NO317119B1 - Fire extinguisher switch - Google Patents

Abstract

The MV load breaker switch has an arc extinction chamber, a movable switch blade (11), a pressure chamber and an expansion chamber with an opening which can be at least partially closed, the closable opening area providing an auxiliary opening (9) in the form of a slit, for passage of the switch blade shaft.

Description

SWITCH WITH EXTINGUISHING CHAMBER

The invention relates to a switch with an extinguishing chamber, in particular a medium-voltage load-disconnecting switch for voltages between 6 and 36 kV.

In order to cause arcs when the contacts of a switch-disconnector are opened to go out as quickly as possible, it is known to arrange extinguishing chambers in a secondary current path, where current flows only briefly immediately after opening the main contact via a lagging contact which is temporarily in the switch-on position. A contact or switch pin or -knife arranged movably in the extinguishing chamber breaks the by-current circuit. The resulting arc is extinguished in the extinguishing chamber.

The knife- or pin-shaped contact or switch pin is arranged between bodies which emit gas when heated (hard-gas principle). When engaging and disengaging, the pin or the knife moves through between these bodies. Under the influence of the heat emanating from the arc that occurs during interruption, on the one hand through heating of the air in the extinguishing chamber, on the other hand through the development of gas, a pressure builds up which produces a gas flow which is to cool and extinguish the arc as quickly as possible.

The requirements for medium-voltage switchgear are constantly increasing. While switchgear systems, which "uptime" master 20 load interruptions, have been common on the market until now, 100 load interruptions are now required at voltages of 12 and 24 kV and a current of 630 A. In order to be able to switch off more and more power more and more often, it is necessary to build larger and more pressure-resistant extinguishing chambers that are dimensioned in such a way that the extinguishing gas required for extinguishing the interrupting arc is made available in the necessary quantity, and that the chambers hold up against the pressure that occurs during the interruption. However, since space is very limited in medium-voltage switchgear systems, and the system dimensions are decisively determined by the size of the switchgear, the dimensions of the switchgear systems, despite the increased requirements for interrupting performance, cannot be significantly increased.

Therefore, it is now common for reasons of space to build different extinguishing chambers for each of the voltage ranges (10, 20, 30 kV), in order to be able to build the switches for the relevant voltage range as small as possible.

There are extinguishing chambers, for example known from the German publication 195 40 552 or from the German publication 195 22 852, which were also developed under the aspect of the smallest possible space requirement.

Thus, the German publication 195 40 552 describes an extinguishing chamber integrated in a supporting insulator, which extinguishing chamber is in each case located between the supporting insulators of a pole. The switch pin located in the extinguishing chamber is pulled along a straight path out of the extinguishing chamber for disconnection. This rectilinear movement requires a relatively large amount of space, as at least the length by which the switch pin is pulled out of the chamber must be kept free outside the extinguishing chamber in its extension for switching movements.

FR patent 2034118 and US patent 3671697 both describe load disconnect switches which comprise a movable switch blade, a pressure chamber, an expansion chamber and at least a partially closable opening in the expansion chamber. Due to their respective designs, the device according to FR 2034118 and US 3671697 has a relatively large overall length.

To reduce this space requirement, the German publication 195 22 852 proposes a tubular extinguishing chamber with a switch pin, both of which have the shape of a circle segment. The switch pin is linked via connections to a pivot point in such a way that it carries out a movement which lies on the predetermined circuit path through its own and the shape of the extinguishing chamber. In order to pull the switch pin out of its contact position and out of the extinguishing chamber, substantially less space is required than with the previously described extinguishing chamber.

The extinguishing chambers described still do not meet today's requirements for medium-voltage switchgear systems for 100 load interruptions among the power conditions specified above.

Against this background, the invention proposes the problem of building a pressure-resistant extinguishing chamber which holds up against the required interrupting performance, which requires the least possible space, and which can be used as universally as possible.

To solve this task, an extinguishing chamber with the features specified in the main requirement is proposed. Advantageous embodiments can be seen from the dependent claims.

Through the device according to the invention, it becomes possible to include switch blades in the extinguishing chamber, so that the extinguishing chamber could be designed larger in order to comply with the increased performance requirements, without the space requirement for the switch blade plus extinguishing chamber being increased overall, so that despite the increase in performance, the existing grid dimensions of the switching cell can be observed. Existing medium voltage switchgear can thus be easily retrofitted with the devices according to the invention.

In addition to this, the extinguishing chamber according to the invention is designed so that it can be used for different voltages, for example for 12 and 24 kV. By the fact that an extinguishing chamber can be used for several voltage ranges, a significant cost advantage arises.

Within the extinguishing chamber, bodies of material which give off gas when heated are provided in a manner known per se. These can be plate-shaped and when switched on press against the switch pin or the tip of the knife contact. Any further form of these bodies can be imagined.

In the following, the invention is explained in more detail with the help of the examples of embodiment shown in the drawings. Fig. 1a shows a cross-section through an extinguishing chamber in the disengaged state; Fig. 1b shows a section through an extinguishing chamber according to Fig. let along line A - A; Fig. 2a shows a cross-section through an extinguishing chamber according to fig. la, where the switch blade is in an intermediate position between the engaged and disengaged state; Fig. 2b shows a section through an extinguishing chamber according to fig. 2a along line A - A; Fig. 3a shows a cross-section through an extinguishing chamber according to fig. leave in engaged state; Fig. 3b shows an elevation of an extinguishing chamber according to fig. 3a from direction A; Fig. 4a shows a cross-section through a further embodiment of an extinguishing chamber, in the engaged state; and Fig. 4b shows an elevation of an extinguishing chamber according to Fig. 4a from direction A.

In fig. 1a, an extinguishing chamber 1 is produced which consists of a housing 2, which is divided into a pressure chamber 3 and an expansion chamber 4, which are separated from each other by a wall 5 with an opening 6. In the pressure chamber 3, it is located on the side which faces away from the expansion chamber 4, a fixed contact 7.

The expansion chamber 4 has, on the side opposite the wall 5, an opening 8 which also extends into the lower area of the expansion chamber 4 and there, so to speak, forms an additional opening 9.

The openings 8 and 6 serve as passages for the contact tip of a movable switch blade 11 in the secondary flow path via the pressure chamber 3 and the expansion chamber 4 up to the contact 7; the breaker knife is held in the engaged position via a nose 12 which hooks behind it. The switch knife 11 is in fig. la manufactured only partially, namely with its contact tip lia which is connected to the pivot point B via a correspondingly curved shaft part 11b, so that the knife moves along a circular path during engagement and disengagement.

In the pressure chamber 3, extinguishing plates 10 of material which emit gas when heated are arranged, which plates are pre-tensioned with springs 21, so that they are pressed against each other. The switch blade 11 moves through between them during engagement and disengagement and thereby touches them.

The switch or separating knife 11 is, as the plans show, designed flat. In order for the extinguishing chamber to be able to comply with the requirements regarding the number of interruptions due to the aforementioned effects (voltages and currents), it was necessary to increase the extinguishing chamber volume, which is achieved in a surprisingly simple way with the invention while complying with the switch dimensions and maintaining the cell grid by not only the contact tip 11a dips into the extinguishing chamber, but at least partially also the breaker or separating knife shaft 11b.

This is made possible by part 9 of the opening 8, i.e. the additional opening according to the invention. During the connection, i.e. when the switch blade 11 is moved away to the fixed contact 7, first a holding part 13 and then the contact tip of the switch blade 11 pass through the rearward-directed part of the opening 8. However, as soon as the switch blade 11 has reached the position depicted in fig. 2a, b, its shaft 11b also enters the chamber area, namely in the additional opening 9 of the opening 8, and this the longer, the further it approaches the fixed contact 7.

In order for the extinguishing chamber, in spite of the additional opening 9 in the expansion chamber 4, to reliably fulfill its task, namely to extinguish the arc that occurs upon disconnection, the area 9 of the opening 8, i.e. the additional opening in the one in fig. la,b produced disconnected state, closed by two flaps 14 which for example consist of insulating material. As can be seen from fig. lb, the flaps 14 are movably attached to the underside of the extinguishing chamber 1, namely at points C. Each of them has the shape of a circle segment and overlaps each other in the disengaged state, as they close the area of the additional opening 9. In a preferred embodiment, they are spring-loaded, so that without an external force acting on them, they occupy the in fig. lb manufactured condition. The extinguishing plates 10 lie next to each other in the disengaged state.

As soon as the switch is now closed via the switch blade 11, i.e. the point B moves away to the fixed contact 7, and it thereby, as previously described, enters the expansion chamber, hitting its shaft 11b sooner or later, as shown in fig. 2a,b, on the flaps 14 and then press these apart against the spring force acting on them, so that they gradually open the initially closed additional opening 9, and the breaker knife 11 thus in the engaged state still protrudes from the extinguishing chamber only through the additional opening 9.

This condition is depicted in fig. 3a,b. The flaps 14 are now fully opened, so that they release the additional opening 9. They are held by the switch blade shaft 11a in this position, while the switch blade contact tip 11a pushes the extinguishing plates 10 apart.

On disconnection, i.e. when the switch blade 11 is separated from the contact 12 and thereby from the fixed contact 7, the switch blade 11 and flaps 14 complete the opposite course of movement. The further the breaker knife 11 moves out of the extinguishing chamber 1, i.e. performs a counter-clockwise turning movement about the point B, the more it retracts out of the additional opening 9, so that the flaps 14, through the spring force acting on them, little by little assume the starting position shown in fig. la,b and again closes the additional opening 9.

The additional opening makes it possible for the sickle-shaped breaker knife 11 that its path of movement lies mostly in the extinguishing chamber 1, so that with the same space requirement for the extinguishing chamber 1 according to the invention compared to known extinguishing chambers, a significantly larger chamber volume is achieved.

Through the flaps 14 which move depending on the position of the switch blade 11, the extinguishing process of an arc that occurs upon interruption becomes significantly more efficient. At the time when the arc occurs, i.e. when the switch knife 11 from its locked position (cf. Fig. 3a,b) just begins to separate from the contact 7, the flaps 14 are opened, so that a relatively large amount of oxygen can penetrate into the extinguishing chamber 1, especially also into the pressure chamber 3. This oxygen is also welcome at the beginning of the extinguishing process, as this requires the fastest possible development of the arc from the small initial flame, so that the evaporation process caused by the arc can very quickly start on the extinguishing plates, and the gases that occur now quickly and efficiently extinguish the arc. The further the breaker knife 11 now moves out of the extinguishing chamber, the more the flaps 14 close and thus prevent, on the one hand, a further supply of oxygen and, on the other hand, an outflow of the gases from the extinguishing chamber downwards, which could lead to ionization of the area between the phases and also to earth and thus to overshoot (short circuit). Through the slit opening 8 adapted to the extinguishing process, the extinguishing gases are controlled so that ionization of the insulation section is excluded.

Moreover, the initially relatively large and then gradually closing additional opening 9 has an accelerating effect on the extinguishing gases that arise in the pressure chamber 3, which, especially in the flow-poor initial phase through vortex formation, causes a more efficient cooling and thus a more reliable extinguishing of the arc. The closing speed of the additional opening 9 can be varied and set in particular through the shape of the flaps 14.

The features according to the invention thereby also significantly increase the efficiency of the extinguishing chamber.

In fig. 4a,b, a further exemplary embodiment of an extinguishing chamber according to the invention is shown, where the parts corresponding to those in the exemplary embodiment according to fig. 1 to 3, are denoted by the same reference numerals. The design example according to fig. 4a,b differ from the previously described embodiment by a different closing mechanism for the additional opening 9.

Instead of the flaps 14, a plate or a strip 15 of insulating material is used here. This is fixed at 16 in the contact end of the extinguishing chamber 1 and closes the entire additional opening 9 when the switch is disconnected. When closing the switch knife 11, its shaft presses the plate or the strip 15 against the action of a spring 17 into the housing 2 in the direction of the attachment point 16, whereby the additional opening 9 be released. The operation of this embodiment is the same as that described previously. Corresponding to the position of the switch blade 11, the additional opening 9 is opened or closed by the plate or strip 15. In the pressure chamber 3, extinguishing plates 10 of material which emit gas when heated are correspondingly provided.

Claims (12)

1. Switch with extinguishing chamber (1), in particular for medium-voltage load-disconnectors for voltages between 6 and 36 kV, with a movable switch blade (11), a pressure chamber (3), an expansion chamber (4) and an at least partially closable opening (8) in the expansion chamber (4), characterized in that the partially closable opening is formed by the opening (8) in the side part of the expansion chamber (4) and an additional opening (9) in the lower area of the expansion chamber (4), and where the closable part of the opening is formed of the additional opening (9) which serves for the passage of a separating knife shaft (11b), the additional opening (9) being arranged to be able to be closed with at least one flap (14), where the flap (14) is rotatable about an approximately vertical axis in the expansion chamber's ( 4) wall where the additional opening (9) is located. 2. Switch according to claim 1, characterized in that the additional opening (9) has a slot shape. 3. Switch according to one of claims 1 or 2, characterized in that the width of the opening (8, 9) corresponds to the thickness of the separating knife (11). 4. Switch according to one of claims 1 to 3, characterized by two flaps (14) which overlap each other when closing. 5. Switch with extinguishing chamber (1), in particular for medium-voltage load-disconnectors for voltages between 6 and 36 kV, with a movable switch blade (11), a pressure chamber (3), an expansion chamber (4) and an at least partially closable opening (8) in the expansion chamber (4), characterized in that the partially closable opening is made up of the opening (8) in the side part of the expansion chamber (4) and an additional opening (9) in the lower area of the expansion chamber (4), and where the closable part of the opening is made up of the additional opening ( 9) which serves for the passage of a separating knife shaft (11b), as the additional opening (9) is designed to be closed with a plate that can be moved along the additional opening (9) or a strip (15). 6. Switch according to one of claims 1 to 5, characterized in that the flaps (14) and also the plate or the strip (15) consist of insulating material. 7. Switch according to one of claims 1 to 6, characterized in that the flaps (14) and also the plate or strip (15) are spring-loaded. 8. Switch according to one of claims 1 to 7, characterized in that the additional opening (9) is open in the engaged state. 9. Switch according to one of claims 1 to 8, characterized in that the additional opening (9) is closed in the disconnected state. 10. Switch according to one of claims 1 to 9, characterized in that the flaps (14) and also the plate or strip (15) are operated via the switch blade (11). 11. Switch according to one of claims 1 to 10, characterized by a switch blade (11) which moves in a circular path. 12. Switch according to one of claims 1 to 11, characterized by spring-loaded extinguishing plates (10) in the pressure chamber (3).