the flange 11 to the intermediate portion of the bar to define the conducting body 9;

A further step then comprises the insertion of the conducting body 9 into the through cavity 3 of the insulating element 2. Consequently, the insertion of the conducting body into the insulating element is the positioning of the initial and final portions in correspondence with the inlet and outlet of the insulating element.

The flange 11 offers the abutment surface 18 which cooperates with a corresponding undercut placed inside the through cavity 3 of the insulating element 2 and defines an axial positioning stop between the conducting element 9 and the insulating element 2; the anti-rotation element 35 prevents relative rotations between the conducting element 9 and the insulation 2.

A further embodiment of the insulator is shown in figures 20 to 26a. With reference to Figure 20, an insulator 100 for electric transformers, in particular for power or distribution transformers, is indicated as a whole.

The insulator 100, for example for low voltage, first of all comprises at least one insulating element 200 (see Figure 20), having a through cavity 300 extending between an inlet 400 and an outlet 500. At the inlet and the output, in conditions of use of the insulator, there are, respectively, the connection points between the transformer and the conducting element arranged in the through cavity and between the cables of the electrical network and the conducting element itself.

In other words, a first end of a conducting element will emerge below the insulating element to define a portion of electrical connection to the transformer, the other end will emerge vice versa from the upper portion to allow the electrical connection to the network cable.

The inlet 400 and the outlet 500 of the insulating element 200 are arranged at opposite ends of the insulating element along its axis of extension 120 with respect to which the insulating element 200 has a cylindrical symmetry.

The insulating element 200 is also provided with a plurality of radially emerging extended portions 70, alternating with cylindrical (or less) central portions 80 having smaller dimensions than the radial portions 70 (Fig. 26). The radially emerging portions 70 are arranged in succession along the axis of extension 120 alternating with the central portions 80 and are in general, but not necessarily different in shape from each other.

Portions 70 define radially extended elements which, in case of rain, avoid the formation of privileged water outflow routes which would constitute preferential lines of electrical dispersion. In addition, their inclined upper surface allows the water to remove any dirt / pollution that may deposit on the elements themselves and which reduces the electrical insulating capacity of the insulator itself.

The insulating element 200 is made, in a non-limiting way, of plastic or in any case of a material which is printable and which allows the maintenance of suitable tolerances; optionally the same could also include parts made of different materials selected for example in the group comprising: ceramic, plastic, rubber, sintered materials, ...

In particular, as can be seen from figures 20 and 26, the insulating element 200 comprises a main insulating element 210, in particular made of plastic material, and an auxiliary insulating element 220, in particular made of porcelain.

Arranged inside the insulating element 200 there is then a conducting body 90 comprising a conducting bar 110.

The conductive bar 110 also extends along a prevalent development direction (which in conditions of mutual engagement between the bar 110 and the insulating element 200 coincides with the development axis 120) and has an initial portion 113, a final portion 114 and an intermediate portion 115 connected to the initial portion 113 and final 114. The final and initial portions, in conditions of engagement between the conducting body 90 and the insulating element 200, correspond, respectively, to the inlet 400 and the outlet 500 of the insulating element 200. The initial portion 113 and the final portion 114 have a respective engagement thread which respectively allows direct connection with the transformer and with the external conductor cable (or with one of its interfaces). In any case, other and different systems of engagement of the conductor element to the transformer and to the external cable may possibly be adopted as an alternative or in combination.

The engagement between the bar 110 and the insulating element 200 occurs at a coupling area 116 arranged on the intermediate portion 115 of the bar 110.

In particular, the insulating element 200 comprises an anchoring portion 117 (fig. 21, 24), configured to engage with the coupling area 116 of the bar 110. The anchoring portion 117 extends along a development axis 120 which under conditions of engagement is aligned with the prevailing development direction 112 of the bar 110 from an upper surface 118 to a lower surface 119, flat and parallel to each other, of the anchoring portion.

By further detailing the configuration of the anchoring portion 117, as can be seen, for example, from Figures 20 and 25, it comprises, in a cross section with respect to the development axis 120, an overall dimension greater than that of the cross section of at least one portions of the bar 110. In other words, a portion of the bar can be inserted by sliding axially into the insulating element.

In particular, it is then possible to note that the anchoring portion 117 is delimited by a surface 120a (for example fig. 21 and 22) extending in the direction of the development axis 120, and that only a part of this surface 120a is in contact with the corresponding contact surface of the bar 110 in conditions of assembly of the conducting body 90.

The anchoring portion 117 and the coupling area 116 are configured in such a way as to engage through a movement transversal to the prevailing development direction 112 of the bar 110.

The embodiment of figures 20-26a is intended to allow the engagement between the insulating element 200 and the bar 110 by means of a reciprocal movement defined by a translation according to a transversal direction which brings the anchoring portion 117 to be fitted on a portion of the 110 bar with reduced section.

The translation is preceded by other relative movements such as the axial sliding between the insulating element 200 and the bar 110.

The anchoring portion 117 is configured to (i.e. has overall dimensions of at least a portion thereof such as to) pass through the initial portion 113 and the intermediate portion 115 up to the coupling area 116. The anchoring portion 117 is also configured to allowing a subsequent coupling step between the insulating element 200 and the bar 110 which occurs transversely to the prevailing development direction 112 of the bar 110.

The figures clearly illustrate a coupling situation by means of a translation in a direction orthogonal to the prevailing development axis and in this sense the abutment surfaces 121, 124 are also flat surfaces that develop orthogonally to the prevailing development axis of the insulator. .

Alternatively, the translation according to the transverse axis may not be orthogonal; the abutment surfaces 121, 124 would in this situation be defined by inclined flat surfaces adapted to receive by sliding corresponding flat surfaces of the anchoring portion 117.

This determines in the relative coupling motion a movement component orthogonal to the development axis and an axial movement component; since the insulating element includes two parts that clamp the transformer wall, the axial motion allows the transformer wall to be clamped and at the same time the orthogonal motion ensures stable engagement with the bar.

It is evident that the above is also applicable to the coupling between bar 10 and flange 11 according to the previous embodiments (figs. 1-19).

The element that makes it possible to position the insulating element 200 on the bar 110 is in this case represented by an axial abutment surface 121 placed in correspondence with the coupling area 116 (visible in figure 20 A). The anchoring portion comprises a coupling portion 122 equipped with a corresponding abutment surface 123 adapted to abut the axial abutment surface 121 of the bar 110 once the insulating element has reached the correct coupling position. In other words, the anchoring portion (in this case for example circular) has such a size that it can be fitted onto the bar 110 and can slide freely along the axis of the latter until it reaches a portion with a larger section. which defines the abutment surface 121 and determines an axial stop with respect to further sliding in the same direction.

The anchoring portion 117 comprises the relative coupling portion 122 provided with a corresponding abutment surface 123 able to abut the axial abutment surface 121 of the bar 110.

In addition to the previous surfaces, the bar 110 has an auxiliary axial abutment surface 124 located in correspondence with the coupling area 116 and axially opposite the axial abutment surface 121 (visible in Figure 20A). As regards the coupling portion 122 of the anchoring portion 117, it is provided with a corresponding auxiliary abutment surface 125 adapted to abut the auxiliary axial abutment surface 124 of the bar 110 in conditions of engagement of the bar 110 and the insulating element 200. The axial abutment surface 121 of the bar and the axial abutment surface 123 of the coupling portion 122 of the anchoring portion 117 are configured to allow relative sliding transversal to the prevailing development axis 112 of the bar 110.

As can be seen in the embodiment of the conducting body of figures 20A, 26 and 26A, the intermediate portion 115 of the bar 110 has a circular cross section while the coupling area 116 has at least one recess 126 suitable for receiving the coupling portion 122 of the anchor portion 117.

In the latter case, the recess 126 is delimited by the axial abutment surface 121, by a connecting surface 127 emerging from the axial abutment surface 121 and by the auxiliary axial abutment surface 124 emerging from the connecting surface 127 and facing the abutment surface axial 121.

As can be seen in Figure 20A, there is a plurality of grooves 126 on the bar which could be angularly offset from each other and / or subsequently arranged along the prevailing development axis 112.

Figures 20 to 26a show the case in which the bar has a plurality of grooves 126 which are coupled with a relative plurality of anchoring portions of the insulating element.

This makes it possible to have a bar available which is designed to receive an insulating element and to lock it at different heights along the axis according to requirements in order to avoid misalignments between the two parts.

The coupling portion 122 also has a connecting surface 128 emerging from the axial abutment surface 123 and an auxiliary axial abutment surface 125.

In conditions of engagement between the bar 110 and the insulating element 200, the axial abutment surface 123 of the anchoring portion 117 faces the axial abutment surface 121 of the bar 110, the connection surface 128 of the anchoring portion faces the connection surface 127 of the bar and the auxiliary axial abutment surface 125 of the anchoring portion faces the auxiliary axial abutment surface 124 of the bar.

As can be seen from Figure 21, the anchoring portion 117 of the insulating element 200 has a closed profile defining an axial insertion opening. The through opening allows engagement with the coupling area 116 in a direction transverse to the prevailing development direction 112.

The profile comprises a first and a second zone 131, 132. The first zone 131 has a passage of greater space than the second zone 132, furthermore the first zone 131 has a passage of space greater than the corresponding dimensions of the initial portion 113 of the bar 110 thus allowing the sliding and consequent positioning of the insulating element 200 in the coupling zone 116 of the bar 110. The second zone 132, on the other hand, is configured to prevent, in working conditions of the bar 110 and the insulating element, the relative axial and rotary movement between insulating element 200 and bar 110.

The first zone 131 of the closed profile comprises at least one curved portion 142, optionally in the form of an arc of a circle.

The second zone 132 of the profile comprises two access lips 133 connected to the curved section of the first zone 132 and a connecting section 134. The access lips can be counter-shaped to the corresponding sections of the profile of the coupling zone 116, optionally they can be substantially straight .

Also for the connecting portion 134 it is possible to have a first situation in which the portion is counter-shaped to the corresponding portion of the profile of the coupling area 116 of the bar 110, optionally the connecting portion is substantially an arc of a circle.

The arc of a circle defining the connecting portion of the second zone 132 has a radius less than the radius of the arc of the first zone 131 of the profile to allow the aforementioned relative movements and locks between the bar and the insulating element.

The description of the process for manufacturing / assembling an isolator 100 for transformers of the type described above is briefly reported below.

A first step comprises the realization, in particular by molding, of an insulating element 200 having the aforementioned through cavity 300 which extends between the inlet 400 and the outlet 500 and comprising an anchoring portion which extends from an upper surface to a lower surface along a prevalent development axis 120;

A second step comprises the production, in particular by extrusion, of the bar 110 which, as described, extends along the prevailing development direction 112 and has an initial portion, a final portion and an intermediate portion in between. The bar comprises the coupling area 116 arranged in correspondence with the intermediate portion 115.

The bar is then machined by means of a material removal process, for example turned. The processing is used to define the hole 126 useful for coupling with the anchoring portion.

A subsequent phase involves Γ insertion of the bar 110 inside the insulating element 200;

Consequently to the insertion of the conducting body inside the insulating element there is the positioning of the initial and final portions in correspondence with the inlet and outlet of the insulating element.

Claims (10)

CLAIMS 1. Isolator (100) for electrical transformers, comprising: at least one insulating element (200) having a through cavity (300) extending between an inlet (400) and an outlet (500), said insulating element (200) comprising at least an anchoring portion (117) which has an upper surface (118) and a lower surface (119), said anchoring portion (117) extending from said upper surface (118) to said lower surface (119) along a development axis (120), at least one conducting body (90) comprising at least one conducting bar (110) arranged within said through cavity (300), said bar (110) extending along a prevalent direction of development (112) and presenting an initial portion (113), a final portion (114), an intermediate portion (115) connected with said initial (113) and final (114) portion, said initial (113) and / or final (114) portions being in correspondence with said inlet (400) and / or of said outlet (500), said bar (110) comprising at least one coupling area (116) arranged on said intermediate portion (115), said anchoring portion (117) being configured to engage with said coupling area (116) of said bar (110) which in engagement condition has the prevailing development direction (112) substantially aligned with the development axis (120) of the anchoring portion (117), the through cavity (300) has, in a transverse section with respect to the development axis (120), an overall dimensions greater than that of the transverse section of at least one of said portions of said bar (110) , characterized in that said anchoring portion (117) of said insulating element (200) is configured to engage with said coupling area (116) through a transverse movement to the prevailing development direction (112) of said bar (110). 2. Insulator according to claim 1, wherein said anchoring portion (117) is configured to engage with said coupling area (116) through a first positioning step in which the insulating element (200) is movable relative to the bar ( 110) by sliding axially along the prevailing development direction (112) of said bar (110), said through cavity (300) being configured to pass through said initial portion (113) and said intermediate portion (115) up to the area of coupling (116) of said bar (110), and a subsequent coupling step between the insulating element (200) and the bar (110) which occurs with motion transversal to the prevailing development direction (112) of said bar (110) . 3. Insulator according to any one of the preceding claims, wherein said bar (110) has an axial abutment surface (121) located in correspondence with the coupling area (116), the anchoring portion (117) comprising a coupling portion ( 122) provided with a corresponding abutment surface (123) able to abut the axial abutment surface (121) of the bar (110) in conditions of engagement of the bar (110) and insulating element (200), said bar (110) presenting an auxiliary axial abutment surface (124) located in correspondence with the coupling area (116) and axially opposite the axial abutment surface (121), the coupling portion (122) of the anchoring portion (117) being provided with a corresponding auxiliary abutment surface (125) adapted to abut the auxiliary axial abutment surface (124) of the bar (110) in conditions of engagement of the bar (110) and insulating element (200). 4. Insulator according to the preceding claim, wherein the axial abutment surface (121) of the rod (110) and the axial abutment surface (123) of the coupling portion (122) of the anchoring portion (117) are configured to allow a relative sliding transversal to the prevailing development axis (112) of the bar (110). 5. Insulator according to any one of the preceding claims, in which the intermediate portion (115) of the bar (110) has a circular cross-section, in which the coupling area (116) has at least one recess (126) suitable for receiving a portion of said anchoring portion (117), in particular said coupling area (116) has a plurality of notches (126) angularly offset from each other with reference to the prevailing development direction (112). 6. Insulator according to the preceding claim, wherein the coupling portion (122) of the anchoring portion (117) has an axial abutment surface (123), a connecting surface (128) emerging from the axial abutment surface (123) and an auxiliary axial abutment surface (125) emerging from the connecting surface (128) and facing away from the axial abutment surface (123), in conditions of engagement between the bar (110) and the insulating element (200) the surface of axial abutment (123) of the anchoring portion (117) facing the axial abutment surface (121) of the bar (110), the connecting surface (128) of the anchoring portion (117) facing the connecting surface (127) of the bar (110) and the auxiliary axial abutment surface (125) of the anchoring portion (117) facing the auxiliary axial abutment surface (124) of the bar (110). 7. Insulator according to any one of the preceding claims, wherein said anchoring portion (117), in view along the prevailing development axis (112), has a closed profile delimiting a first and a second zone (131, 132 ), said first area (131) having a larger size than the second area (132), said first area (131) having a bigger size than the corresponding size of the initial portion (113) of said bar (110) to allow the relative sliding between the insulating element (200) and the bar (110), the second zone (132) having a smaller size than the corresponding dimensions of the initial portion (113) of said bar (110) to prevent relative axial sliding between the insulating element (200) and the bar (110). 8. Insulator according to the preceding claim, in which the first zone (131) of the profile comprises at least one curved portion, in particular an arc of a circle, the second zone (132) of the profile has two access lips (133) connected to a connecting section (134), said access lips (133) being connected to said curved section of said first zone (131), said access lips (133) being counter-shaped to the corresponding sections of the profile of the coupling zone (116) of said bar (110), optionally said connecting section (134) being counter-shaped to the corresponding profile section of the profile of the coupling area (116) of said bar (110), in particular the access lips (133) being substantially rectilinear in particular parallel, optionally the connecting portion (134) being curved in particular like an arc of a circle. 9. Insulator according to any one of claims 33 to 53, wherein said insulating element (200) comprises at least one main insulating element (210) and an auxiliary insulating element (220) distinct and separate, said main insulating elements (210) and auxiliary (220) being engaged on said intermediate portion (115) of said bar (110) and subsequently arranged with respect to each other along the prevailing development direction (112) of said bar (110). 10. Process for making an insulator (100) comprising the steps of: making, in particular by molding, at least one insulating element (200) having a through cavity (300) extending between an inlet (400) and an outlet ( 500) and comprising at least an anchoring portion (117) which extends along a prevalent development axis (120), said anchoring portion (117) comprising at least an upper surface (118) and a lower surface (119); realize, in particular by extrusion, a bar (110) extending along a prevalent development direction (112) and having an initial portion (113), a final portion (114), an intermediate portion (115) connected with said initial portion ( 113) and final (114); making, in particular by removing material, said at least one coupling area (116) arranged on the intermediate portion (115) of said bar (110); insert said bar (110) into said through cavity (300) of the insulating element (200) to position the initial (130) and / or final (140) portions at said inlet (400) and / or said outlet ( 500); coupling said bar to said anchoring portion by means of a translation with respect to the prevailing development axis of the bar.