DE202023100030U1 - Current transformer housing with pressure relief device and current transformer - Google Patents

Abstract

Current transformer housing (1) with pressure relief device with a housing body (10) with an interior, a housing cover (20), wherein the housing cover (20) is mounted on the housing body (10) in such a way that it closes the housing body (10) in a dust- and splash-proof manner and that it lifts off from the housing body (10) in the event of an excess pressure compared to the ambient pressure, so that a pressure equalization gap (50) is created, characterized in that a protective element (30; 32; 34, 12) is attached to the housing cover (20) in such a way that, in the event of an excess pressure compared to the ambient pressure in the current transformer housing (1), the protective element (30; 32; 34, 12) covers the pressure equalization gap.

Description

The invention relates to a current transformer housing with pressure relief device and a current transformer.

Problem

In view of climate change, there is an effort to replace fossil energy generation with energy generation using renewable energy sources. The most common renewable energy sources are wind and solar. In contrast to wind energy, solar energy can also be converted into electricity by domestic and private photovoltaic systems. This electricity is used in the household that generates it or fed into a public energy supply network. In order to ensure the stability of the energy supply network even when there are many feeders, such as private photovoltaic systems, there are regulations set by operators of part of the energy supply network regarding the feed-in of electrical power. For example, an inverter that converts the direct current from a photovoltaic system or another direct current source into feed-in alternating current must feed a high level of electrical power into the energy supply network when the frequency of the energy supply network drops in order to "support" it, i.e. to try to increase the network frequency by feeding in active power. In another case, it may be necessary to feed high reactive power and/or high reactive current into the power grid.

This can lead to increased heat generation in components. In the worst case, this leads to a component temperature higher than the permissible one, which can lead to flames and/or explosions of components. Both can damage both material and people in the vicinity of an overheated inverter.

Alternatively or additionally, but above all not exclusively, arcs and short circuits can also lead to excessive heating of the interior or to the explosion of a component inside a housing. Causes of arcs or short circuits include, for example, assembly defects when assembling components of a current transformer, such as forgetting tools in the housing of a current transformer. Insulation faults, poor contact of high-current connections or overvoltages can also trigger an arc or short circuit. Furthermore, a faulty component could also trigger an arc or short circuit. In summary, there are various reasons why an arc or short circuit can occur in a current transformer.

State of the art includes automated extinguishing mechanisms with extinguishing agents in the event of flames and pressure equalization mechanisms in the event of overpressure in the inverter housing.

However, automated extinguishing mechanisms are expensive and cumbersome. Furthermore, in the case of flames and excess pressure, flames can escape into the environment through the known pressure equalization mechanisms. This poses a high risk of burns to people or fire to equipment or parts of buildings in the area.

It is therefore an object of the invention to ensure the safety of persons in the vicinity of an overheated inverter.

This problem is solved by the subject matter of the main claim, while subordinate and auxiliary claims represent aspects or further developments of the invention.

The main claim shows a current transformer housing according to the invention with a pressure relief device. The current transformer housing comprises a housing body with an interior and a housing cover, wherein the housing cover is mounted on the housing body in such a way that it seals the housing body against dust and splash water and that it lifts off the housing body in the event of an overpressure compared to the ambient pressure, so that a pressure equalization gap is created. Furthermore, a protective element is attached to the housing cover in such a way that, in the event of an overpressure compared to the ambient pressure in the current transformer housing, the protective element covers the pressure equalization gap.

This design of the current transformer housing according to the invention makes it possible for the pressure equalization gap to equalize pressure that arises, for example, due to an explosion inside the housing with the ambient pressure. The function of the protective element is to hold back flames or to cool them by dissipating heat, to prevent loose individual components from flying out of the current transformer housing and, for example in the case of pressure equalization through the pressure equalization gap without an explosion or similar, to ensure that the current transformer housing is dust and splash-proof. Injuries to bystanders or damage to equipment or parts of buildings can therefore be avoided by the current transformer housing according to the invention.

The housing body of the current transformer housing according to the invention can be a conventional housing body. Electrical, electronic and/or electromechanical devices and equipment are arranged in the housing body, which serve the intended function of the current transformer. Furthermore, the housing body is provided with openings or connections for guiding cables or lines into the housing body or for connecting devices outside the housing to devices or equipment in the housing. The housing body can be made of a plastic, a metal, a glass or even a composite material. Material properties that should be taken into account when choosing the material for the housing body are weather resistance, a permissible temperature range or even mechanical properties.

The housing cover according to the invention can also be a conventional housing cover. The cover serves mainly to close or cover the housing body so that the devices or equipment located in the housing body are protected from external influences and also from external influences. The housing cover can be made of a material described above. In particular, the housing cover can be made of the same material as the housing body, but the choice of material is not limited to this material.

In the normal state or during normal operation of the current transformer, the housing cover covers the housing body in such a way that it is sealed against dust and splash water. For this purpose, the housing cover or the housing body can be provided with a circumferential seal. Furthermore, the housing cover can be mounted on the housing body in such a way that a sufficiently large force is applied to maintain the sealing effect.

In the event that excess pressure occurs inside the current transformer housing, the housing cover is designed in such a way that it lifts off from the housing body, so that a gap is created between the housing body and the housing cover, which enables the pressure equalization of the excess pressure created in the current transformer housing compared to the ambient pressure and is hereinafter referred to as the pressure equalization gap.

According to the invention, a protective element is arranged in front of this pressure equalization gap, which prevents components thrown around by an explosion, for example, from leaving the current transformer housing or from being thrown out of the current transformer housing and thus becoming a danger to people in the surrounding area. In addition, the protective element prevents flames or fire from escaping from the current transformer housing into the surrounding area. This is achieved by the protective element cooling and/or redirecting the flames or preventing flames from escaping from the current transformer housing.

According to one embodiment, a limiter is attached to the housing body and to the housing cover, which limits the size of the pressure equalization gap and is dimensioned such that the protective element between the interior and the environment covers the entire pressure equalization gap.

To ensure that the protective element covers the pressure equalization gap, a limiter is provided in this embodiment. This is achieved by attaching the limiter to the housing body and the housing cover, thus limiting the size of the pressure equalization gap. For example, the limiter is dimensioned so that the pressure equalization gap can only be as large as the protective element is dimensioned. It is also possible for the limiter to limit the pressure equalization gap to a size that is slightly smaller than the protective element. In this way, there is an overlap area between the protective element attached to the housing cover and the housing body. In this way, the protective effect can be ensured even with an elastic protective element.

According to one embodiment, the housing body has a contact surface against which the protective element rests.

In this embodiment, the relationship between the housing body and the protective element is specified. When the protective element rests against the housing body, the protective effect of the protective element is increased even further. Furthermore, the contact surface can be processed, such as coated. It is thus possible to increase the protective and sealing effect of the protective element, for example by means of a rubberized contact surface.

According to one embodiment, the protective element is designed to be dust- and splash-proof.

If there is an overpressure in the current transformer housing and pressure equalization with the environment takes place via the pressure equalization gap, dust or splash water must be prevented from penetrating the current transformer housing and thus contaminating the interior of the current transformer housing.

The design of the protective element as dust and splash-proof prevents penetration Dust and splash water can be effectively prevented by the protective element covering the pressure equalization gap and thus covering the entire area open to the environment.

According to one embodiment, the protective element is made of a metal.

There are many advantages to making the protective element out of metal. For example, the metal protective element has good mechanical properties and can withstand any impacts or other mechanical stress. Furthermore, flames can be effectively extinguished thanks to good thermal conductivity, while a high melting point means that the protective element can be reused or at least recycled.

According to one embodiment, the protective element is made of a metal foam, a metal fabric or a metal mesh.

Metal foam, metal fabric and metal braiding have the advantage over a simple metal plate as a protective element that the surface area is larger and any flames that arise can therefore be cooled better. Furthermore, pressure equalization is more effective due to the open structure of metal foam, metal fabric and metal braiding. Furthermore, metal foam, metal fabric and metal braiding have a more elastic behavior than a solid body as a protective element, which ensures the protective effect in the event that excess pressure inside the current transformer housing is equalized with the environment via the protective element. In particular, elastic behavior also ensures that the protective element is not damaged by the excess pressure inside the current transformer housing, so that any components flying around inside the housing can still be held back by the undamaged protective element.

According to one embodiment, the protective element is designed as a labyrinth seal.

If the protective element is designed as a labyrinth seal, the path that a flame has to travel from the inside of the current transformer housing to the environment is significantly extended, whereby the flame cools down through contact with the labyrinth seal and does not erupt from the current transformer housing or at least erupts less far from the current transformer housing. Furthermore, fluid mechanics principles can be taken into account when dimensioning individual sections of the labyrinth seal, so that an intermediate section of the labyrinth seal can function as a fluid mechanics orifice or throttle.

According to one embodiment, the protective element is made of a filter fabric.

A filter fabric made of a technical textile, such as PTFE, enables excellent pressure equalization through permeability to air. Furthermore, filter fabric is very durable due to its elastic behavior and deformability and can reliably protect the interior of the housing from dust.

According to one embodiment, the filter fabric is fireproof.

If the filter fabric is fireproof, it will not melt when it comes into contact with a flame and can therefore effectively cool it or at least prevent it from leaving the current transformer housing into the environment.

According to one embodiment, the protective element is made of ceramic.

Ceramic is a particularly suitable material for the protective element because it is resistant to high temperatures. In particular, ceramic is more temperature-resistant than the material from which power converter housings are traditionally made, such as aluminum.

One aspect of the invention shows a current transformer with a current transformer housing according to one of the above embodiments. The current transformer with a current transformer housing according to the invention offers the aforementioned advantages of the current transformer housing itself. In particular, the current transformer with a current transformer housing according to the invention ensures that pressure equalization can take place in the event of excess pressure and that no flames can reach the environment in the event of ignition.

A further aspect of the invention is a protective element according to the invention as described in one of the preceding embodiments.

• 1 ein erfindungsgemäßes Stromwandlergehäuse mit einem Schutzelement zeigt,
• 1a einen in 1 mit einem Kreis markierten Bereich im Detail zeigt,
• 2 einen in 1 mit einem Kreis markierten Bereich im Detail im Fall eines Überdrucks im Stromwandlergehäuse zeigt,
• 3 einen in 1 mit einem Kreis markierten Bereich im Detail mit einem Schutzelement nach einer weiteren Ausführungsform zeigt, und
• 4 einen in 1 mit einem Kreis markierten Bereich im Detail mit einem Schutzelement nach einer weiteren Ausführungsform zeigt.

In the following, the invention is illustrated with the help of the figures, where

• 1 shows a current transformer housing according to the invention with a protective element,
• 1a one in 1 shows the area marked with a circle in detail,
• 2 one in 1 shows the area marked with a circle in detail in the event of overpressure in the current transformer housing,
• 3 one in 1 shows the area marked with a circle in detail with a protective element according to another embodiment, and
• 4 one in 1 shows the area marked with a circle in detail with a protective element according to a further embodiment.

The figures are explained in detail below.

In 1 a current transformer housing 1 is shown. The current transformer housing 1 comprises a housing body 10 and a housing cover 20. The housing cover 20 is attached to the housing body 10 via a means not shown, such as a hinge, or is placed on it. Electrical and/or electronic devices and/or apparatuses 40 are arranged within the housing body 10. A protective element 30 is arranged on the housing cover 20 near a contact area between the housing cover 20 and the housing body 10, whereupon in 1a will be discussed in more detail.

1a shows a section of the 1 circled area of the current transformer housing shown 1. In 1a It becomes clear that the protective element 30 is located near the contact area between the housing body 10 and the housing cover 20 and is attached to the housing cover 20.

2 shows the 1 encircled area in a state in which an overpressure is present in the current transformer housing 1 and achieves pressure equalization with the environment via a pressure equalization gap 50. In 2 it is visible that the protective element 30 covers the pressure equalization gap 50 in the event of pressure equalization via the pressure equalization gap 50. Furthermore, the protective element 30 can have an overlapping region with the housing body 10.

3 shows a current transformer housing 1 with a protective element 32. The protective element 32 is, in contrast to the protective element 30, made of 1 as a sponge or foam, but at least with pores. In this embodiment of the protective element 32, the protective element 32 also covers the pressure equalization gap 50.

4 shows a current transformer housing 1 with a protective element 34, 12, which is designed as a labyrinth seal. As in 4 As can be seen, the protective element 34, 12 is designed in two parts. One part 34 of the protective element 34, 12 is attached to the housing cover 20, while the other part 12 of the protective element 34, 12 is attached to the housing body 10. Between the parts of the protective element 34, 12, a constriction 34a is formed, for example, which functions as a fluid-mechanical aperture or throttle.

List of reference symbols

1

Current transformer housing

10

Housing body

12

Part of the protective element

20

Housing cover

30

Protective element

32

Protective element

34

Part of the protective element

34a

bottleneck

40

Electrical and/or electronic devices and/or equipment

50

Pressure equalization gap

Claims (11)

Current transformer housing (1) with pressure relief device with a housing body (10) with an interior, a housing cover (20), wherein the housing cover (20) is mounted on the housing body (10) in such a way that it closes the housing body (10) in a dust- and splash-proof manner and that it lifts off from the housing body (10) in the event of an excess pressure compared to the ambient pressure, so that a pressure equalization gap (50) is created, characterized in that a protective element (30; 32; 34, 12) is attached to the housing cover (20) in such a way that, in the event of an excess pressure compared to the ambient pressure in the current transformer housing (1), the protective element (30; 32; 34, 12) covers the pressure equalization gap. Current transformer housing according to Claim 1 , wherein a limiter is attached to the housing body (10) and to the housing cover (20), which limits the size of the pressure equalization gap (50) and is dimensioned such that the protective element (30; 32; 34, 12) between the interior and the environment covers the entire pressure equalization gap (50). Current transformer housing according to Claim 1 or 2 , wherein the housing body (10) has a contact surface against which the protective element (30; 32; 34, 12) rests. Current transformer housing according to one of the preceding claims, wherein the protective element (30; 32; 34, 12) is designed to be dust- and splash-proof. Current transformer housing according to one of the preceding claims, wherein the protective element (30; 32) is made of a metal. Current transformer housing according to Claim 5 , wherein the protective element (30; 32) is made of a metal foam, a metal fabric or a metal braid. Current transformer housing according to one of the Claims 1 until 4 , wherein the protective element is designed as a labyrinth seal (34, 12). Current transformer housing according to one of the Claims 1 until 4 , wherein the protective element (30; 32) is made of a filter fabric. Current transformer housing according to Claim 8 , whereby the filter fabric is fireproof. Current transformer housing according to one of the Claims 1 until 4 , wherein the protective element (30; 32; 34, 12) is made of ceramic. Current transformer with a current transformer housing according to one of the preceding claims.

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