DE9211808U1 - Arrangement with surge protection devices - Google Patents

Description

Company DEHN + SÖHNE GmbH + Co. KG
Rennweg 11 - 15, 8500 Nuremberg

'Arrangement with surge protection devices'

The invention relates first of all to an arrangement with overvoltage protection means according to the preamble of claim 1. An arrangement for overvoltage protection according to DE-PS 38 12 058 is known for this purpose. In the circuit combination described therein, the impedance connected in series with the varistor can optionally be an ohmic resistance, an inductance or a capacitor. This series circuit is parallel to the spark gap. The voltage drop across the series circuit depended on whether an ohmic resistance was used (evaluation based on the current peak value), whether an inductance was used (evaluation based on the current gradient), or whether a capacitor was used (evaluation based on the pulse duration). Thus, with the impedance provided in each case, only a certain waveform of the surge current could be recorded and evaluated. On the other hand, deviations occurred with surge currents with other curves.

The task of the invention, compared to this state of the art, is to make the varistor

Starting from an arrangement according to the generic term of claim 1, it should first be ensured that, regardless of the aforementioned parameters, current peak value, current gradient or pulse duration, the spark gap is always ignited before an energetic overload of the varistor occurs.

The solution to this problem is initially seen, starting from the generic term of claim 1, in the features of the characterizing part of claim 1. A PTC resistor is understood to be a PTC thermistor with a positive temperature coefficient, which becomes more highly resistive as the temperature rises. This means that when a correspondingly high current flows in the series circuit of PTC resistor and varistor, the heat generated by this current in the PTC resistor causes this resistor to become more highly resistive, which leads to an increase in the voltage drop across the PTC resistor. If the total voltage drop resulting from the

² ^ If the voltage drop across the PTC resistor and the varistor is so large that it reaches the ignition voltage of the spark gap, the spark gap ignites and discharges the overvoltage, which leads to a sudden reduction in the current that previously existed in the series circuit of the PTC resistor and

² ^ varistor. It has no influence on the desired result whether it is, for example, a surge current of 5 kA (8/20), i.e. with a relatively short pulse duration, or a surge current of 2.5 kA (10/350) and thus a surge current with a smaller peak value but longer pulse duration. In each case, it only depends on the energy load on the PTC resistor and the resulting heating of this resistor. Since the same current also flows through the varistor and loads it energetically, an increase (or decrease) in this current results in an analogous increase (reduction) in the energy load in the PTC resistor and in the varistor. This enables

If the data for the spark gap, the PTC resistor and the varistor are selected accordingly, the spark gap is ignited and the varistor's energy is thus relieved. The combination of PTC resistor and varistor is effective even after several loads, since such an arrangement changes its U/I characteristic curve only to a very small extent. The functions and advantages of limiting the maximum energy IQ that can be supplied to the varistor explained for this circuit consisting of a spark gap, PTC resistor and varistor take place with dynamic current loads (impulse loads), such as those that occur with surge currents with a current that changes rapidly over time.

The invention is also intended to counteract harmful energy loads on the varistor that occur in the static range, with particular reference to a mains frequency leakage current that constantly flows through the varistor and that occurs due to some kind of damage or fault in the varistor. In this context, one also speaks of a pre-damage range in which the varistor is not completely destroyed, but has damage that allows the mains frequency leakage currents described to flow.

_c To solve this further task, the features of claim 2 are used first. The thermal coupling of the PTC resistor and varistor components connected in series results in additional heating at the PCT resistor, which is additional to the heating due to the flowing current.

_ The additional heating of the PTC resistor causes -30

There is a corresponding additional increase in its own resistance and the voltage drop.

The aforementioned protection of the varistor in static current conditions (mains frequency continuous current) is according to the 35

Invention preferably provided together with the ignition of the spark gap of the switching arrangement, which due to the dynamic

see surge current processes occur by reaching a total voltage drop at the series connection of PTC resistor and varistor at the level of the ignition voltage of the spark gap (see explanations for claim 1). The features of claim 3 and the related subclaims can also be implemented here.

The heat coupling provided in claim 2 and the explained reduction of the heat generated by the PTC resistor and the

IQ Varistor to a value that no longer damages the varistor can, however, also be used successfully on its own, ie without a parallel-connected spark gap, in order to achieve a series connection of a varistor with a PTC resistor and furthermore

^g a thermal coupling of these two components to achieve the aforementioned current reduction in the varistor. In this case, too, this leads to a significant reduction in the varistor temperature by limiting the current and can cause it to "heal itself", i.e. the explained advantage

2Q damage to the varistor is not further increased. For this purpose, according to claim 1 as an independent claim, subordinate claim 4, the then occurring, reduced current in the series circuit of PTC resistor and varistor can be so low that it does not cause a voltage drop for

„f. causes the spark gap to ignite and at the same time reduces the line frequency continuous current in the varistor to a value that no longer poses a risk. This line frequency leakage or continuous current in the varistor results in the varistor acting as a thermistor. This means a reduction in resistance at increased temperature, ie U

an NTC resistor with a negative temperature coefficient. This is partially compensated by the opposite behavior of the PTC resistor. Fusible link monitoring of the heating of the varistor, which has been common practice up to now, is no longer necessary.

The further subclaims relate to advantageous embodiments

-δ-formations of the heat coupling and further according to claim 8 an arrangement according to the invention with a control circuit.

Further advantages and features of the invention can be found in the following description and the associated drawings or diagrams of possible embodiments of the invention. The drawing shows:

Fig. 1: a basic circuit of a first IQ embodiment according to the invention,

Fig. 2: the current/voltage characteristics corresponding to Fig. 1 ,

each Fig. 3: one optionally in the circuit according to Fig. 1

or a stand-alone design of a unit consisting of a varistor and PTC resistor,

„&lgr; Fig. 4: a supplement to the circuit in Fig. 1 with

an indication of an error case.

Fig. 1 shows schematically the parallel connection of a _spark gap 1, which is preferably capable of carrying lightning current and extinguishing follow currents, with a series connection consisting of a PTC resistor 2 and a varistor 3. The aforementioned parallel connection is located between a phase L and an earth line. The PTC resistor and the varistor are dimensioned in their characteristics so that in the event of a surge current (dynamic

_&Lgr; mixed impulse load) the total 30

Voltage drop Ug is equal to or slightly greater than the ignition voltage Ug, e.g. 3 kV of the spark gap 1. As explained, an increase in the current i flowing in the series circuit of PTC resistor 2 and varistor 3 has a

corresponding heating of the PTC resistor and thus a 35

This results in an increase in its resistance value, which in turn leads to an increase in the voltage drop U ₂ at the PTC resistor and

-ε&igr; thus resulting in an increase in the total voltage drop Up. The characteristics of the PTC resistor 2, the varistor 3 and the spark gap 1 are coordinated with one another in accordance with the aforementioned teaching of the invention.

The associated characteristic curves are shown in Fig. 2. The voltage U between phase L and earth is plotted on the ordinate and the surge current i flowing in the series circuit of PTC resistor and varistor is plotted on the abscissa. The voltage drop in this series circuit is plotted on the ordinate with LL·, which corresponds to the ignition voltage of the spark gap 1, ie when it is reached the spark gap ignites, thus preventing the formation of a surge current i ¹ or i' ₂ which would destroy the varistor.

In the diagram of Fig. 2, curve 4 concerns the voltage/

Current characteristic for a surge current pulse shape 8/20 for the case where only the varistor 3 is provided. 5 indicates the surge current i' ₂ which leads to destruction of the varistor 2Q in the case of a surge current pulse shape 8/20.

The characteristic curve 6, on the other hand, is created with a series connection according to the invention of the varistor 3 with a PTC resistor. With a surge current i« < i* (surge current pulse shape 2g 8/20), this already results in a voltage drop at the level of the voltage U ₃ , ie the ignition of the spark gap with a surge current i«, which does not yet lead to an energetic overload and thus destruction of the varistor.

_g0 Furthermore, Fig. 2 shows in the vertical dashed line the current i', which in the case of a surge current pulse shape 10/350 would lead to the energetic destruction of the varistor. The characteristic curve 8 is achieved if the series connection of the varistor with the PTC resistor according to the invention is provided for the aforementioned surge current pulse shape.

Then the voltage U ₅ is already reached at a current i. <i' and causes the ignition of the spark gap,

before the current i has reached the value i' and thus the destruction limit of the varistor.

The PTC resistor therefore creates characteristics 6, 8, which differ from the original characteristics (e.g. characteristic 4) without PTC resistor due to an energetically adjusted, additional voltage drop. It is important that the spark gap is ignited without endangering the varistor in the case of a long-lasting current impulse with a small peak value (e.g. 2.5 kA (10/350)) (characteristic 8), as well as in the case of a comparatively short current impulse with a high peak value (e.g. 10 kA (8/20)) according to characteristic 6. The disadvantages explained in relation to the state of the art are therefore avoided. This is also due to the fact that

!5 a PTC resistor 2 is connected in series with the varistor 3, the voltage drop of which depends on the temperature of this resistor, ie on its energetic load by the flowing current, whereby the same current ^is the cause of the energetic load on the varistor to be avoided -

In addition to the circuit arrangement according to Fig. 1 or independently thereof, a thermal coupling between the varistor 3 and the PTC resistor 2 can be provided ₂ c according to the invention. A preferred embodiment of this is shown in Fig. 3. This sandwich construction enables intensive heat transfer from the varistor to the PTC resistor. A central contact plate 9 with connection b or instead

_ soldering of existing contact surfaces of the 30

Components 2, 3 are provided. This soldering is not shown in the drawing. Furthermore, external contact plates 10, 11 are provided for connections a, c. It is recommended that components 2, 3 have the same outline, e.g.

a circular outline with the same diameter d. 35

The circuit according to Fig. 4 shows in the left half the

Circuit of Fig. 1, whereby the total voltage drop IL occurs between points a and c. For numbers a, b and c, see also the correspondingly marked connection points in Fig. 3. Furthermore, a further series connection of a resistor 12 and a display 13 is provided, whereby the resistor 12 is connected in parallel to the varistor 3 and the display 13 is connected in parallel to the PTC resistor 2. In the event of pre-damage to the varistor 3, a high voltage drop U« occurs at the PTC resistor. This activates the display, which gives, for example, a light signal or an acoustic signal. This indicates that the varistor is damaged, so that it may need to be replaced.

All features shown and their combinations with each other

,_ which are essential to the invention, &igr;&ogr;

- Protection claims -

Claims (9)

Arrangement with overvoltage protection means for overvoltage protection in low-voltage systems with a spark gap capable of carrying lightning current and extinguishing follow current and a line branch connected in parallel to the spark gap and having a varistor, in which a resistor connected in series with the varistor is provided, the total voltage drop occurring across this resistor and the varistor as a whole when a certain surge current is exceeded reaching the response voltage (ignition voltage) of the spark gap, characterized in that the resistor is a PTC resistor (2) and that the data of this PTC resistor are matched to the data of the varistor (3) and the spark gap (1) in such a way that the total voltage drop (Up) reaches the value of the response voltage (IL·) of the spark gap before the varistor is overloaded energetically by the surge current. 2. Arrangement in particular according to claim 1, characterized in that a thermal coupling is provided between the varistor (3) and the PTC resistor (2). -&Igr;&Ogr;&Igr; 3. Arrangement according to claim 1 and 2, characterized by a dimensioning of the electrical data of the varistor (3) and the PTC resistor (2) such that in the event of a fault in the varistor, an increase in the resistance value of the PTC resistor (2) occurs such that the current (i) flowing in the series circuit is reduced to a mains frequency continuous current with a value that does not endanger the varistor (3). 4. Arrangement with overvoltage protection means, wherein a varistor and a resistor are connected in series, characterized by a series connection of a varistor (3) with a PTC resistor (2) and further a spatial assignment of these two components to one another such that a thermal coupling exists between the varistor (3) and the PTC resistor (2) and by a dimensioning of the electrical data of these two components such that in the event of a fault in the varistor, an increase in the resistance value of the PTC resistor occurs such that the current (i) flowing in the series connection is reduced to a mains frequency continuous current with a value that does not endanger the varistor and that the total voltage drop across the PTC resistor and varistor remains below the response voltage of the spark gap. 5. Arrangement according to one of claims 2 to 4, characterized in that the PTC resistor (2) and the varistor (3) are a structural unit. 6. Arrangement according to claim 5, characterized in that the PTC resistor (2) and the varistor (3) are disk-shaped and have the same outline. 7. Arrangement according to claim 6, characterized by a sandwich construction of this structural unit consisting of varistor (3) and PTC resistor (2). 8. Arrangement according to claim 7, characterized by soldering surfaces or contact plates on the outer sides of the structural unit and between the two components (2, 3). 9. Arrangement according to one of claims 1 to 8, characterized in that a series circuit comprising a series resistor (12) and a display (13) is connected in parallel to the series circuit comprising the PTC resistor (2) and the varistor (3), the display (13) being dimensioned such that it indicates an increased voltage drop (U ₂ ) across the PTC resistor.