RU99899U1 - MEDIUM VOLTAGE ELECTRIC DISCONNECTOR - Google Patents

Abstract

 1. Medium voltage gas insulated switch (1) with one or more phases, comprising:! gas-tight housing (2) containing gas; ! for each phase, a movable contact, a fixed contact and a grounding contact, which are located inside the housing (2); ! a drive mechanism (3) for moving the movable contact between the open position, the closed position and the grounded position; ! the housing (2) contains a metal half-shell (22) and a plastic half-shell (21),! the plastic half-shell (21) is made with a plastic flange (210), by means of which the plastic half-shell (21) is gas-tightly connected to the metal half-shell (22),! for each phase, the plastic half-shell (21) contains a half-chamber (31) protruding from the plastic flange (210), the first pair of side surfaces (31a, 31c) and the second pair of side surfaces (31b, 31d),! each side surface (31a, 31b, 31c, 31d) of the indicated first pair (31a, 31c) and the specified second pair (31b, 31d) is connected to the corresponding central supporting jumper (51) connected to the plastic flange (210),! characterized in that for each half-chamber (31) each side surface (31a, 31c) of said first pair (31a, 31c) is also connected in parallel with the central supporting bridge (51) to a pair of side supporting bridge (52) that are attached to the plastic flange (210). ! 2. The disconnector according to claim 1, characterized in that the side surfaces (31a, 31c) of said first pair (31a, 31c) are mutually opposite and alternating with the side surfaces of said second pair (31b, 31d). ! 3. The disconnector according to claim 1, characterized in that �

Description

This utility model relates to a gas-insulated MV disconnector.

In particular, this utility model relates to a three-phase, three-position disconnector with integrated grounding used for medium voltage. Disconnectors of this type are known in the prior art; see, for example, EP 1928065.

A particular disconnector of this design comprises a gas-tight enclosure that forms an interior filled with SF6 gas. Such a housing accommodates, for each phase, one or more movable contacts and one or more corresponding fixed contacts. In a typical application, the disconnector comprises, for each phase, a movable contact, a fixed contact, and a ground contact, wherein the movable contact is movable between an open position, a closed position, and a grounded position. Depending on the application, the disconnector must satisfy several requirements, which are often difficult to fulfill at the same time. For example, it is generally desirable that the disconnector be as compact as possible in order to occupy as little space as possible in which it is located.

In some cases, the disconnector may need to be enclosed between the parts forming the enclosure. For this purpose, the disconnector comprises a housing composed of a first half-housing made of metal and a second half-housing made of plastic material.

It should be noted that the disconnector containing the SF6 gas must have the ability to prevent leakage of such SF6 gas, which requires the housing to have a stable and reliable design.

Similarly, thermal performance is important, with the disconnector being the location of electrical material whose power inevitably generates heat.

The present utility model aims to increase the utility of such a disconnector.

Such great utility is achieved by means of a gas-insulated medium voltage disconnector with one or more phases, containing:

- gas-tight housing containing gas;

- for each phase, a movable contact, a fixed contact and a ground contact, which are located inside the specified housing;

- a drive mechanism for moving the movable contact between the open position, the closed position and the earthed position;

the housing comprises a metal half-shell and a plastic half-shell, the plastic half-shell is made with a plastic flange, by means of which the plastic half-shell is gas-tightly connected to the metal half-shell, in which for each phase the plastic half-shell contains a half-chamber protruding from the plastic flange, and the first pair of side surfaces and a second pair of side surfaces, with each side surface of the specified first pair and the specified second pair attached to the corresponding center an additional supporting jumper connected to a plastic flange, characterized in that for each half-chamber each side surface of said first pair is also connected, parallel to the central supporting jumper, to a pair of side supporting jumpers that are attached to the plastic flange.

It has been found that, unexpectedly, this makes it possible to achieve a structure that is particularly strong and suitable for containing SF6 gas.

Also, this design also proved the ability to effectively withstand thermal requirements.

Additional features and advantages of the present utility model will become more apparent from the description of some preferred, but non-exclusive embodiments of the present utility model, shown by way of example in the accompanying drawings, in which:

- figure 1 shows a perspective view of a disconnector in accordance with this utility model;

- figure 2 shows a perspective view with exploded parts of the disconnector in figure 1;

- figure 3 shows a component of the disconnector in figure 1;

- figure 4 shows an additional component of the disconnector in figure 1;

- figure 5 shows a perspective view with exploded parts of the composite element in figure 4;

- figure 6 shows the control panel of the electrical system on which the disconnector of figure 1 is installed.

In particular, FIG. 6 shows a control panel 10 that includes a disconnector 1 in accordance with a utility model, which, in particular, is shown in FIGS. 1-5.

Disconnector 1 is a gas-insulated switch of medium voltage, in the present case SF6 will be the gas. Disconnector 1 has three phases.

Such a disconnector 1 comprises a gas tight housing 2 comprising said SF6.

For each phase, the disconnector 1 contains a movable contact, a fixed contact and a grounding contact, which are located inside the specified housing 2.

The drive mechanism 3 is applicable for moving a movable contact between an open position, a closed position and a grounded position.

The housing 2 must also contain, in accordance with a utility model, also a pressure sensor, an exhaust valve or, in general, a pressure relief system to withstand any possible overpressure, as well as one or more inspection windows for visually monitoring the positions of the contacts.

The housing 2 contains a plastic half-shell 21 and a metal half-shell 22, which are mutually connected so as to form a housing 2.

The connection between the half-shells 21, 22 is gas-tight, so that the gas contained in the housing does not leak.

The plastic half-shell 21 is made of a polymer material, in particular epoxy.

The metal half-shell 22 is made of steel, in particular stainless steel. The metal half-shell 22 can also be made of pre-galvanized steel.

The plastic half-shell 21 comprises a plastic flange 210. In the same way, the metal half-shell 22 comprises a metal flange 220. The flanges 210, 220 are designed so as to form an interface for interconnecting the half-shells 21, 22.

Flanges 210, 220 comprise seats for sealing means, for example, a gasket type, which is known per se, in order to realize the aforementioned gas impermeability. Included are fasteners that are located on the flanges 210, 220 in such a way that it is possible to mutually fasten the half-bodies 21, 22 by means of a fastening between the flanges 210, 220. This fastening is carried out using threaded fasteners of a type that is known per se.

The plastic flange 210 is substantially rectangular with a larger size 210b and a smaller size 210a; such a plastic flange contains smoothed corners 210c.

For each phase, the disconnector 1 comprises a plastic support 41, which is connected to the plastic half-shell 21. In the same way, the metal half-housing 22 is connected to the metal support 42 for each phase.

It should be noted that each plastic support 41 is a type with three discs 41a, 41b, 41c, one located below the other, and the diameter of which decreases as the distance from the flange 220 increases.

For comparison, each metal support 42 has a substantially cylindrical shape. In this case, each metal support 42 is connected to a corresponding circular cavity 42a formed in the metal half-shell 22. However, the resulting connection is made in order to maintain gas impermeability by means of a sealing and fixing structure, which is known per se.

Preferably, an alternative is provided in which each metal support 42 is structurally and electrically connected to a voltmeter / voltage indicator.

Each plastic support 41 supports a corresponding fixed contact (not shown) located inside the housing 2, while the metal support 42 supports a corresponding movable contact (not shown) located inside the housing 2. In particular, each support 42 contains a terminal 420 that supports possibility of rotation of the corresponding movable contact. The movable support of the knife type, therefore, is applicable for moving between:

a closed position in which the movable contact is in contact with the corresponding fixed contact;

a grounded position in which the movable contact is in contact with a corresponding grounding contact;

an open position in which the movable contact is not in contact with the corresponding fixed contact and the grounding contact.

The guide rod, not shown, as it is traditional, is able to attach three movable contacts to the drive mechanism 3, which is located inside the housing 2.

According to the utility model, for each phase, the plastic half-shell 21 comprises a half-chamber 31. Such a half-chamber 31 projects from a plastic flange 210. This half-chamber 31 is connected to a connected support 41.

Each half chamber 31 represents four side surfaces 31a, 31b, 31c, 31d; each of these side surfaces 31a, 31b, 31c, 31d is attached to the upper surface 31e.

Each side surface 31a, 31b, 31c, 31d is connected to a respective central supporting jumper 51.

Each central supporting jumper 51 is connected to a plastic flange 210.

The lateral surfaces 31a, 31b, 31c, 31d are divided into:

- the first pair of side surfaces (31a, 31c);

- a second pair of side surfaces (31b, 31d).

The disconnector 1 further comprises, in accordance with a utility model, side support jumpers 52. In fact, with respect to each half-chamber 31, each side surface 31a, 31c of the first pair is also connected to a pair of the same side support jumpers 52.

In turn, each side support jumper 52 is connected to a plastic flange 210. Each side support jumper 52 is parallel with respect to a corresponding central support jumper 51.

The lateral surfaces 31a, 31c of the first pair are opposite to each other. Additionally, it should be noted that each side surface 31a, 31c of the first pair alternates with the side surfaces 31b, 31d of the second pair.

It should be noted that the side surfaces 31b, 31d of the second pair do not have side bridges.

The lateral support webs 52 associated with the side surface 31a are lateral extensions of the support webs 52 of the opposite side surface 31c.

Each side support jumper 52 has an edge formed by the following sections:

- a first edge portion 52a parallel to the plastic flange 210;

a second edge portion 52b perpendicular to said plastic flange 210;

a third edge portion 52 c located between the first and second edge portions 52a, 52b so as to describe an arc.

Moreover, each of these lateral supporting jumpers 52 has a housing divided into:

- the first half-shell 52d perpendicular to the plastic flange 210;

- the second half-shell 52e, which is attached to the plastic flange 210 in a rounded manner.

The lateral support jumpers 52 and the central support jumpers 51 have at least partially a thickness that is substantially the same relative to each other.

Each side support bridge 52 is formed on a continuation of the side surface 31b, 31d of the second pair.

It should be noted that the central supporting jumper 51 is usually located between one phase and the next.

Flange 210 has a smaller size 210a, which increases substantially parallel to the lateral support webs 52.

It should be noted that the thickness of said plastic flange 210, at least for the most part, is not greater than the thickness of the central supporting jumpers 51 and the side supporting jumpers 52.

The control panel 10 includes a cavity 101, which forms the inner space. The disconnector 1 is located in the specified inner space so that it is divided between the first compartment 110 and the second compartment 120.

The drive mechanism 3 is located outside the cavity 101 and is connected to the movable contact by means of a drive connection of the traction type.

The disconnector 1 provides housing insulation between the first compartment 110 and the second compartment 120, due to differences in the material from which the half-shells 21, 22 are made.

The most significant advantage that can be obtained thanks to a real utility model is its simplicity, but at the same time, in the strength of its design, which additionally provides amazing heat resistance.

The lateral supporting jumpers interact with the central supporting jumpers, which, due to the presence of these lateral supporting jumpers, can be more limited in size than in the state of the art.

It should be noted that the presence of many supporting jumpers provides the possibility of a certain strength, for example, if the disconnector falls. In fact, the lateral supporting jumpers prevent the deformation of the half-chambers and, therefore, make it impossible to leak SF6 gas.

It has also been observed that the lateral support jumpers in cooperation with the central support jumpers can be easily grasped by human fingers, which gives an additional unexpected advantage.

The fact that the side supporting webs are essentially located on the extension of the side surfaces of the half-chambers allows us to ensure the rigidity of the design of the disconnector.

Claims (16)

1. SF6 disconnector (1) medium voltage with one or more phases, containing:  gas-tight housing (2) containing gas;  for each phase, a movable contact, a fixed contact and a grounding contact, which are located inside the housing (2);  a drive mechanism (3) for moving the movable contact between the open position, the closed position and the grounded position; while the housing (2) contains a metal half-shell (22) and a plastic half-shell (21), the plastic half-shell (21) is made with a plastic flange (210), through which the plastic half-shell (21) is gas-tightly connected to the metal half-shell (22), for each phase, the plastic half-shell (21) contains a half-chamber (31) protruding from the plastic flange (210), a first pair of side surfaces (31a, 31c) and a second pair of side surfaces (31b, 31d), wherein each side surface (31a, 31b, 31c, 31d) of said first pair (31a, 31c) and said second pair (31b, 31d) is connected to a corresponding central supporting jumper (51) connected to a plastic flange (210), characterized in that for each half-chamber (31) each side surface (31a, 31c) of said first pair (31a, 31c) is also connected in parallel with the central supporting bridge (51) to a pair of side supporting bridge (52) that are attached to the plastic flange (210). 2. The disconnector according to claim 1, characterized in that the side surfaces (31a, 31c) of said first pair (31a, 31c) are mutually opposite and alternating with the side surfaces of said second pair (31b, 31d). 3. The disconnector according to claim 1, characterized in that the side surfaces (31b, 31d) of said second pair (31b, 31d) do not have side jumpers. 4. The disconnector according to claim 2, characterized in that the side supporting jumpers (52) relative to the side surface (31a) of the indicated first pair (31a, 31c) are located on the corresponding extension of the side supporting jumpers (52) of the opposite side surface (31c) of the first pairs (31a, 31c). 5. The disconnector according to claim 1, characterized in that each of the side supporting jumpers (52) has an edge formed by the following sections:  a first edge portion (52a) substantially parallel to said plastic flange (210);  a second edge portion (52b) substantially perpendicular to said plastic flange (210);  a third edge portion (52c) located between said first edge portion (52a) and said second edge portion (52b) and describing the arc. 6. The disconnector according to any one of claims 1 to 5, characterized in that each of the side supporting jumpers (52) contains a housing divided between:  a first half-shell (52d) substantially perpendicular to the plastic flange (210);  the second half-shell (52e), which is attached to the specified plastic flange (210) in a rounded manner. 7. The disconnector according to claim 1, characterized in that each of the side supporting jumpers (52) is defined on the extension of the side surface (31b, 31d) of the specified second pair (31b, 31d). 8. The disconnector according to claim 1, characterized in that it contains many phases, while the central supporting jumper (51) is common to two phases. 9. The disconnector according to claim 8, characterized in that the plastic flange (210) is essentially rectangular with a large size (210b), essentially perpendicular to the specified side supporting jumpers (52), and a smaller size (210a), essentially parallel with respect to the lateral support jumpers (52). 10. The disconnector according to claim 9, characterized in that the plastic flange (210) has smoothed corners (210c). 11. The disconnector according to claim 1, characterized in that the thickness of the plastic flange (210), at least for the most part, is not greater than the thickness of the central supporting jumpers (51) and side supporting jumpers (52). 12. The disconnector according to claim 1, characterized in that each side surface (31a, 31b, 31c, 31d) of said first pair (31a, 31c) and said second pair (31b, 31d) is attached to the upper surface (31e). 13. The disconnector according to claim 12, characterized in that said upper surface (31e) is attached to the corresponding plastic support (41). 14. The disconnector according to claim 1, characterized in that the metal half-shell (22) is made of steel. 15. The disconnector according to claim 1, characterized in that the plastic half-shell (21) is made of a polymeric material, in particular epoxy resin. 16. The control panel, characterized in that it contains a disconnector according to claim 1.