RU2615979C2 - Electrical device with insulator - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to an electrical device to an electrical circuit having at least a first insulator with the first insulating main body and the second insulator to the second base insulating body. The first and second insulating main body portions extend from respective electrical device along a first longitudinal axis and second longitudinal axis respectively, wherein said first and second longitudinal axes lie parallel to each other in a common plane. The first and second insulating bushings are ribs projecting from the corresponding insulating bodies.

EFFECT: reduction of electrostatic discharge between the main insulating insulator bodies.

15 cl, 9 dwg

Description

Technical field

The present invention relates to an electrical device having multiple insulators with improved characteristics.

State of the art

As is known, insulators are widely used in electrical devices, for example, such as insulating sleeves or insulating rods connected to the corresponding parts of such devices that are energized. In particular, the insulator has a main insulating body, configured to enclose the corresponding parts under voltage, so as to isolate them from the environment outside the insulator.

In general, the phase of an electrical device is connected to an insulator that constitutes electrical insulation between the electrical phase itself and the other, adjacent electrical phases of the electrical device.

For example, insulators can be connected to electrical phases or poles of known switching devices, such as circuit breakers, disconnectors or contactors.

For example, insulators can be connected to the electrical phases of known electrical transformers, as is the case where a bushing is provided to allow a live conductor to pass through an obstacle, for example, through a transformer tank.

The insulator generally contains many rounded ribs that protrude from its main insulating body to increase the creepage distance of the insulator itself (i.e., the distance traveled by the leakage current flowing along the peripheral surface of the main insulating body between its upper and lower ends) .

In particular, ribs having a larger radius (larger ribs) and ribs having a smaller radius (smaller ribs) protrude from the main insulating body, alternating with each other.

The larger ribs of the insulating bodies located side by side with each other are facing each other, and the smaller ribs of such insulating bodies are facing each other.

For example, in FIG. 1 shows a first insulator 700 and a second insulator 701, according to the prior art, having a first main insulating body 702 and a second main insulating body 703, respectively.

An insulating body 702 and an insulating body 703 protrude from and extend from respective portions of a known electrical device, for example, such as a switching device, along a first longitudinal axis 80 and a second longitudinal axis 81, respectively. The first and second longitudinal axes 80 and 81 lie parallel to each other in a common plane so that the main insulating bodies 702 and 703 are aligned with each other and are located side by side.

The insulators 700 and 701 are connected to the first electrical phase and the second, adjacent electrical phase of the electrical device, respectively.

Large circular ribs 710 of insulator 700 protrude from the main insulating body 702, each of which faces a corresponding larger circular rib 711 protruding from the main insulating body 703; in particular, larger ribs 710 and 711 facing each other have the same radius.

The smaller round ribs 712 of the insulator 700 protrude from the main insulating body 702, each of them facing the corresponding of the smaller ribs 713 protruding from the second main insulating body 703; smaller ribs 712 and 713 facing each other have the same radius.

The separation distance between the first and second electrical phases depends on the minimum _phase distance D in the air between the insulators 700, 701. In particular, this _phase distance D corresponds to the minimum distance between the larger ribs 710 of the insulator 700 and the corresponding larger ribs 711 of the insulator 701.

The _phase distance D is critical since the electrostatic voltage between adjacent phases (and the undesirable effects of this electrostatic voltage) is highly dependent on such a _phase distance D.

In the current state of the art, although the known solutions work in a rather satisfactory manner, there is still a reason and need for further improvements.

Summary of the invention

Such a need is realized by means of an electrical device adapted to be installed in an electrical circuit and comprising at least a first insulator having a first main insulating body and a second insulator having a second main insulating body, the first main insulating body and the second main insulating body protrude from the corresponding sections of the electrical device along the first longitudinal axis and the second longitudinal axis, respectively, while the first and second longitudinal axes pass arallelno each other in a common plane.

The first insulator has many insulating ribs containing:

at least one first insulating rib protruding from the first main insulating body so as to lie in the corresponding first plane perpendicular to the common plane, and such a first insulating rib has a first distance D ₁ between its limiting end closest to the second longitudinal axis, and the first longitudinal axis; and

at least one second insulating rib protruding from the first main insulating body so as to lie in a corresponding second plane perpendicular to the common plane, the second insulating rib having a second distance D ₂ between its limiting end closest to the second longitudinal axis and the first longitudinal axis, wherein the first distance D _{1 is} greater than the second distance D ₂ .

The second insulator has many insulating ribs containing:

at least one third insulating rib protruding from the second main insulating body so as to contact the first insulating rib, the third insulating rib having a third distance D ₃ between its limiting end closest to said first longitudinal axis and the second longitudinal axis; and

at least one fourth insulating rib protruding from the second main insulating body so as to contact the second insulating rib, the fourth insulating rib having a fourth distance D ₄ between its limiting end closest to said first longitudinal axis and the second longitudinal axis.

The first, second, third and fourth distances D ₁ , D ₂ , D ₃ and D ₄ satisfy the following relations:

D ₁ > D ₃ ; D ₄ > D ₂ ; D ₄ > D ₃ ; and D ₄ <D ₁ + (D ₁ -D ₂ )

Another aspect of the present invention is directed to the development of a switchgear comprising at least one electrical device, such as an electrical device defined by the attached claims and disclosed in the following description.

In the following description, specific references will be made, for example, to an electrical switching device; in particular, references will be made, for example, to an electric switching device adapted for use in applications involving medium voltages.

In the context of the present invention, the term "medium voltage" refers to applications with operating voltages in the range from 1 kV to several tens of kV, for example 30 kV or 40 kV.

It should be noted that the principles and technical characteristics included in the following description apply to switching devices of a different type and / or used in applications with a voltage range different from the above, for example, in applications involving voltages of more than 40 kV.

In addition, the included solutions and technical characteristics, in particular those related to the proposed insulators, are also applicable to any type of electrical device, such as, for example, an electric transformer.

Brief Description of the Drawings

Additional characteristics and advantages will become clearer from the description of possible, but not exclusive, embodiments of the electrical device in accordance with this invention depicted in the accompanying drawings, in which:

FIG. 1 shows two insulating bodies arranged aligned with each other side by side in an electrical device corresponding to the state of the art;

FIG. 2 is a circuit diagram of an electric phase in a switching device in accordance with the present invention;

FIG. 3 is a perspective view of a switching device in accordance with the present invention;

FIG. 4 is an exploded view of the components of the switching device according to FIG. 3;

FIG. 5 is a perspective view of the metal shell of the switching device according to FIG. 3 also illustrating components enclosed in or supported by such a metal sheath;

FIG. 6 is a cross-sectional side view of the switching device of FIG. 3;

FIG. 7 is a cross-sectional front view of the electrical phase of the switching device according to FIG. 3;

FIG. 8 is a cross-sectional side view showing at least partially three aligned main insulating bodies of the switching device according to FIG. 3;

FIG. 9 is a cross-sectional side view of a switchgear having a switching device installed therein in accordance with the present invention.

Description of Preferred Embodiments

It should be noted that in the following detailed description, components that are identical or structurally and / or functionally similar have the same reference numerals regardless of whether they are depicted in different embodiments of the present invention; it should also be noted that for a clear and concise description of the present invention, the drawings may not necessarily be drawn to scale, and some features of the invention may be depicted in a somewhat schematic form.

The present invention relates to an electrical switching device 1 configured to be installed in an electrical circuit; the electrical device 1 comprises at least a first insulator 800 having a first main insulating body 92a and a second insulator 801 having a second main insulating body 92b. The main insulating body 92a and the main insulating body 92b protrude from the respective sections of the electrical device 1 along the first longitudinal axis 500a and the second longitudinal axis 500b, respectively; in particular, the first and second longitudinal axes 500a and 500b lie parallel to each other in the common plane 900 (which is schematically shown by dashed lines in Fig. 3, and which practically coincides with the drawing plane of Fig. 8) so that the main insulating bodies 92a and 92b are aligned with each other.

In practice, the longitudinal axes 500a and 500b are centered through the respective insulators 800 and 801 along the longitudinal direction of their main insulating bodies 92a and 92b.

Turning to an exemplary non-limiting embodiment, according to FIG. 2-9, the electrical device 1, in accordance with the present invention, may be a switching device 1 suitable for installation in an electrical circuit 102, for example, in a medium voltage circuit 102.

The switching device 1 shown, for example, in FIG. 2-9, comprises: a first electrical phase 2a connected to a first insulator 800 (having a main insulating body 92a), a second electric phase 2b connected to a second insulator 801 (having a main insulating body 92b); and a third electrical phase 2c coupled to a third insulator 802 (having a main insulating body 92c).

Three electrical phases 2a, 2b and 2c operatively electrically connect the first part 100 and the second part 101 of the electric circuit 102 (as shown, for example, in FIG. 2, which relates to the electric phase 2a). For example, the first part 100 of the electrical circuit 102 may be a distribution or linear part, the part 100 is configured to distribute power, and the second part 101 may be a load part 101 transmitting power from the distribution part 101.

In particular, each of the three illustrated electrical phases 2a, 2b, 2c comprises at least one switching unit 10 having a movable contact 11, which can be actuated during operation of the switching unit 10 itself, connected to a corresponding fixed contact 12, and disconnect from it, as will be described in more detail in the following description.

In the exemplary embodiment shown in FIG. 3-4, 6 and 8-9, the main insulating bodies 92a, 92b, 92c of the three insulators 800, 801, 802 protrude from the corresponding section 90 of the switching device 1 along the longitudinal axis 500a, the longitudinal axis 500b and the third longitudinal axis 500c, respectively, which lie parallel to each other in a common plane 900.

The three main insulating bodies 92a, 92b, 92c are aligned with each other; in particular, the main insulating body 92a is placed side by side with the main insulating body 92b, which, in turn, is placed side by side with the main insulating body 92c.

It should be noted that the switching device 1 in accordance with the present invention may have, according to specific requirements, the number of phases and associated insulators different from that shown, for example, a single electric phase 2, two or four electrical phases and two or four associated phases insulator.

Turning to the exemplary embodiment of FIG. 3-9 (in particular, to FIGS. 6 and 8), the first insulator 800 of the electrical device 1, in accordance with the present invention, has a plurality of insulating fins comprising:

at least one first insulating rib 41a (for simplicity, hereinafter referred to simply as “rib 41a”) protruding from the main insulating body 92a so as to lie in the corresponding first plane 901 (schematically indicated by a dashed line in Fig. 6), which is perpendicular to relative to the common plane 900; the rib 41a has a first distance D ₁ between its limiting end 45a closest to the longitudinal axis 500b of the main insulating body 92b and the longitudinal axis 500a of the main insulating body 92a; and

at least one second insulating rib 41b (hereinafter referred to simply as “rib 41b” for simplicity) protruding from the main insulating body 92a so as to lie in the corresponding second plane 902 (schematically indicated by the dashed line in Fig. 6), which is perpendicular to relative to the common plane 900; the rib 41b has a second distance D ₂ between its bounding end 45b closest to the longitudinal axis 500b and the longitudinal axis 500a.

The second insulator 801 of the electrical device 1, in accordance with the present invention, has many insulating ribs containing:

at least one third insulating rib 42a (hereinafter referred to simply as “rib 42a” for simplicity) protruding from the main insulating body 92b so as to contact the rib 41a; rib 42a has a third distance D ₃ between its limiting end 46a closest to the longitudinal axis 500a of the main insulating body 92a and the longitudinal axis 500b of the main insulating body 92b; and

at least one fourth insulating rib 42b (hereinafter referred to simply as “rib 42b” for simplicity) protruding from the main insulating body 92b so as to contact the rib 41b; rib 42b has a fourth distance D ₄ between its limiting end 46b closest to the longitudinal axis 500a of the main insulating body 92a and the longitudinal axis 500b of the main insulating body 92b.

In particular, the insulating ribs 41a and 42a lie in the same plane 901 so as to face each other; in the same way, the insulating ribs 41b and 42b lie in the same plane 902 so as to face each other.

Distances D ₁ , D ₂ , D ₃ and D ₄ satisfy the following relationships:

D ₁ > D ₂ ; D ₁ > D ₃ ; D ₄ > D ₂ ; D ₄ > D ₃ ; and

D ₄ <D ₁ + (D ₁ -D ₂ )

To better explain how satisfying the above ratios provides an improvement over known solutions, firstly, a case is considered in which the ribs 41a, 41b, 42a, 42b are sized in accordance with the state of the art, i.e., when the ribs 41a , 41b, 42a, 42b the following dimensions are given:

D ₁ = D ₃ ; D ₂ = D ₄ ;

wherein D ₁ > D ₂ .

In this case, taking into account the distance D between the longitudinal axes 500a and 500b of the main insulating bodies 92a and 92b, the minimum _phase distance D in the air between the insulators 800, 801 should be equal to D-2D ₁ .

Secondly, we consider the case of the presence of insulating ribs 41a, 41b and 42a, already having the following dimensions in accordance with this invention:

D ₁ > D ₂ and D ₁ > D ₃ .

The remaining edge 42b, in addition to having a size at which D _{4 is} larger than D ₂ and larger than D ₃ , must be of such a size that imposes an upper limit on the value of D ₄ . Such an upper limit is chosen so that the distance D ₂₄ between the bounding ends 45b and 46b of the ribs 41b and 42b facing each other (see FIG. 4) is greater than the minimum _phase distance D in air that could be obtained by giving ribs 41a, 41b, 42a, 42b are appropriately sized in accordance with the state of the art.

Therefore, a requirement is imposed in accordance with which:

D ₂₄ > D-2D ₁ , and D ₂₄ = DD ₂ -D ₄ .

This leads to the following dimensional constraint for rib 42b:

D ₄ <D ₁ + (D ₁ -D ₂ ).

According to a preferred, but not restrictive embodiment, the ribs 41a, 41b and 42a, 42b are rounded; in this case, the distances D ₁ , D ₂ , D ₃ and D ₄ correspond to the radius of a circle defining the peripheral edge of the corresponding ribs 41a, 41b, 42a, 42b.

According to an exemplary embodiment, the distance D ₄ is equal to the distance D ₁ and the distance D ₃ is equal to the distance D ₂ . Thus, between the bounding ends 45a-46a of the facing ribs 41a-42a and between the bounding ends 45b-46b of the facing ribs 41b-42b there is the same _phase distance D.

In this case, the ratio between the distance D ₃ (equal to the distance D ₂ ) and the distance D ₁ (equal to the minimum distance D ₄ ) is, for example, between 0.5 and 0.9, for example 0.8.

According to a preferred, but not restrictive embodiment, the insulator 800 comprises a plurality of ribs 41a and a plurality of ribs 41b, the ribs 41a and 41b protruding from the main insulating body 92a alternating with each other, as shown in the exemplary embodiment of FIG. 3-4, 6 and 8-9.

Accordingly, the insulator 801 comprises a plurality of ribs 42a and a plurality of ribs 42b, the ribs 42a and 42b protruding from the main insulating body 92b alternating with each other. In particular, each rib 42a faces a corresponding one of the plurality of ribs 41a (i.e., it lies in the same plane 901 of the corresponding rib 41a), and each rib 42b faces a corresponding one of the plurality of ribs 41b (i.e., it lies in the same plane 902 of the corresponding rib 42b).

In an exemplary embodiment, as shown in FIG. 3-9, the main insulating bodies 92a, 92b and 92c of the insulators 800, 801 and 802 have a substantially cylindrical shape.

Two rounded insulating ribs 41a and two rounded insulating ribs 41b protrude from the main insulating body 92a, alternating with each other; two circular insulating ribs 42a and two annular insulating ribs 42b protrude from the main insulating body 92b, alternating with each other, so that each of the two insulating ribs 42a faces one of the two insulating ribs 41a (i.e., they lie in the same plane 901), and each of the two insulating ribs 42b faces the corresponding one of the two insulating ribs 42b (i.e., they lie in the same plane 902).

It should be noted that the number of alternating insulating ribs 41a and 41b and corresponding insulating ribs 42a and 42b may differ from the depicted number.

Each of the two insulating ribs 41a has a distance D ₁ between its limiting end 45a closest to the longitudinal axis 500b of the main insulating body 92b and the longitudinal axis 500a of the main insulating body 92a (this distance D ₁ corresponds to the radius of the circle that defines the peripheral edge of the rib 41a).

Each of the two insulating ribs 41b has a distance D ₂ between its limiting end 45b closest to the longitudinal axis 500b and the longitudinal axis 500a (this distance D ₂ corresponds to the radius of the circle that defines the peripheral edge of the rib 41b).

Each of the two insulating ribs 42a has a distance D ₃ between its limiting end 46a closest to the longitudinal axis 500a and the longitudinal axis 500b (this distance D ₃ corresponds to the radius of the circle that defines the peripheral edge of the rib 42a).

Each of the two insulating ribs 42b has a distance D ₄ between its limiting end 46b closest to the longitudinal axis 500a and the longitudinal axis 500b (this distance D ₄ corresponds to the radius of the circle that defines the peripheral edge of the rib 42b).

In an exemplary embodiment, as shown in FIG. 8, the distance D ₁ is equal to the distance D ₄ , and the distance D ₂ is equal to the distance D ₃ , and the distance D _{1 is} greater than the distance D ₂ . In particular, the ratio between D ₃ and D ₁ (and therefore between D ₂ and D ₄ ) is essentially 0.8.

Thus, between the bounding ends 45a-46a of the facing ribs 41a-42a and between the bounding ends 45b-46b of the facing ribs 41b-42b there is the same _phase distance D in the air.

As an alternative to the illustrated embodiment of FIG. 8, the minimum distance D ₄ (greater than the minimum distance D ₂ and the minimum distance D ₃ ) can be made insignificant with respect to the minimum distance D ₁ , or you can give it a value in accordance with the following ratio:

D ₁ + (D ₁ -D ₂ )> D ₄ > D ₁ .

In the exemplary embodiment of FIG. 3-9, the insulator 802 also comprises two rounded ribs 43a and two rounded ribs 43b, the ribs 43a and 43b protruding from the main insulating body 92c alternating with each other so that each of the two ribs 43a faces one of the two ribs 42a (i.e., it lies in the same plane 901 of the corresponding rib 42a), and each of the two ribs 43b faces the corresponding one of the two ribs 42b (i.e., it lies in the same plane 902 of the corresponding rib 42b) .

Each of the two insulating ribs 43a has a distance between its limiting end 48a closest to the longitudinal axis 500b of the main insulating body 92b and the longitudinal axis 500c of the main insulating body 92c; such a distance is equal to the distance D ₁ and corresponds to the radius of a circle defining the peripheral edge of the rib 43a.

Each of the two insulating ribs 43b has a distance between its limiting end 48b closest to the longitudinal axis 500b and the longitudinal axis 500c, which is equal to the distance D ₂ (this distance corresponds to the radius of the circle that defines the peripheral edge of the rib 43b).

Thus, between the bounding ends 47a-48a of the ribs 42a-43a facing each other and between the bounding ends 47b-48b of the ribs 42b-43b facing each other, there is the same _phase distance D in the air.

Each of the two insulating ribs 42a having a distance D ₃ faces the respective ribs 41a and 43a having a larger distance D ₁ , and each of the two ribs 42b having a distance D ₄ (equal to the radial distance D ₁ ) faces the corresponding ribs 41b and 43b having a shorter distance D ₂ .

The switching device 1 according to an exemplary embodiment according to FIG. 2-9, comprises a housing 50 having at least a portion 51 made of an insulating material. The housing 50 preferably defines an interior space that can be filled with an insulating gas, such as, for example, SF ₆ , or, alternatively, in applications for lower voltages, with air.

In the housing 50 is enclosed a switching unit 10 of each of the electrical phases 2a, 2b, 2c, and its insulating section 51 contains insulators 800, 801 and 802 associated with such electrical phases 2a, 2b and 2c.

In a preferred embodiment, the housing 50 advantageously also comprises a metal portion 52. In the exemplary embodiment of FIG. 3-9, the insulating portion 51 and the metal portion 52 of the housing 50 comprise an insulating sheath 51 and a metal sheath 52, respectively, which are connected to each other.

The insulating shell 51 may be made, for example, of a polymeric material (for example, a thermoplastic or thermoset material). Among thermosetting polymers can be called, for example, epoxy resin or polyester. In the case of installing the switching device 1 in the open air, the insulating sheath 51 can be completely made of a polymer material or contain at least a covering layer of this material that is resistant to environmental influences, for example, an epoxy cycloaliphatic resin or a material with organosilicon coating. The metal sheath 52 can be made, for example, of steel, such as stainless steel or pre-galvanized steel.

Each of the main insulating bodies 92a, 92b and 92c of the insulators 800, 801 and 802 preferably defines an inner chamber 93 in which the switching unit 10 of the corresponding electric phase 2a, 2b, 2c is enclosed.

In an exemplary embodiment, as shown in FIG. 2-9, the switching unit 10 is an automatic shutdown unit 10, and its movable contact 11 can be actuated during operation of the automatic shutdown unit 10 by moving this contact between the closed position in which it is connected to the corresponding fixed contact 12, and an open position in which it is spaced with the fixed contact 12, so as to be electrically separated from such contact 12.

Referring to the example of FIG. 2, the actuation of the movable contact 11 of the block 10 for automatically turning off the electric phase 2a with the movement of this contact from the open position to the closed position ensures the flow of _phase I current between the first and second parts 100, 101 of the electric circuit 102 through electrically connected to each other movable and stationary pins 11, 12.

The actuation of the movable contact 11 with its movement from the closed position to the open position interrupts such a _phase I current through electrical separation between the movable and fixed contacts 11, 12. Such actuation can be caused by manual intervention of the operator or automatically (by means of actuators) when electrical damage occurs, such as overload or short circuit.

In an exemplary embodiment, as shown in FIG. 3-9, the automatic shutdown unit 10 comprises a cylinder 15 defining an internal sealed environment where electrical connection / separation between the movable and fixed contacts 11, 12 may occur. The interior of the cylinder 15 is preferably in a vacuum; alternatively, such an interior space may be filled with insulating gas.

Accordingly, the circuit breaker chamber 93 is defined to enclose a cylinder 15 of the corresponding circuit breaker 10. A through hole 95 is formed at the upper end of the insulating bodies 92a, 92b, and 92c, allowing free passage of the electrical terminal 3 to the corresponding circuit breaker chamber 93.

The electrical terminal 3 is connected to the automatic shutdown unit 10 enclosed in the circuit breaker chamber 93 (in particular, it is connected to the fixed contact 12, entering the cylinder 15) and is configured to electrically connect the automatic shutdown unit 10 to the corresponding section 100 of the electric circuit 102.

The switching device 1 comprises actuating means (shown schematically and indicated by the reference numeral 200 in FIG. 2), which are operatively connected to the movable contact 11 of each block 10 for automatically turning off the switching device 1 itself and are configured to actuate this contact.

For example, the actuating means 200 comprise a kinematic chain (indicated generally by 201) and drive means 203 operatively connected to each other. The kinematic chain 201 is operatively connected to the movable contact 11 of each automatic shutdown unit 10 enclosed in the corresponding circuit breaker chamber 93 and configured to be driven by the drive means 203, causing the movable contacts 11 to be actuated to move them between open and closed positions.

In an exemplary embodiment, as shown in FIG. 2-3 and 6, the drive means 203 is a drive shaft 203 that can rotate around a rotation axis 204 and which is operatively connected (using conventional coupling means 205) to the kinematic chain 201. The kinematic chain 201, in turn, is operatively connected to movable contact 11 of each block 10 automatic shutdown and is configured to cause the activation of this contact when the rotation of the drive shaft 203 around the axis 204 of rotation.

The insulating shell 51 of the switching device 1 comprises a central portion 90 defining an inner main chamber 91 enclosing at least a portion of the actuating means 200, the main insulating bodies 92a, 92b and 92c protruding from such a central portion 90 along the respective longitudinal axes 500a 500b and 500c.

In the exemplary embodiment of FIG. 3-4 and 6-8, in the inner main chamber 91 there is a kinematic chain 201, and access to each chamber 93 of the circuit breaker is possible from the main chamber 91, so that the kinematic chain 201 can quickly interact with the movable contacts 11 of the automatic blocks 10 connected to it off.

In the central portion 90 of the insulating shell 51, an opening 59 is made for access; the switching device 1 includes a cover 400, which is operatively connected to the Central section 90 to cover the opening 59 for access, and which is configured to cover and support the drive shaft 203 so that it can rotate around the axis 204. The opening 59 for access provides free access of the coupling means 205 to the main chamber 91 to operatively connect the drive shaft 203 and the kinematic chain 201. The cover 400 is preferably made of a metal material to better support the drive shaft 203 and withstand to exert forces created during rotation of the drive shaft 203 itself.

According to a preferred embodiment, the insulating sheath 51 is advantageously made in one piece, i.e. a central portion 90, a main insulating body 92a (with associated insulating ribs 41a, 41b), a main insulating body 92b (with associated insulating ribs 42a, 42b) and a main insulating body 92c (with associated insulating ribs 43a, 43b ) - all of them are made in the manufacturing process as a whole.

In the exemplary embodiment of FIG. 3-9, the central portion 90 of the insulating shell 51 comprises: a base portion 53; a first front wall 96 and a second front wall 97 that protrude laterally from two opposite ends of the base portion 53 so as to face each other; the first and second parallel side walls 98 and 99, which protrude in the transverse direction from the portion 53 of the base in such a way that they connect in the transverse direction of the first and second front walls 96 and 97; and an upper wall 25, connecting in the transverse direction, the first and second side walls 98 and 99 (and the first and second facing walls 96 and 97 facing each other).

Section 53 of the base is connected to the corresponding flange section 54 of the metal shell 52, and the opening 59 for access is made in the first front wall 96, and the cover 400 is attached to such wall 96, so as to cover such an opening 59 for access and support the drive shaft 203. The main insulating bodies 92a, 92b and 92c protrude from the upper wall 25 along their respective longitudinal axes 500a, 500b and 500c.

Advantageously, the central portion 90 further comprises: at least one support tab 110 connecting the first side surface 98 to the base portion 53; and at least one support lobe 111 connecting the second side wall 99 to the base portion 53. Such support lobes 110, 111 are configured to reinforce the entire structure of the insulating shell 51.

In an exemplary embodiment, as shown in FIG. 3, said at least one support lobe 110 comprises:

a support lobe 110a lying in a plane 450 containing a longitudinal axis 500a;

a support lobe 110b lying in a plane 451 containing a longitudinal axis 500b;

a support lobe 110c lying in a plane 452 containing a longitudinal axis 500c;

a support lobe 100d located between the support lobes 110a and 110b; and

a support lobe 100e located between the support lobes 100b and 110c.

Said at least one support lobe 111 comprises:

a support lobe aligned with the support lobe 110a (i.e., lying in the same plane 450 of the support lobe 110a);

a support lobe aligned with the support lobe 110b (i.e., lying in the same plane 451 of the support lobe 110b);

a support lobe aligned with the support lobe 110c (i.e., lying in the same plane 452 of the support lobe 110c);

a support lobe aligned with the support lobe 110d (i.e., lying in the same plane of the support lobe 100d); and

a support lobe aligned with the support lobe 110e (i.e., lying in the same plane of the support lobe 110e).

According to an exemplary embodiment of FIG. 2-9, each of the electrical phases 2a, 2b and 2c of the switching device 1 comprises an additional switching unit 20 associated with the switching unit 10 disclosed in the foregoing description. Such a switching unit 20 contains at least one movable contact 21 which during operation of the switching unit 20 itself can be actuated, connected to and disconnected from the corresponding fixed contact 22.

An electrical terminal 4 is connected to each switching unit 20 and is configured to electrically connect the switching unit 20 to a corresponding portion 101 of the electrical circuit 102. The switching unit 20 of each of the electrical phases 2a, 2b, 2c is also enclosed within the housing 50.

In an exemplary embodiment, as shown in FIG. 2-9, the switching unit 20 is a disconnecting unit 20, and its movable contact 21 can be actuated during operation of the disconnecting unit 20 itself, between the connection position in which it is connected to and connected to the corresponding fixed contact 22, and, at least one open position in which it is spaced from the fixed contact 22, so as to be disconnected from such a contact 12.

The switching device 1 comprises actuating means (shown schematically and indicated by the reference numeral 300 in FIG. 2) operatively connected to the movable contact 21 of each disconnecting unit 20 and configured to actuate this contact. Preferably, at least a portion of the actuating means 300 is enclosed in a housing 50.

Turning to FIG. 2, the connection between the movable and fixed contacts 21, 22 is configured to make an electrical connection between the first and second parts 100, 101 of the electrical circuit 102. Bringing the movable contact 21 into operation with movement from the connection position to the disconnect position causes a physical separation between the first and second parts 100, 101 (to interrupt the electrical connection between them).

Preferably, the disconnecting unit 20 and the automatic shutdown unit 10 of each phase 2a, 2b, 2c are preferably connected in series between the first and second parts 100, 101 of the circuit 102.

In particular, in the exemplary embodiment of FIG. 2, the movable contact 11 is electrically connected to the fixed contact 22 so as to make a series connection between the connected automatic shutdown unit 10 and the disconnecting unit 20; alternatively, such a connection can be made by connecting the fixed contact 12 of the automatic shutdown unit 10 to one of the movable and fixed contacts 21 and 22 of the disconnecting unit 20 associated with it.

Referring to the example of FIG. 2, under normal operating conditions of the switching device 1, a _phase I current flows between the first and second parts 100, 101 along a current path made by electrically connected to each other movable and fixed contacts 11, 12 of the automatic shutdown unit 10 and by connected movable and fixed contacts 21, 22 of the disconnecting unit 20.

After the movable contact 11 of the automatic shutdown unit 10 is moved from the closed to the open position to interrupt the _phase I current, the movable contact 21 of the disconnecting unit 20 can also be moved from the connection position to the disconnection position to provide further physical interruption in the electrical connection between the first and second parts of 100, 101.

According to a preferred, but not restrictive embodiment, the disconnecting unit 20 is advantageously configured to also implement the functionality of the grounding means 30, i.e., the disconnecting unit 20 is designed so that, during its operation, it can connect him part 101 of the electrical circuit 102 with electrical "ground".

According to an exemplary embodiment of FIG. 2-9, the disconnecting unit 20 comprises a grounding contact 23, i.e. a contact 23 electrically connected to the ground, and the movable contact 21 of such a disconnecting unit 20 can be actuated by moving between the connection position and:

a first disconnect position in which the movable contact 21 is disconnected from the corresponding fixed contact 22 and the ground contact 23;

the second disconnect position or ground position, in which the movable contact 21 is disconnected from the corresponding fixed contact 22 and connected to the grounding contact 23.

When the movable contact 21 is in the ground position, the associated part 101 of the electrical circuit 102 is electrically connected to the grounding contact 23 by an electrical connection provided by the movable contact 21 and the electrical terminal 4.

The metal shell 52 of the housing 50 is preferably grounded, i.e. it is connected to an electrical “ground” for separating by grounded metal between the first and second parts 100, 101 of the electrical circuit 102. In this case, the ground contact 23 is preferably connected to a metal sheath 52; for example, the grounding contact 23 can be mounted in an appropriate section of the metal sheath 52 (as shown in a possible embodiment, according to Fig. 5).

According to an exemplary embodiment of FIG. 3-9, the metal shell 52 is configured to: maintain a movable contact 21 and enclose a grounding contact 23 of each disconnecting unit 20, and also enclose actuating means 300.

In particular, the actuating means 300, according to the illustrated exemplary embodiment, comprises a drive shaft 301. The drive shaft 301 is operatively connected to each movable contact 21 by conventional means of connection so that the rotation of the drive shaft 301 around the axis 302 causes actuation each movable contact 21 between the connection position, the first disconnect position and the ground position.

The metal sheath 52 comprises at least: a base wall 71; a front wall 72 and a rear wall 73 protruding in the transverse direction from two opposite ends of the base wall 71; the first and second parallel side walls 74, 75 protruding in the transverse direction from the base wall 71, connecting the front and rear walls 72, 73. The upper ends of the front and rear walls 72, 73 and side walls 74, 75 are configured to determine the overall flange upper an edge (indicated generally by 76) that is connected to the flange portion 54 (which, in turn, is connected to the insulating sheath 51).

The ends of the drive shaft 301 are operatively connected to the front wall 72 and the rear wall 73 of the metal shell 52 so that the drive shaft 301 is configured to rotate around the axis of rotation 302.

The drive shaft 301 is located inside the metal sheath 52 between the movable contacts 21 and the second side wall 75. The grounding contacts 23 are attached to the first side wall 74, each of which is aligned in the direction of movement of the corresponding contact 21. The metal sheath 52 is connected to the electrical "earth" together with grounding contacts attached to it 23.

The present invention also relates to an electrical unit 1000 or a switchgear 1000 comprising at least one electrical device 1 in accordance with the present invention.

In an exemplary embodiment, as shown in FIG. 9, the switchgear 1000 comprises a housing 1001, within which a switching device 1 is installed, corresponding to the previous description. Such a switching device 1 is located between the upper compartment 1002 or the power distribution compartment 1002 containing the power distribution buses, and the lower compartment 1003 or the load compartment 1003 containing the cables or load connections connected to one or more electrical loads transmitting power from the distribution buses.

In particular, the insulating sheath 51 of the housing 50 is located in the power distribution compartment 1002, so that the electrical terminal 3 connected to each automatic shutdown unit 10 can be connected to a corresponding distribution bus. The metal sheath 52 of the housing 50 is located in the load compartment 1003, so that the electrical terminal 4 connected to each disconnecting unit 20 can be connected to a corresponding cable or load connector.

Thus, the housing 50 (in particular, the grounded metal shell 52) provides separation by grounded metal between the distribution compartment 1002 and the load compartment 1003.

In practice, it is noticed how the electrical device 1 in accordance with this invention provides the achievement of the task with some advantages over other known technical solutions.

In particular, more is achieved in relation to the known technical solution, such as the solution shown in FIG. 1, the minimum _phase distance D in air between insulators 800-801, 801-802, placed side by side. Having a larger minimum distance D of the _phase in air, the electrostatic voltage between the insulators 800-801, 801-802 (and therefore between the adjacent adjacent electric phases 2a-2b, 2b-2c) is reduced in relation to the known solutions.

In addition, the proposed switching device 1 performs at least the function of interrupting current between parts 100, 101 of the connected electrical circuit 102 (using blocks 10 automatic shutdown) and the disconnection function between such parts 100, 101 (using disconnecting blocks 20). The switching device 1 itself also preferably performs grounding functions on one of the parts 100, 101 of the connected electrical circuit 102, namely on the part that is associated with one or more electrical loads.

By integrating more functionality in one device, you can drastically reduce the entire space occupied by the casing 1001 of the corresponding electrical unit, such as switchgear 1000.

Mentioned one or more blocks 10 automatic shutdown (performing the function of interruption) and said one or more disconnecting blocks 20 (performing the function of disconnection) are enclosed in a single housing 50 having a compact and at the same time robust construction.

In particular, it is advantageous to define the housing 50 by connecting the insulating sheath 51 and the metal sheath 52 (separation by means of a grounded metal).

The insulating sheath 51 allows the economical and compact dimensions of the entire housing 50 to be embodied. Since such dimensions are obtained from the manufacture of the insulating material, it becomes possible to reduce the electrical distance of the sheath with respect to the parts under current (i.e., the parts under voltage) in the switchgear 1000, such as tires in the switchgear compartment 1002, thereby further reducing the waste of space in the casing 1001 of the switchgear 1000.

The compact insulating shell 51 is configured to enclose the automatic shutdown units 10 (and at least the associated kinematic circuit 201) in accordance with a practical and economical solution. By making the insulating shell 51 integral, such advantages can be further enhanced.

In particular, the automatic shutdown units 10 are enclosed in respective respective circuit breaker chambers 93 determined by aligned main isolating bodies 92a-92c. The disclosed configuration of the insulating ribs 41a-43a, 42a-42c and 43a-43c reduces the electrostatic voltage between the main insulating bodies 92a-92b and 92b-92c, and therefore between the automatic shutdown units 10 enclosed in the circuit breaker chambers 93 of such main insulating bodies 92a-92c.

A metal casing 52 connected to the ground embodies the dimensions of the entire casing 50, which ensures compliance with relevant standards (for example, the required separation by grounded metal between the distribution compartment 1002 and the load compartment 1003 of the distribution device 100), even if between the distribution busbars of the distribution compartment 1002 and the load compartment contains only one multifunctional and very compact device, such as switching device 1, and even if the insulating cover point 51 of such a device 1 is very close to the distribution buses. Moreover, all parts / components can be replaced with other, technical equivalent elements; in practice, the types of materials and sizes can be any, corresponding to the needs and state of the art.

Claims (37)

1. An electrical device (1) configured to be installed in an electrical circuit (102), wherein the electrical device (1) comprises at least a first insulator (800) having a first main insulating body (92a) and a second insulator (801) having a second main insulating body (92b), the first main insulating body (92a) and the second main insulating body (92b) protruding from the respective sections (90) of the electrical device (1) along the first longitudinal axis (500a) and the second longitudinal axis ( 500b), respectively, with the first and second the longitudinal axes (500a, 500b) lie parallel to each other in the common plane (900), the first insulator (800) having a plurality of insulating ribs (41a, 41b), comprising: at least one first insulating rib (41a) protruding from the first main insulating body (92a) so as to lie in a corresponding first plane (901) perpendicular to the common plane (900), the first insulating rib having a first distance D ₁ between its bounding end (45a) closest to the second longitudinal axis (500b) and the first longitudinal axis (500a); and at least one second insulating rib (41b) protruding from the first main insulating body (92a) so as to lie in a corresponding second plane (902) perpendicular to the common plane (900), the second insulating rib having a second distance D ₂ between its bounding end (45b) closest to the second longitudinal axis (500b) and the first longitudinal axis (500a), wherein the first distance D _{1 is} greater than the second distance D ₂ ; a second insulator (801) having a plurality of insulating ribs (42a, 42b), comprising: at least one third insulating rib (42a) protruding from the second main insulating body (92b) so as to contact the first insulating rib (41a), said third insulating rib having a third distance D ₃ between its limiting end (46a), closest to the first longitudinal axis (500a), and said second longitudinal axis (500b); and at least one fourth insulating rib (42b) protruding from the second main insulating body (92b) so as to access the second insulating rib (41b), the fourth insulating rib having a fourth distance D ₄ between its limiting end (46b) closest to the first longitudinal axis (500a), and the second longitudinal axis (500b), characterized in that the first, second, third and fourth distances D ₁ , D ₂ , D ₃ and D ₄ satisfy the following relations: D ₁ > D ₃ ; D ₄ > D ₂ ; D ₄ > D ₃ ; and D ₄ <D ₁ + (D ₁ -D ₂ ). 2. An electrical device (1) according to claim 1, characterized in that the fourth distance D ₄ is equal to the first distance D ₁ and the third distance D ₃ is equal to the second distance D ₂ . 3. An electrical device (1) according to claim 2, characterized in that the ratio between the third distance D ₃ and the first distance D ₁ is between 0.5 and 0.9. 4. The electrical device (1) according to claim 1, characterized in that at least one first insulating rib (41a) comprises a plurality of first insulating ribs (41a), and at least one second insulating rib (41b) comprises a plurality of second insulating ribs (41b), the first and second insulating ribs (41a, 41b) protrude from the first main insulating body (92a), alternating with each other; at least one third insulating rib (42a) comprises a plurality of third insulating ribs (42a), each of which faces a respective one of the plurality of first insulating ribs (41a), and at least one fourth insulating rib (42b) contains a plurality of fourth insulating ribs (42b), each of which is facing the corresponding one of the many second insulating ribs (41b). 5. An electrical device (1) according to any one of claims 1 to 4, characterized in that it comprises at least: a first electrical phase (2a) comprising at least one first switching unit (10), the first switching unit (10) comprising at least one first movable contact (11), which can be brought into operation during the operation of the first switching unit (10) into action, connect to and disconnect from the corresponding fixed contact (12); a second electrical phase (2b) comprising at least one second switching unit (10), the second switching unit (10) comprising at least one second movable contact (11), which can be brought into operation during the operation of the second switching unit (10) into action, connect to and disconnect from the corresponding first fixed contact (12), wherein the first insulator (800) and the second insulator (801) are connected to the first electric phase (2a) and the second electric phase (2b), respectively. 6. An electrical device (1) according to claim 5, characterized in that it comprises a housing (50) having at least one insulating section (51), wherein a first switching unit (10) and a second switching unit are enclosed in said casing (50) block (10), and wherein at least one insulating section (51) of the housing (50) comprises first and second insulators (800, 801). 7. An electrical device (1) according to claim 6, characterized in that the first main insulating body (92a) defines a first inner chamber (93) in which the first switching unit (10) is enclosed, and the second main insulating body (92b) determines the second inner chamber (93), in which the second switching unit (10) is enclosed. 8. An electrical device (1) according to claim 7, characterized in that it comprises actuating means (200) that are operatively connected to and configured to actuate at least one first movable contact (11) and at least one second movable contact (11), and at least one insulating section (51) of the housing (50) comprises a central section (90) defining a main chamber (91), in which at least a section of actuating means (200) is enclosed , and the first and second main isolating bodies (92a, 92b) protrude from the central portion (90). 9. An electrical device (1) according to claim 8, characterized in that the central portion (90) comprises: base section (53); first and second parallel side walls (98, 99) protruding in the transverse direction from the base portion (53); at least one support lobe (110) connecting the first side wall (98) to the base portion (53); and at least one support lobe (111) connecting the second side wall (99) to the base portion (53). 10. An electrical device (1) according to claim 9, characterized in that the central portion (90) comprises an upper wall (25), connecting in the transverse direction the first and second side walls (98, 99), the first and second main insulating bodies (92a, 92b) protruding from the upper wall (25); at least one lobe (110) connecting the first side wall (98) to the base portion (53) comprises: a first support lobe (110a) lying in a plane (450) containing the first longitudinal axis (500a); a second support lobe (110b) lying in a plane (451) containing a second longitudinal axis (500b); a third support lobe (110c) located between the first support lobe (110a) and the second support lobe (110b); at least one support lobe (111) connecting the second side wall (99) to the base portion (53) comprises: a fourth support lobe aligned with the first support lobe 110a; a fifth support lobe aligned with the second support lobe (110b); and a sixth support lobe aligned with the third support lobe (110c). 11. An electrical device (1) according to claim 6, characterized in that the housing (50) comprises a metal section (52). 12. An electrical device (1) according to claim 11, characterized in that at least one insulating section (51) of the housing (50) contains an insulating shell (51), and the metal section (52) contains a metal shell (52) connected with said insulating sheath (51). 13. The electrical device (1) according to claim 11, characterized in that the first electrical phase (2a) comprises a third switching unit (20) connected to the first switching unit (10), the third switching unit (20) comprising at least one third movable contact (21), which during operation of the third switching unit ( 20) can be actuated, connected to the corresponding third fixed contact (22) and disconnected from it; the second electrical phase (2b) comprises a fourth switching unit (20) connected to the second switching unit (10), the fourth switching unit (20) comprising at least one fourth movable contact (21), which during operation of the fourth switching unit ( 20) can be actuated, connected to the corresponding fourth fixed contact (22) and disconnected from it, moreover, the third and fourth switching units (20) are enclosed in the housing (50). 14. An electrical device (1) according to claim 13, characterized in that the first and second switching blocks (10) are the first and second blocks (10) of automatic shutdown, respectively, and the third and fourth switching blocks (20) are the third and fourth disconnecting blocks (20), respectively. 15. Switchgear (1000) comprising at least one electrical device (1) according to claim 1.

Images