EP1836752B1 - Lightning arrester comprising two divergent electrodes and a spark gap acting between the electrodes - Google Patents

Abstract

Lightning arrester has spark gap acting between two divergent electrodes and auxiliary sliding device for electric arc, which is active on electrode arc. Mobility of electric arc is increased directly after the ignition thereof, by means of combination of measures for reinforcing inherent magnetic field related to electric arc, and phased gas circulation (7) of encapsulated conducting lead.

Description

The invention relates to a surge arrester with two diverging electrodes and a spark gap acting between the electrodes, a housing, an effective at the Elektrodenfußpunkt sliding aid for the arc and means for magnetic blowing of the arc according to the preamble of patent claim 1.

In low-voltage networks, overvoltage arresters based on self-extinguishing spark gaps are used in many cases to protect against overvoltages between two active conductors. These spark gaps also serve to protect against direct lightning strike and must therefore have a high surge current discharge capacity. In addition, there is a demand for high system availability, i. Even with overvoltage, even with lightning, an undisturbed power supply should be made via the mains. This requires from the surge arresters the highest possible follow current extinguishing capacity and also an effective follow current limiting, so that the triggering of the overcurrent protection elements of the network can be avoided. Due to the ever more compact design of the installation environment of the surge arrester, in addition to an installation-friendly design of modern devices, the avoidance of the release of ionized gases into the environment when responding is required.

Avoiding the delivery of ionized gases to the environment results in dramatically higher power transfer in the spark gap. In Ausblasenden spark gaps are sometimes discharged over 90% of the energy converted in the form of hot gas to the environment. The desired follow current limitation and the associated high arc voltage also requires a higher energy conversion in the spark gap. This compared to previous surge arresters significantly higher power conversion requires both complex designs and more powerful or burn-resistant and costly materials. By the with the energy input Associated aging of all parts used is also the realization of the main tasks of the arrester, namely on the one hand to maintain a reproducible response voltage in overvoltage and on the other hand to form a highly insulating route under normal network conditions difficult.

It is known from the prior art that, in the case of spark gaps with diverging electrodes, the arc has the tendency to migrate away from its place of origin owing to its own magnetic field. It is also known that the sensitive ignition region, which often has a sliding section made of ceramic or polymers or the like, can be protected from the power conversion, in particular by the subsequent current, at least over a certain period of time as a result of this path migration. Reducing the load on pulse currents is difficult due to physically related arcing times of up to several 10μs. In addition to the effect of reducing the stress on the ignition region, divergent electrodes often use the extension of the arc for subsequent current quenching due to the increase in the arc voltage.

Currently known surge arrester with divergent electrodes and high lightning impulse current and high follow-current extinguishing capacity are designed ausblasend.

Due to the escape of hot ionized gases, such arresters can endanger neighboring plants. For example, with respect to the prior art on the EP 0 706 245 A2 , the DE 44 02 615 A1 , the DE 44 39 730 C2 and the U.S. Patent 2,608,599 directed.

In order to reduce the risk of the environment by the blow-out, further known surge absorbers of Hörnerstrecken-type have one or more, the arc chamber downstream rooms in which the temperature of the gas is cooled before blowing out of the trap. Such solutions are for example in the EP 0 860 918 A1 or the WO 2004/015830 disclosed. Change the known measures for these arresters but not the principle of Ausblasenden design and are able to reduce the existing hazard only, but not completely eliminate. In particular, the effect of the gas pressure wave can be reduced only conditionally by the known measures.

Staple trunks for the medium voltage range, as they are often used in a series circuit, occasionally have Isoliersteg- and also splitter chambers, but are not designed for lightning currents of high amplitude and today usual DIN rail mounting. Such spark gaps are generally used in a series circuit with varistors, which take over the current limit to a large extent. The movement of the arc is supported in prior art devices with series-connected high inductance blow coils. In addition to these puffing coils, the housings, and in particular the electrodes, are made of materials which can not control significant lightning currents.

For an effective following current limitation with spark gaps an arc voltage in the range of the mains voltage is necessary. In known Ausblasenden arresters in the low voltage range with diverging electrodes, the required arc voltage is achieved by means of quenching plate assemblies, the division of the arc into several partial arcs and the extension of the arc. In addition to the blowing out of the ionized gases, the known lightning current-carrying spark gaps have further disadvantages.

Thus, the arc must cover relatively long distances to run into the splitter plate chamber, whereby the arc voltage at the beginning of the follow current is low and thus the follow current can rise almost unaffected and the follow current limit reaches only low values in this phase. The current thus attains high instantaneous values, the reduction of which is again very expensive.

The running into a high number of quenching plates and possibly also the division into partial arcs causes despite the relatively long duration of the arc until reaching the quenching chamber a nearly jump-like increase the arc voltage. This often leads to the back-firing of the follow-current arc at thermally heavily loaded areas, such as the ignition of the arc, which was also exposed to the previous pulse impulse current or at structurally related deflection of the arc running path, which often leads to prolonged persistence of the arc.

However, these restrikes lead to repeated collapse of the arc voltage and thus to longer arc times and higher Durchlaßintegralen.

Due to the Ausblasenden design of these known arrester arc runs in spite of multiple flashbacks in general again into the quenching chamber.

The functional principle of this incoming follow current extinction corresponds largely to that of low-voltage circuit breakers. Low-voltage circuit breakers of comparable size and follow-up current quenching capacity currently have largely free exhaust openings. Compared to spark gaps switch have the advantage that the movement of the arc is promoted by the opening and the immediate extension of the arc to the arc chamber. The mobility of a short arc, as it arises due to the short distances at spark gaps, however, is limited.

Furthermore, spark gaps have the disadvantage that the ignition can start with a high pulse current and thus abruptly creates an extremely high pressure load, especially in an encapsulated design, which greatly influences the beginning and the movement of the arc. However, this generated pressure build-up is not only faster, but often also significantly higher than due to the limiting follow-on currents in switching devices.

From the GB 957 359 A a surge arrester is previously known, which has two diverging electrodes and a spark gap acting between the electrodes in a housing. Furthermore, a quenching chamber is present. By generating a magnetic field, it is possible to increase the arc length and to improve the extinguishing behavior, which also serves for a gas circulation.

In summary, currently dominating Ausblasende design variants in order to circumvent the resulting encapsulation of these devices disadvantages from the outset. An encapsulation basically leads to a drastic reduction of the performance and the life up to the total failure of corresponding devices.

When encapsulating a surge arrester, but also a circuit breaker with diverging electrodes, the following problems arise among others.

When the arc is ignited, the pressure in the spark gap increases. This causes an extension of the arc retention time and a reduction in the speed of this. The sudden build-up of pressure in encapsulated housings leads to reflections of pressure waves. The arc runs against its own pressure wave and the density of the gas to be displaced increases. This can cause the force of the arc's intrinsic magnetic field to be insufficient to move the arc along the electrodes. Thus, the entry of the arc takes place in the splitter plate very late or not at all, whereby a rapid follow current limiting can not be guaranteed.

From the foregoing, it is therefore an object of the invention to provide a further developed surge arrester with two diverging electrodes and a spark gap acting between the electrodes, wherein the arrester to be created is executed encapsulated and in addition to a lightning current carrying capacity high follow-stream extinguishing and limiting capacity has an amplified arc-related internal magnetic field has.

The object of the invention is achieved by a surge arrester according to the teaching of claim 1, wherein the dependent claims include expedient refinements and developments.
Accordingly, the mobility of the arc is increased immediately after its ignition by a combination of measures to increase the arc-related intrinsic magnetic field and a staggered gas circulation of the encapsulated executed arrester.

For this purpose, at least one of the electrodes for supporting the arc movement is deposited with a ferromagnetic material. Furthermore, an arc chamber is formed within the housing, the electrodes at least partially enclosing, wherein the chamber walls are made of ferromagnetic material or the chamber walls are deposited isolated with a ferromagnetic material. By the above measure, the firing and running range of the arc between the electrodes is substantially U-shaped by the ferromagnetic material.

In addition, the running behavior at the divergent electrodes is improved by a targeted and staggered gas circulation in the spark gap, which also reduces the pressure reflection and supports the guidance of the arc in a gap-like chamber.

Also, the shrinkage of the arc in the current limiting device can be improved in addition to the measures mentioned by the design of the arc inlet region.

Specifically, the electrodes have recesses in the running region of the arc, through which a gas flow reaches the interior of the arc chamber in order to assist the arc movement.

The arc chamber walls have further recesses through which a gas flow is guided to support the arc movement in the interior of the arc chamber.

Also for targeted gas supply, the electrodes in the base area each have a bore or the like opening. The bore or the opening is in communication with a groove which is present on the inside of the electrodes, wherein gas can be supplied to the deionization via the bore and the groove of the ignition point of the arc.

According to the invention, the arc chamber joins a deion chamber, the deion chamber having an inlet facing the diverging electrodes and a plurality of lateral, slot-shaped outlet openings.

Between the lateral, slot-shaped outlet openings of the Deionkammer and the recesses in the arc chamber and the bore in the electrode base gas-carrying channels are provided.

In the channel, which leads to the hole in the electrode base, cooling cascades are provided or this channel is meandering for cooling the gas.

The gas which reaches the hole in the base of the electrode can be mixed with ambient air and thereby also cooled.

For gas mixing, a mixing chamber is arranged below the base of the electrode, which has one or more bores of small cross-section which also act in a pressure-compensating manner to the environment.

The holes in the electrode base reach into the mixing chamber or have a corresponding connection to this.

In the area of the electrode base, a magnet for promoting the movement of the arc can furthermore be arranged.

The aforementioned gas-carrying channels are isolated from each other and performed separately to ensure a targeted flow feedback and circulation to the ignition and the running range of the arc.

For defined setting of the gas flow, the channels may have certain predetermined cross-sectional areas.

In a further embodiment of the invention, a bluff coil may be provided for assisting and amplifying the magnetic field at subsequent currents be, which forms a shunt to one of the electrodes, wherein in the arc running direction before the connection point of the coil, the relevant electrode has a high-impedance section or an insulation section.

Thus, the retention time of the arc is low and the Lichtbogenfußpunktbildung and the arc motion can be accelerated, the effect of the intrinsic magnetic field is already increased near the ignition of the arc according to the invention.

This can be done by the widest possible current loop of the current-carrying contacts to the ignition. Through the use of additional magnetic fields by blowing coils or magnets or even by a deposit or U-shaped sheathing of the electrodes with iron or other ferromagnetic substances further amplification of the desired effect is possible.

The proposed measure of the deposit of the electrodes with ferromagnetic material to support the arc movement is both easy to implement and inexpensive to implement. These materials may be electrically conductively connected to the divergent electrodes. However, it is expedient to have an insulated arrangement. In particular, this increases the magnetic field at the base of the arc, ie directly at the electrodes.

In a further embodiment of the invention, it is proposed to integrate ferromagnetic materials into the electrodes of erosion-resistant material directly behind or next to the arc running surface. If the ferromagnetic material is integrated directly next to the preferred arc running surface, the material can be covered with an insulator to avoid negative signs of wear. The mobility of the arc root can also be supplemented or increased by the deposit or integration of permanent magnets in one or both electrodes.

Studies have shown that even higher arc mobility is achieved by this, although the arc column one movement supporting magnetic field is exposed. This can be achieved, for example, by the proposed U-shaped jacket of one of the electrodes and of the entire discharge region between the two diverging electrodes. The field lines generated by the arc in the ferromagnetic material close by the arc between the electrodes and thus generate a targeted force on this. Here it is expedient if the one electrode without a U-shaped casing has no ferromagnetic deposit or deposits, since otherwise the field lines close over this material, whereby the effect on the arc column is reduced. The U-shaped enclosing of the electrode can replace or supplement the deposit with ferromagnetic material.

Also ausgestaltend the ferromagnetic material may be interrupted for design reasons, or from the deposit of the one electrode and two plates or an L-shape and a plate next to the diverging electrodes are formed.

The retention time of the arc can be further influenced by the choice of the electrode material expediently. Thus, it is particularly advantageous if the electrodes each consist of different materials or of alloys or sintered materials.
Furthermore, inhomogeneities of the surface have a positive effect. These can also be material-related. Microscopic or even macroscopic structures which are parallel to the direction of the arc are particularly advantageous. The higher field emission caused by these measures promotes a sudden movement of the arc root points, whereby the migration speed can be increased.

Also, the Fußpunktwanderung can be supported on the rails by tread design, in particular, edges in the direction of positive effect. Furthermore, the rails may consist of layered in the same direction or the same different materials, whereby the lateral direction to the running direction is reduced. The rail material may contain high and low melting components or be composed of these, so that edges or peaks arise in the direction of movement, to which the arc root preferably jump, whereby the arc speed increases and the retention times are reduced. Fiber metals, layer metals or corresponding laminates are conceivable here.

The above-described measures reduce the tendency of the arc to persist and promote the initial movement of the same. After the starting phase, the arc should be extended as quickly as possible and fed to the quenching chamber. However, the continuous movement is counteracted by the increased pressure and the reflected pressure waves in the encapsulated trap.

In order to achieve an effective current limitation in encapsulated spark gaps with diverging electrodes, it is proposed to guide the arc within an as short time as possible in an arc chamber, in which the arc voltage is increased so much that the instantaneous value of the mains voltage is reached or exceeded.

In principle, all systems known from low-voltage circuit breakers can be used as the arc chamber. These include, inter alia, Isolierstegkammern, Löschblechkammern, Deionkammern, Mäanderkammern and their combinations. The operation of these chambers is based on the extension, the cooling and in part the division of the arc.

According to the invention, in addition to the support of the running behavior of the arc by the explained magnetic fields, it is now forced to enter the obstacle arc chamber or deion chamber.

However, the prerequisite for an effective effect is efficient gas circulation and cooling, which supports the movement of the arc to and into the arc chamber.

For this purpose, constructive measures according to the invention are implemented, which allows the gas circulation in several circles with different functions.

Both the gas outflow from the arc chamber and the gas recirculation into the arc chamber via at least two channels.

The return and cooling of the hot gases is preferably carried out laterally adjacent to the arc chamber. The return of the cooled gases takes place to a small extent directly in the ignition region of the arc between the diverging electrodes and their base and serves for deionization in this area.

So that the risk of re-ignition is reduced by still hot gases, the small amount of gas that is fed into this area, passes through an additional area for intensive cooling. In this area, the gas is passed through narrow channels, preferably made of metal with a high heat capacity. In a massive design of the electrodes or the ferromagnetic deposit of these electrodes, these channels can be integrated without additional space in them. A necessary for encapsulated trap pressure equalization port of small cross-section can be mounted so that it is in communication with the channel with the intensely cooled gas.

The return of the much larger amount of gas, which forms the main circulation circuit, via separate channels on the side of or adjacent to the divergent electrodes above the ignition point, but below the inlet region in the arc or Deionkammer. This supply can be made via one or more channels along the rails. Particularly favorable for this feed is the electrode area, which lies practically above the main area of the pulsed current load. The arc thus enters this area only after overcoming the retention time and a certain running distance along the divergent electrodes. In this initial area is the support of the arc movement due to the intrinsic magnetic field, the ferromagnetic deposit of the electrodes and possibly gas-emitting sliding aids still sufficient.

The staggered gas recirculation avoids that long-lasting pulse currents are prematurely excited or cooled to an accelerated movement, whereby the power consumption and the load of the spark gap can be limited. As a result of the gas circulation, essentially only the follow-current arc is supported in its movement before it enters the quenching chamber. By the nature of the gas supply not only the arc column is detected, but also for the movement of the arc with responsible Fußpunktbereiche on both electrodes.

In order to increase the effect of the gas flow on the arc column, the running range of the arc to the quenching chamber is designed largely gap-like. This makes it possible to achieve that even arcs with relatively low amperage have a cross section in the region of the gap width and thus the gas can not flow alongside the arc, but the greatest possible force is exerted on the arc.

On the one hand, the running behavior of the arc along the electrodes is accelerated by the smallest possible gap width. On the other hand, the gap formation in this running range does not lead to an extreme reduction of the cross section compared to the area of the momentum discharge, since otherwise strong pressure reflections could already occur in this lower running range, which negatively influence the running behavior.

The cross section of the arc discharge space in the ignition region is essentially determined by the desired height of the pulse to be controlled and the compressive strength of the electrodes and wall materials.

In one embodiment of the invention, it is possible to store the chamber walls elastically. As a result, the chamber walls can move laterally under strong pressure loads. This measure will be simultaneously reduces the risk of an electrically conductive connection between the electrodes via the lateral chamber walls.

According to the invention, the gas outlet from the arc chamber is not only above the quenching chamber, but already staggered in the course of the quenching chamber with lateral versions. The designs are isolated at splitter plate or Deionkammern so that the spread of the arc can be prevented. Likewise, the ends of the metal plates of the quenching chamber are protected by insulating distances before the arc spread. The hot gases are passed after leaving the quenching chamber in channels, which preferably extend on both sides parallel to the arc chamber. In these channels, the gas is cooled and then fed to a relaxation space, from which the supply takes place in the arc chamber in the manner described.

The surface of the intended channels and cavities should be as large as possible and the wall materials should have a high heat capacity and thermal conductivity. As inner walls can thus serve the magnetic baffles or, if present, and the ferromagnetic U-shaped shell of the quenching chamber, whereby this simultaneously assumes two functions.

Further support for the effectiveness of the ferromagnetic materials may be provided by a complete U-shaped envelope of the entire arc region. This closed ferromagnetic cladding exerts an attractive effect on the arc. To prevent eddy currents, which have an inhibiting effect on the movement of the arc, the sheath should be suitably laminated. So that it does not come to the short circuit of the arc over the envelope, it must be insulated on the inside thin-walled with arc-resistant material. Ideally, this insulation can be carried out as an insulating gap, meandering chamber or Isolierstegkammer. Depending on the design, this embodiment ensures a gradual or also a sudden increase in the arc voltage when entering the gap region. Will the insulation material still designed from gas-emitting substances, an additional pressure increase and thus an immediate increase in the arc voltage can be effected.

To increase the extinguishing capacity of the arc chamber, an additional introduction of Deionblechen in the isolation chamber makes sense. Ideally, however, they should have a different height, so that the number of partial arcs only gradually, i. time-delayed increases. Alternatively, the inlet slots of the sheets can be designed differently or asymmetrically, to force a gradual division of the arc.

The inlet of the arc into the quenching chamber should be forced immediately after the ignition range of the arc or after a very short acceleration distance, otherwise no effective current limitation is possible.
However, the shorter the lead-in area, the higher the risk of re-ignition in the region of the ignition range of the spark gap, since the cooling and the deionization of the ignition range within a short period of time and limited possible. To reduce this risk, an extension of the acceleration section or a deflection of the arc is possible. The arc propagation can be tilted by a certain angle to the emergence of the arc or it can be the arc, for example, in a meandering chamber and laterally offset to its place of origin. With these measures, a direct beam effect of the arc on the ignition is avoidable.

With regard to the magnetic field amplification further possibilities are proposed. In particular, so-called blister coils can be used according to the invention. At DC, a homogeneous, independent of the current field field can also be realized by the use of permanent magnets. Furthermore, the leadership of the connections to the firing point can be designed so that an additional force the arc in the Chamber pulls. It is conceivable here, for example, to put a connection loop around the quenching chamber.

When using blown coils, e.g. with magnetic baffle the number of turns must be measured quite small due to the high lightning impulse currents and the size, creating a strong magnetic field only at relatively high currents. However, since these high currents are just to be severely limited, it is advantageous even at relatively low currents already have a strong magnetic field.

In the above sense, it is proposed that the surge current flowing as a result of the ignition of the spark gap, is led via a separate lead without a blowout coil or a separate winding coil winding with low number of turns to ignition point and that the follow current through a blow coil with a relatively high number of turns to lead, which already generates a strong magnetic field at low currents. Technically, this is realized by two power supply to at least one spark plug or an electrode. For this purpose, the electrode is interrupted at one point in an electrically conductive manner or high-resistance. After the arc has been ignited and the surge current, the arc skips over this region and the follow current flows over the blow coil or the portion of the higher number of turns of the blow coil.

The electrodes are manufactured in the ignition range of the surge currents from erosion-resistant material. The width and height of these erosion-resistant surfaces on the electrodes in the ignition area should not be less than 4 mm.

The invention will be explained below with reference to an embodiment and with the aid of figures.

Fig. 1

eine stirnseitige Schnittdarstellung eines erfindungsgemäßen Überspannungsableiters;

Fig. 2

eine Querschnittsdarstellung durch einen erfindungsgemäßen Ableiter;

Fig. 3

eine Ausführungsform eines Ableiters in Stirnseitenansicht, bei wel- cher die Elektroden und der Zündbereich bereits von der Lichtbogen- Löschkammer umgeben sind, und

Fig. 4

eine seitliche Ansicht einer Funkenstrecke, bei der zur Verstärkung des Magnetfelds bei Folgestrom eine Blasspule vorgesehen ist.

Hereby show:

Fig. 1

a frontal sectional view of a surge arrester according to the invention;

Fig. 2

a cross-sectional view through an arrester according to the invention;

Fig. 3

an embodiment of a diverter in front view, in which the electrodes and the ignition area are already surrounded by the arc extinguishing chamber, and

Fig. 4

a side view of a spark gap, in which a blow coil is provided to amplify the magnetic field at follow-up.

The surge arrester after Fig. 1 has an outer housing, which represents a quasi-pressure-tight enclosure.

Inside this housing there is an electrode assembly 1, the electrodes 1a and 1b (see FIG Fig. 2 ) diverge like a horn.

The electrodes 1 have a continuous bore 14 and on its inner side a vertical recess 13, which together form a channel, can be supplied via the gas 8 between the electrodes for deionization of the ignition point 4 in the interior of the spark gap.

Instead of a continuous bore 14 also lateral or frontal recesses may be provided on the electrodes 1.

The electrodes 1 additionally have in the running region of the arc lateral recesses 2, through which the main part of the gas circulation 7 is supplied to support the arc movement to the interior of the spark gap.

At the same time or alternatively, the supply of the gas in this area can also take place by means of lateral recesses 3 or through corresponding apertures or holes in the arc chamber walls 11. These chamber walls may be backed with ferromagnetic material 10 to aid in arc motion.

From the interior of the spark gap, the gas passes through several staggered mounted side openings and after the complete passage through the above provided Deionkammer 6, which is almost a part of the arc chamber.

The gas flows in one, but preferably in a plurality of separate channels 12, which extend on one or both sides next to the arc chamber 11.

The higher the number of these channels, in particular in the end region of the deion chamber 6, the lower the risk of the union of partial light arcs outside the deion chamber 6.
After admission to the separate channels, the gas is cooled in these channels and fed through the openings 2, 3 and partially 14 the interior of the spark gap.

The cooling can be done here both on existing insulation materials and on the metal components.

The gas 8, which serves to deionize the ignition region, is further cooled by the guide in the channel within the electrodes. An additional cooling can be realized by a meandering guide 5 of the gas along cooling walls.

Furthermore, it is possible to additionally mix the gas 8 with air from the environment, which passes through the pressure equalization opening 9 in the spark gap. For this purpose, a mixing chamber is virtually present in the lower region of the arrester. This opening with minimal cross-section is also necessary to prevent a long-lasting or cumulative pressure build-up inside the spark gap.

The side view of an embodiment of the invention according to Fig. 2 shows again the main electrodes 1a and 1b, wherein one of the main electrodes (1b) in support of the arc movement with a ferromagnetic Material 10 is deposited. Together with the ferromagnetic material in or on the arc chamber walls 10 (see Fig. 1 ), the ignition and the running range of the arc between the two main electrodes 1a and 1b is enclosed in a U-shape.

Ausgestaltend a magnet 15 can be mounted in the ignition area, whereby the Fußpunktbewegung the arc is promoted.

The gas outlet from the arc quenching chamber 6 (Deionkammer) takes place both through the side openings 17 of the chamber and at the top of the chamber.

The escaping gas on the sides, but also on the top can be performed in separate, mutually insulated channels. The return of the gas to close the circulation takes place both in the ignition region through the electrodes and in the running region of the arc via the openings. 2

Fig. 3 shows a view of the end face of a surge arrester according to the invention, in which the main electrodes 1 and the ignition area are already surrounded by the arc-quenching chamber (Deionkammer) 6.

By this measure, the time can be reduced until the arc enters the chamber and the ferromagnetic material of the Deion chamber accelerates the ignition of the movement of the arc.

In addition, the illustration after Fig. 3 the possibility of surrounding the entire arc chamber 6 with a U-shaped ferromagnetic enclosure 18. These as well as the passages for gas circulation are suitably arranged in isolation to the arc chamber 6.

As shown Fig. 4 a bluff coil 19 is used to amplify the magnetic field at follow-up current.

This coil forms a shunt to one of the main electrodes 1. The arc is ignited at impulse load at the ignition point 4 between the main electrodes 1. In this case, the pulse current flows directly via the main electrode 1 and not via the coil 19.
Due to the short duration of the pulse discharge, the arc remains in region 20 between the main electrodes. In the case of long-lasting pulses or in the event of a subsequent current, the arc also reaches the region between the electrodes, which is identified by the reference numeral 30.
The base of the arc reaches the position 22 on the electrode with connected blow coil 19. At this point, the electrode is high impedance or isolated interrupted. After skipping this point, the current flows through the blow coil 19, thereby causing the arc movement to be assisted.

The bluff coil 19 may additionally have so-called guide plates, which in turn comprise the running region of the arc in a U-shape.

In the presentation after Fig. 4 the openings 21 for deionization of the ignition point 4 are designed as grooves transversely and not as a continuous bore in the electrodes. The openings of the gas circulation to support the running behavior of the arc 2 may be mounted above, but also partially below the point of interruption 22.

In summary, the proposed solution makes it possible to specify an encapsulated surge arrester based on a spark gap with divergent electrodes, wherein a special gas circulation takes place in such a way that the hot gas is staggered and removed from the current limiting device in separate channels and cooled, and again at least in arcs -Laufrichtung offset and separate openings through the channels of the arc chamber cold gas is supplied. In the ignition range, cold gas can still be supplied from outside through a pressure equalization opening. The U-shaped ferromagnetic material causes a self-magnetic field gain around at least one electrode, wherein the arc chamber can be surrounded with ferromagnetic material.

Claims (15)

1. Surge arrester comprising two diverging electrodes (1a, 1b) and a spark gap acting between the electrodes, a housing and, if necessary, a sliding aid for the arc active at the electrode base point, and means for the magnetic blow-out of the arc, wherein the mobility of the arc immediately after its ignition is increased by a combination of measures for intensifying the arc-induced self-magnetic field and a phased gas circulation of the encapsulated arrester,
   characterized in that
   at least one of the electrodes (1b) is backed with a ferromagnetic material (16) to support the movement of the arc and that an arc chamber (11) is formed inside the housing to enclose the electrodes at least partially and the chamber walls are made of ferromagnetic material (10) or are backed with such a material, so that the ignition and travel area of the arc between the electrodes is enclosed by the ferromagnetic material in a substantially U-shaped manner.
2. Surge arrester according to claim 1,
   characterized in that
   the electrodes (1) comprise recesses (13, 14) in the travel area of the arc, through which a gas flows into the interior of the arc chamber (11) to support the movement of the arc.
3. Surge arrester according to claim 1 or 2,
   characterized in that
   the arc chamber walls (11) comprise additional recesses (3) through which a gas flows into the interior of the arc chamber (11) to support the movement of the arc.
4. Surge arrester according to one of the preceding claims,
   characterized in that
   the electrodes (1) each have a bore (14) and a groove or recess internally connected with the former in the base point, wherein gas (8) for deionization can be fed to the ignition point (4) of the arc through the bore and the groove.
5. Surge arrester according to one of the preceding claims,
   characterized in that
   the arc chamber (11) is joined by a quenching chamber, specifically a deionizing chamber, wherein the deionizing chamber (6) has an inlet directed towards the diverging electrodes (1) and several, also lateral and slot-shaped outlet openings.
6. Surge arrester according to claim 5,
   characterized in that
   gas-carrying and gas-conducting, completely space-dividing channels (12) are provided at least between the lateral, slot-shaped outlet openings of the deionizing chamber (6) and the recesses in the arc chamber (11) as well as the bore (14) in the electrode base point.
7. Surge arrester according to claim 6,
   characterized in that
   in the channel (12) leading to the bore (14) in the electrode base point cooling cascades are provided or the channel (5) runs in a meandering pattern.
8. Surge arrester according to claim 7,
   characterized in that
   the gas (8) flowing to the bore (14) in the electrode base point is mixed with ambient air.
9. Surge arrester according to claim 8,
   characterized in that
   a mixing chamber for mixing the gas is disposed underneath the electrode base point, which includes one or more pressure-compensating bores (9) of a small cross section.
10. Surge arrester according to claim 9,
    characterized in that
    the bore (14) in the electrode base point extends into the mixing chamber or is connected to it.
11. Surge arrester according to one of the preceding claims, characterized in that
    a magnet (15) for supporting the movement of the arc is disposed in the area of the electrode base point.
12. Surge arrester according to claim 6,
    characterized in that
    the channels (12) are passed insulated from each other and separately so as to ensure a deliberate flow return to the ignition area and to the travel area of the arc.
13. Surge arrester according to claim 12,
    characterized in that
    the channels (12) have defined, predetermined cross-sectional areas.
14. Surge arrester according to claim 1,
    characterized in that
    the ferromagnetic material (18) is disposed in an insulated manner with respect to the arc chamber (6).
15. Surge arrester according to one of the preceding claims,
    characterized in that
    for intensifying the magnetic field in the event of follow currents a blow-out coil (19) is provided, which forms a shunt to one of the electrodes, wherein, in the traveling direction of the arc upstream of the connection point of the coil, the respective electrode includes a high-impedance section or an insulation distance.

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