DE10146728B4 - Overvoltage protection device - Google Patents

Abstract

Overvoltage protection device, with a first electrode (1), with a second electrode (2) and with an effective between two electrodes (1, 2) breakdown spark gap (3), wherein when igniting the breakdown spark gap (3) between the two electrodes (1, 2) an arc is created,
characterized,
in that the series connection of a voltage switching element (4) and an ignition element (5) is connected to the two electrodes (1, 2),
that the response voltage of the voltage switching element (4) is below the response voltage of the breakdown spark gap (3),
that at the contact point (6) between the ignition element (5) and the ignition element (5) associated electrode (2) is given a contact resistance, and
that upon activation of the voltage switching element (4) first a leakage current flows through the ignition element (5), wherein the ignition element (5) is designed such that at larger leakage currents due to the contact resistance at the contact point (6) discharges occur, resulting in a preionization of the lead the contact point (6) surrounding contact area.

Description

The Invention relates to an overvoltage protection device, with a first electrode, with a second electrode and with an effective between two electrodes breakdown spark gap, wherein when igniting the breakdown spark gap between the two electrodes Arc is created.

electric, but in particular electronic measuring, control and regulating circuits, especially telecommunications equipment and facilities are sensitive to transient overvoltages, as they are in particular due to atmospheric discharges, as well by switching operations or short circuits in power supply networks may occur. This sensitivity has increased to the extent that electronic Components, in particular transistors and thyristors used become; above all, increasingly used integrated circuits to a great extent by transient overvoltages endangered.

electrical Circuits work with them specified voltage, rated voltage, normally trouble-free. That does not apply if overvoltages occur. As overvoltages apply all voltages that are above the upper tolerance limit of Nominal voltage are. Which includes especially the transient overvoltages, the due to atmospheric Discharges, but also by switching operations or short circuits in power grids may occur and galvanic, inductive or capacitive in electrical circuits can be coupled. To now electrical or electronic circuits, in particular electronic measuring, Control, regulating and switching circuits, in particular including telecommunications equipment and installations, wherever they are used, against transient overvoltages to protect, are overvoltage protection devices been developed and known for more than twenty years.

essential Component of overvoltage protection device the type in question here is at least one spark gap, the at a certain overvoltage, the response voltage, responds and thus prevents that in the by an overvoltage protection device protected circuit surges occur larger than the response voltage of the spark gap are.

input is executed been that the Overvoltage protection device according to the invention two Electrodes and one between the two electrodes. effective breakdown spark gap having. With breakdown spark gap is generally one Breakdown spark gap meant; should be included so so too a breakdown spark gap, where not air, but a other gas is present between the electrodes. In addition to overvoltage protection devices with a breakdown spark gap, there are overvoltage protection devices with a flashover spark gap, at which occurs when responding a sliding discharge.

Overvoltage protection devices with a breakdown spark gap have the advantage over surge protective devices with a flashover spark gap the advantage of a higher surge current carrying capacity, but the disadvantage of a higher - and not very constant - Ansprechspannung. Therefore, various overvoltage protection devices have been proposed with a breakdown spark gap, which have been improved in terms of the response voltage. In this case, ignition aids have been realized in various ways in the region of the electrodes or the effective between the electrodes breakdown spark gap, z. B. such that between the electrodes has been provided at least one triggering a triggering ignition aid, which protrudes at least partially into the breakdown spark gap, is web-like and made of plastic (see, for DE 41 41 681 A1 or DE 44 02 615 A1 ).

The in the known surge protection devices provided, previously mentioned Zündhilfen can be called as "passive Zündhilfen" as it were, "passive ignition aids" because they do not speak "actively" yourself, but only by an overvoltage respond, which occurs at the main electrodes.

From the DE 198 03 636 A1 is also an overvoltage protection device with two electrodes, with an effective between the two electrodes breakdown spark gap and a starting aid known. In this known overvoltage protection device, the ignition aid, in contrast to the previously described, a sliding discharge triggering ignition aids, as "active ignition aid" formed, namely the fact that in addition to the two electrodes - there referred to as main electrodes - two ignition electrodes are provided. These two ignition electrodes form a second, serving as a spark gap breakdown spark gap. In this known overvoltage protection device belongs to the ignition aid except the spark gap nor a firing circuit with an ignition switch. When applying an overvoltage to the known overvoltage protection device, the ignition circuit with the ignition switching element ensures a response of the spark gap. The sparks track or the two ignition electrodes are arranged with respect to the two main electrodes such that, characterized in that the spark gap has addressed, the breakdown spark gap between the two main electrodes, called main spark gap responds. The response of the spark gap leads to an ionization of existing in the breakdown spark gap air, so that - abruptly - after response of the spark gap then the breakdown spark gap between the two main electrodes, so the main spark gap responds.

at the known, previously described embodiments of overvoltage protection devices with ignition aids to lead the ignition aids to an improved, viz lower and more constant response voltage.

at Overvoltage protection devices of the type in question - with or without using a starting aid - arises when igniting the breakdown spark gap by the resulting arc a low impedance connection between the two electrodes. About these low-impedance connection flows initially - intentionally - the derived Lightning current. When connected mains voltage then follows over this low-impedance connection of the overvoltage protection device undesirable Netzfolgestrom, so that one strives to keep the arc as possible quickly clear after completion of the discharge process. A possibility To achieve this goal is the arc length and thus increasing the arc voltage.

One way to erase the arc after the dissipation process, namely to increase the arc length and thus the arc voltage is in the overvoltage protection device, as it is known from DE 44 02 615 A1 is known, realized. The from the DE 44 02 615 A1 known overvoltage protection device has two narrow electrodes, which are each formed angularly and each having a sparking horn and a bent therefrom terminal leg. In addition, the spark horns of the electrodes are provided in their adjacent to the terminal legs areas with a bore. The holes provided in the spark horns of the electrodes ensure that at the moment of the response of the overvoltage protection element, ie the ignition, the resulting arc is "set in motion" by a thermal pressure effect, ie migrates away from its point of origin. Since the spark horns of the electrodes are arranged in a V-shape relative to one another, the distance to be bridged by the arc as the arc travels out is thus increased, as a result of which the arc voltage also increases.

A another possibility to extinguish the arc after the discharge process, consists in the cooling of the Arc through the cooling effect of insulating material walls as well as the use of gas-releasing insulating materials. It is a strong current of the extinguishing gas necessary, which requires a high design effort.

is for overvoltage protection devices of erased type of arc, so first is the low-impedance connection between the two electrodes interrupted, the Space between the two electrodes, d. H. the area of the breakdown spark gap, is still almost complete filled with plasma. Due to the existing plasma, however, the response voltage between the two electrodes lowered so that it already at Operating voltage for a renewed ignition of the breakdown spark gap can come. This problem occurs especially when the overvoltage protection device has an enclosed or semi-open housing, since then a cooling or volatilizing of the plasma prevented by the substantially closed housing becomes.

Around a renewed ignition the overvoltage protection device, d. H. the breakdown spark gap, To prevent so far, various measures have been taken to drive away or cool the ionized gas cloud from the ignition electrodes. For this are structurally elaborate labyrinths and heatsinks have been used, resulting in the manufacture of the overvoltage protection device expensive.

From the German patent specification 174 502 an overvoltage protection device is known, in which a renewed response of the breakdown spark gap after the discharge is effectively prevented, which nevertheless can be realized structurally simple. This known overvoltage protection device is one with a main spark gap, with a secondary spark gap igniting the main spark gap, and with a housing accommodating the main spark gap and the auxiliary spark gap, wherein the main spark gap comprises a first main electrode, a second main electrode and an existent between the main electrodes Having a breakdown spark gap and when igniting the breakdown spark gap an arc between the first main electrode and the second main electrode is formed, wherein the auxiliary spark gap has a first sub-electrode, a second sub-electrode and an existent between the sub-electrodes second breakdown spark gap and an ignition the second breakdown spark gap leads to an ignition of the first breakdown spark gap and wherein the second sub-electrode is connected via at least one impedance, directly or indirectly, to the second main electrode.

From the DE 198 56 939 A1 a circuit arrangement for the protection of electrical installations against overvoltages is known in which a arranged in series with the breakdown spark gap disc-shaped varistor is provided, which is placed directly contacting on an electrode plate. As a result, a particularly compact design can be achieved.

The DE 42 44 051 A 1 discloses an overvoltage protection device for dissipating transient overvoltages, with an effective between two electrodes breakdown spark gap, in which between the electrodes a sliding discharge triggering ignition aid is integrated in the form of an auxiliary flashover spark gap.

An initially described overvoltage protection device is finally from the DE 195 10 181 C1 known. In this overvoltage protection device two spark gaps are connected in parallel to each other. The first spark gap, which is connected in series with an impedance and which has a lower response voltage than the second spark gap, serves to ignite the overvoltage protection device. By igniting the first spark gap creates a preionization of the second spark gap, so that it then comes to an ignition of the second spark gap. The two spark gaps and the impedance are dimensioned such that the voltage drop occurring at the first spark gap and the impedance connected in series when the first spark gap is ignited is greater than the response voltage of the second spark gap. This results in a separation of functions in such a way that the first spark gap only takes over the ignition of the arrangement, while the second spark gap leads after ignition most of the surge current or the Netzfolgestromes.

Of the Invention is the object of an overvoltage protection device the type described above in a particularly simple manner with a particularly easy-acting ignition aid to provide.

The overvoltage protection device according to the invention, in which the object indicated above is achieved, it is characterized that between the two electrodes, the series connection of a voltage switching element and a firing element connected is that the Response voltage of the voltage switching element below the response voltage the breakdown spark gap is that at the contact point between the ignition element and the ignition element associated contact resistance is given, and that at Response of the voltage switching element, first a leakage current through the igniter flows, wherein the ignition element is formed such that at because of larger leakage currents the contact resistance At the contact point discharges arise, leading to a preionization lead the contact area surrounding the contact area.

This realizes a completely new overvoltage protection device with a starting aid or a completely new starting aid in an overvoltage protection device, as is apparent from the following functional description:
The voltage switching element is chosen or dimensioned so that it becomes conductive at the response voltage of the overvoltage protection device, ie "switches". As a voltage switching element, a varistor, a suppressor diode or a gas-filled arrester can be provided. However, it is also possible to provide as a voltage switching element, a combination of a varistor and a suppressor diode, a combination of a varistor and a gas-filled surge arrester, a combination of a suppressor diode and a gas-filled surge arrester or combination of a varistor, a suppressor diode and a gas-filled surge arrester. For the ignition element is preferably that it consists of an electrically conductive material and is resistant to arc; In addition, it must be ensured that the ignition element can not weld or fuse with its associated electrode, ie with the electrode with which it is in electrically conductive contact. Preferably, the ignition element and / or the ignition electrode associated electrode made of an electrically conductive ceramic material, a non-welding metallic material and / or of an electrically conductive plastic.

Occurs at the overvoltage protection device according to the invention on an overvoltage, which is equal to or greater than the predetermined by the voltage switching element operating voltage, so the voltage switching element, so that via the series connection first electrode - voltage switching element - igniter - second electrode begins to flow a leakage current; Overvoltages with low energy content are thus derived via the series connection described above. When the energy content of the overvoltage applied to the overvoltage protection device is greater, a correspondingly larger current flows. This current leads at the contact point between the ignition element and the associated electrode we conditions of contact resistance at the contact point to discharges, which lead to a preionization of the contact area, so that an arc is formed, which bridges the contact point. Because of the not insignificant resistance of the ignition element, the arc migrates along the ignition element in order to bridge its resistance. This mechanism then causes the breakdown spark gap between the two electrodes ignites, so an arc is formed between the two electrodes.

Unlike the one from the DE 195 10 181 C1 known overvoltage protection device creates the first discharge due to the already flowing over the ignition element leakage current and not due to exceeding the response voltage of the breakdown spark gap. The discharge arises due to the contact resistance at the contact point or due to the exceeding of the current carrying capacity of the contact point.

According to the invention is thus an overvoltage protection device with a starting aid emerged, in a simple way, the response in wide Limits can be adjusted with low tolerances, namely by the selection or dimensioning of the voltage switching element. there is of particular importance that the ignition aid in the overvoltage device according to the invention Insensitive to mechanical and thermal stresses and directly inside the spark gap formed by the two electrodes can be used. It is also important that in the overvoltage protection device according to the invention a "passive ignition aid" has been realized is, so it's an additional ignition circuit - with a Ignition pulse generation - not requirement.

in the There are now a variety of possibilities, the overvoltage protection device according to the invention to design and develop. This is referred to on the one hand to the claims subordinate to claim 1, on the other hand to the following description of preferred embodiments in conjunction with the drawing. In the drawing show

1 a schematic diagram of a first embodiment of an overvoltage protection device according to the invention and

2 a schematic diagram of a second embodiment of an overvoltage protection device according to the invention.

In the 1 and 2 In each case an overvoltage protection device according to the invention is shown only in terms of their basic structure. The illustrated overvoltage protection devices each include a first electrode 1 , a second electrode 2 and one between the two electrodes 1 and 2 existing or effective air breakdown spark gap 3 , For the overvoltage protection devices according to the invention applies, as for the overvoltage protection devices, from which the invention proceeds, that when igniting the air breakdown spark gap 3 between the two electrodes 1 and 2 a - not shown - arc is formed.

According to the invention, the two electrodes 1 and 2 the series connection of a voltage switching element 4 and a firing element 5 connected.

In the 1 and 2 is the voltage switching element 4 shown only schematically. As a voltage switching element 4 with which the response voltage of the overvoltage protection device according to the invention is predetermined, a varistor, a Surpressordiode or gas-filled surge arrester can be provided. But it is also possible, as a voltage switching element 4 to provide a combination of a varistor and a Surpressordiode, a combination of a varistor and a gas-filled surge arrester, a combination of a Surpressordiode and a gas-filled surge arrester or a combination of a varistor, a Surpressordiode and a gas-filled surge arrester.

Like the voltage switching element 4 , so in the in the 1 and 2 illustrated embodiments of inventive overvoltage protection devices and the ignition element 5 shown only schematically. The ignition element 5 consists of a material that is electrically conductive and arc resistant. In addition, it must be ensured that the ignition element 5 at the contact point 6 to the electrode 2 with the electrode 2 can not weld. Preferably, the ignition element 5 or / and the ignition element 5 associated electrode 2 of an electrically conductive ceramic material, of a non-welding metallic material and / or of an electrically conductive plastic.

Otherwise, between the ignition element 5 and the ignition element 5 associated electrode 2 permanently given a contact resistance; the contact point 6 So it has permanent contact resistance. This contact resistance can be achieved by a suitable choice of the electrical conductivity of the materials of the ignition element 5 and / or the ignition element 5 associated electrode 2 reali be siert, preferably by a suitable choice of the material of the ignition element 5 , The one at the contact point 6 Permanently given contact resistance can take place by a suitable choice of the electrical conductivities of the materials of the ignition element 5 and / or the ignition element 5 associated electrode 2 or additionally by a suitable geometric design of the ignition element 5 at the contact point 6 to the associated electrode 2 and / or by a suitable geometric design of the electrode 2 at the contact point 6 to the ignition element 5 be realized, preferably by a small contact surface.

The contact point 6 between the ignition element 5 and the associated electrode 2 especially has a small contact surface when the ignition element 5 at his the electrode 2 associated end cut or punctiform and the electrode 2 at her the ignition element 5 facing side is convex. In the geometric realization of the contact point 6 between the ignition element 5 and the electrode 2 However, care should be taken to contact the contact point 6 subsequent air gap between the ignition element 5 and the electrode 2 According to the invention must meet two criteria in electrical terms. On the one hand, the air gap must be so large that at an overvoltage with low energy content of the leakage current only via the contact point 6 flows, so the contact point 6 surrounding contact area still undergoes no preionization. On the other hand, the air gap must be so small that when the energy content of the overvoltage is greater, the flowing current to a Vorionisierung of the contact point 6 surrounding contact area leads. A solution that meets both criteria is realized in the illustrated embodiments. This is the electrode 2 facing end of the ignition element 5 conical-convex and the ignition element 5 facing side of the electrode 2 cone-shaped concave.

The 1 and 2 show in this respect preferred embodiments of inventive overvoltage protection devices, as the contact pressure between the ignition element 5 and the associated electrode 2 is adjustable. In the embodiments, this is by a on the ignition element 5 acting pressure spring 7 realized; with compression springs 7 different spring types can be realized different contact pressures. But there is also the possibility not shown in the figures, the contact pressure between the ignition element 5 and the associated electrode 2 by a mechanically reversible deformable material of the ignition element 5 and / or at least one electrode, preferably the ignition element 5 associated electrode 2 to make adjustable.

It is stated above that in the inventive overvoltage protection devices between the two electrodes 1 and 2 the series connection of a voltage switching element 4 and a firing element 5 is provided. This is meant electrically, not necessarily mechanically or spatially or geometrically.

In the embodiment of an overvoltage protection device according to the invention, which in 1 is shown schematically, both the voltage switching element 4 as well as the ignition element 5 spatially between the two electrodes 1 and 2 intended. In contrast, the shows 2 an embodiment in which the voltage switching element 4 spatially outside the area between the two electrodes 1 and 2 is provided. In this embodiment, this is spatially outside the area between the two electrodes 1 and 2 provided voltage switching element 4 on the one hand via an outer connecting element 8th with the electrode 1 and on the other hand via a connecting pin 9 with the - electrically conductive - compression spring 7 and thus with the ignition element 5 connected.

Claims (8)

Overvoltage protection device, with a first electrode ( 1 ), with a second electrode ( 2 ) and with one between both electrodes ( 1 . 2 ) effective breakdown spark gap ( 3 ), wherein upon ignition of the breakdown spark gap ( 3 ) between the two electrodes ( 1 . 2 ) an arc is formed, characterized in that to the two electrodes ( 1 . 2 ) the series connection of a voltage switching element ( 4 ) and an ignition element ( 5 ) is connected, that the operating voltage of the voltage switching element ( 4 ) below the response voltage of the breakdown spark gap ( 3 ) that at the point of contact ( 6 ) between the ignition element ( 5 ) and the ignition element ( 5 ) associated electrode ( 2 ) a contact resistance is given, and in that the response of the voltage switching element ( 4 ) first a leakage current through the ignition element ( 5 ) flows, wherein the ignition element ( 5 ) is designed such that at larger leakage currents because of the contact resistance at the contact point ( 6 ) Discharges occur, leading to a preionization of the contact point ( 6 ) lead surrounding contact area. Overvoltage protection device according to claim 1, characterized in that as a voltage switching element ( 4 ) a varistor, a suppressor diode or a gas-filled surge arrester is provided. Overvoltage protection device according to claim 1 or 2, characterized in that the ignition element ( 5 ) and / or the ignition element ( 5 ) associated electrode ( 2 ) consists of an electrically conductive ceramic material, of a non-fusing metallic material and / or of an electrically conductive plastic. Overvoltage protection device according to one of Claims 1 to 3, characterized in that the contact resistance between the ignition element ( 5 ) and the ignition element ( 5 ) associated electrode ( 2 ) by a suitable choice of the electrical conductivities of the materials of the ignition element ( 5 ) and / or the ignition element ( 5 ) associated electrode ( 2 ), preferably by a suitable choice of the material of the ignition element ( 5 ) is realized. Overvoltage protection device according to one of Claims 1 to 4, characterized in that the contact resistance between the ignition element ( 5 ) and the ignition element ( 5 ) associated electrode ( 2 ) by a suitable geometric design of the ignition element ( 5 ) at the contact point ( 6 ) to the associated electrode ( 2 ) and / or by a suitable geometric design of the electrode ( 2 ) at the contact point ( 6 ) to the ignition element ( 5 ) is realized, preferably by a small contact surface. Overvoltage protection device according to one of Claims 1 to 5, characterized in that the contact pressure between the ignition element ( 5 ) and the associated electrode ( 2 ) is adjustable, for. B. by a on the ignition element ( 5 ) acting compression spring ( 7 ) and / or by a mechanically reversible deformable material of the ignition element ( 5 ) and / or at least one electrode, preferably the ignition element ( 5 ) associated electrode ( 2 ). Overvoltage protection device according to one of Claims 1 to 6, characterized in that the voltage switching element ( 4 ) and the ignition element ( 5 ) spatially between the two electrodes ( 1 . 2 ) are provided. Overvoltage protection device according to one of Claims 1 to 6, characterized in that the voltage switching element ( 4 ) spatially outside the region between the two electrodes ( 1 . 2 ) is provided.