DE202019001241U1 - Overvoltage protection circuit with failure indication - Google Patents

Abstract

Protection circuit (1) against overvoltage on a live electrical line (10), wherein the electrical line (10) via a protective diode (3) to a reference potential (P) is connected, characterized in that electrically in series with the protective diode (3) an electrical fuse (20) is connected, and electrically in parallel with the fuse (20) a failure indicator (9) is connected, indicating a failure of the protection circuit (1).

Description

The invention relates to a protection circuit against overvoltage on a live electrical line, wherein the electrical line is connected via a protective diode to a reference potential.

Such a protection circuit against overvoltage is known per se. Thus, as a surge protection component z. B. a spark gap can be provided which connects the electrical line to a reference potential. The spark gap shows a gap formed between electrodes filled with air or gas. When an overvoltage occurs, a sparkover occurs between the electrodes to dissipate the overvoltage to the reference potential, usually to ground potential. To control the separating spark gap, a filter and a first protective diode can be arranged in series in a parallel branch to the overvoltage protection component. If an overvoltage occurs, a large part of the overvoltage will drop in the parallel branch at the filter, which leads to the response of the overvoltage protection component. The cable is connected to the earth potential via the isolating spark gap. The overvoltage is dissipated.

A built-in protection circuit spark gap can not be visually considered to be faulty. Is z. B. in the parallel branch before a defective component, no ignition of the overvoltage protection component takes place in the event of overvoltage. Since it can not be visually recognized whether an overvoltage protection component or its activation is faulty, the overvoltage protection component and / or the protection circuit itself must be regularly removed and tested for control purposes.

The invention has for its object to provide a protective circuit against overvoltage on a live electrical line in which a malfunction of the protection circuit can be seen without removing the electrical components.

The object is achieved in that in a protective circuit against overvoltage on a live electrical line, which is connected via a protective diode to a reference potential, an electrically connected in series with the protective diode electrical fuse is provided, connected to the electrically parallel a preferably electronic failure indicator is that indicates a failure of the protection circuit. The fuse is appropriate a fuse.

By lying in series with the protective diode fuse can be evaluated in a simple manner when the fuse voltage dropping on her. An error state or a short-circuit state of the protection circuit can be detected by evaluating the voltage drop across the fuse without special measures, especially from the outside.

The fuse limits the operating current flowing in the protection circuit to a predetermined value. In particular, the fuse is designed for the maximum operating current of the protective diode. Since the fuse is designed for the maximum permissible operating current, it will respond at a higher operating current and disconnect the current path. If the fuse has responded, a voltage drops across it, via which a failure indicator for overvoltage protection is activated.

Advantageously, the protective diode lying electrically in series with the fuse is a first protective diode, wherein a second protective diode is electrically connected in parallel with the fuse. The voltage dropping across the second protection diode is fed to the failure indicator. This decreasing voltage is determined by the type of protection diode used. If the fuse is intact, the second protection diode is short-circuited by the fuse. When the fuse activates and disconnects the current path of the first protection diode, a voltage is applied to the second protection diode, e.g. B. fall off the blocking voltage. This voltage dropping across the second protective diode can be evaluated in an evaluation circuit of the failure indicator and used to control the failure indicator itself.

Of particular advantage is that a destroyed fuse can be seen not only in the event of overvoltage, but also at a voltage applied to the monitored line supply voltage of z. B. 12 volts. The supply voltage will drop substantially at the first protection diode. At the first protection diode will always drop a voltage component, even if the fuse bridges the second protection diode. If the fuse is destroyed by an excessively high operating current, at least one voltage component of the supply voltage at the second protective diode will drop and can be used as a failure indicator.

To limit the operating current in the current path of the series circuit of protection diode and fuse, an ohmic resistance may be provided in the series circuit.

In a development of the invention, an overvoltage protection component can be arranged between the line and the reference potential electrically in parallel with the series connection of protective diode and fuse. This results in a redundant structure of the protection circuit. This is designed that the overvoltage protection component responds as the first component in the event of overvoltage. If the overvoltage protection component fails or does not respond, the operating current in the electrical series circuit of fuse and protective diode will rise until the fuse responds and disconnects the current path.

Advantageously, a coil is arranged in series with the series circuit of protection diode and fuse. The response of the protection circuit or the overvoltage protection device can thus be improved. In particular, this may also be provided for a filter lying electrically in series with the protective diode and the fuse. Is in the series circuit of the first protection diode and fuse, the current increased to a value greater than the allowable operating current, it can be assumed that the overvoltage protection component is defective, with the result that in an overvoltage the overvoltage protection component no longer safely responds.

The protective circuit and in particular the overvoltage protection component are preferably arranged in a common housing, which is used in particular as a modular component in control cabinets. The failure indicator according to the invention is advantageously integrated in the space of the module housing. The protection circuit itself and the failure indicator are thus arranged in a common housing. The arranged in the module housing failure indicator is provided so that the outer dimensions of a module housing with an overvoltage protection without failure indication are not changed.

The failure indication is preferably an optical and / or acoustic, in particular a local optical display. In a simple embodiment, the optical display can be an LED, which is expediently arranged in the module housing and visible from outside the module housing.

The failure indicator can also be designed as a remote display. For this purpose, the evaluation circuit is provided with a signal output, on which an output signal is output.

The overvoltage protection component is advantageously a separating spark gap, a gas discharge gap or a varistor.

The protection diode lying in series with the fuse is advantageously a suppressor diode, expediently a bidirectional suppressor diode, in particular a fail-safe suppressor diode. With the arrangement of the suppressor diode, a safe component is provided against overvoltage, which ensures redundancy of the protective circuit in the arrangement of an overvoltage protection component. If the overvoltage protection component is not responding, the suppressor diode assumes the overvoltage protection function. The suppressor diode is a voltage-limiting component that changes to a predetermined state in the event of overload. If the suppressor diode is a fail-safe suppressor diode, it can become high-impedance in the event of overload or lead to a defined short circuit. (Fail Safe characteristic). The voltage dropping across the suppressor diode is a predetermined fail-safe voltage or goes to zero in the event of a short circuit.

In a development of the invention, the second protective diode lying electrically parallel to the fuse is a suppressor diode, preferably a bidirectional suppressor diode, in particular a fail-safe suppressor diode. It may be advantageous to use a bidirectional suppressor diode.

The electrical line to be protected by the protection circuit with overvoltage protection can be an electrical supply line (eg 230 volt mains supply), a data line or the like electrical line with e.g. B. 12 volts.

In a particular embodiment of the invention, at least two fuses are provided in series in the electrical series connection of the first protective diode. The at least two fuses connected in series with the first protective diode are designed with different current values. For each fuse, a second protective diode is electrically connected in parallel. The voltage dropping across the second protective diodes are evaluated in a particularly common evaluation circuit for a trend display. In this way, an expected future failure of the protection circuit can be calculated and displayed, so that a timely replacement of the protection circuit is possible.

Advantageously, the energy for operating the failure indicator and / or the optical and / or the acoustic display is tapped at the second protection diode. For this purpose, the voltage dropping across the second protective diode is used. It may be appropriate to convert the voltage via a rectifier into a DC voltage and / or to stabilize. An additional power supply for the evaluation circuit as well as for the failure indication itself is not necessary. The failure indicator includes the evaluation circuit that evaluates a voltage drop across the second protection diode.

Advantageously, the failure indicator is designed as an adhesive relay, which electrically switches an optical or / or acoustic display. The adhesive relay remains stable after a control, so that a short current pulse is sufficient to switch the adhesive relay in its display position.

• 1 in einer ersten Ausführungsform ein schematisches Schaltbild einer vereinfachten Schutzschaltung nach der Erfindung,
• 2 ein schematisches Blockschaltbild der Schutzschaltung nach der Erfindung,
• 3 ein schematisches Blockschaltbild einer erweiterten Schutzschaltung nach der Erfindung.

Further features of the invention will become apparent from the other claims, the description and the drawings, in which individual embodiments of the protection circuit according to the invention are shown. Show it:

• 1 in a first embodiment, a schematic circuit diagram of a simplified protection circuit according to the invention,
• 2 a schematic block diagram of the protection circuit according to the invention,
• 3 a schematic block diagram of an extended protection circuit according to the invention.

In the 1 schematically illustrated protection circuit 1 secures an electrical line 10 before an overvoltage Us , which can occur due to switching operations in the network or lightning strikes. To protect the electrical line 10 is a protection diode 3 provided the electrical line 10 with a reference potential P , especially with earth potential connects. The electrical line 10 can also have an overvoltage protection component 2 be connected to the reference potential P. The surge protection component 2 is useful as a spark gap 11 educated. Such a spark gap 11 can z. B. be formed by a gas discharge arrester. Also, the overvoltage protection component 2 be designed as a voltage-dependent resistor in the form of a varistor. Above a certain threshold voltage, the differential resistance of the varistor decreases abruptly.

The protective diode 3 is switched in the reverse direction. Electrically in series with the protection diode 3 is a fuse 20 switched, which is preferably designed as a fuse. Other forms of security 20 may be appropriate.

The protective diode 3 is especially as a suppressor diode 14 educated. In the exemplary embodiment shown, a preferred embodiment of the suppressor diode is shown as a bidirectional suppressor diode. The suppressor diode is in particular a fail-safe suppressor diode with a fail-safe voltage of 24 volts.

In series with the series circuit of protective diode 3 and fuse 20 is advantageous an ohmic resistance 8th provided for current limiting. In conjunction with a surge protection component 2 it may be advantageous to connect in series with the series protection diode 3 and fuse 20 a coil 5 to provide, in particular with the ohmic resistance 8th an RL member 6 as a filter 4 can form.

The series connection of the protective diode 3 and the fuse 20 , if necessary supplemented with the ohmic resistance in series 8th , and / or the coil 5 and / or the RL member 6 forms a parallel branch 7 to the overvoltage protection component 2 ,

When an overvoltage Us occurs, it is in the parallel branch 7 an operating current I _B through the first protection diode 3 occur and on the filter 4 a large part of the overvoltage drop, resulting in the response of the overvoltage protection component 2 leads. The protected line 10 is about the z. B. as a spark gap 11 trained overvoltage protection component 2 connected to the ground potential P. The overvoltage is dissipated to earth.

If there is a malfunction, a defective component or another electrical fault, the fault-free operation of the overvoltage protection component is required 2 no longer guaranteed. According to the invention is in parallel branch 7 to the overvoltage protection component 2 in series with the first protection diode 3 the electrical fuse 20 intended. Parallel to the electrical fuse 20 is advantageous a second protection diode 21 connected.

The fuse 20 limited in the parallel circle 7 flowing operating current I _B to a predetermined allowable value, in particular to the maximum operating current through the first protection diode 3 , This limitation has the advantage that the fuse 20 responds before the protection diode 3 is damaged. In case of a fault in the protection circuit 1 can in parallel branch 7 a current that is greater than the maximum operating current I _B is. An excessive operating current I _B is an indication of a malfunction of the protection circuit 1 and / or the overvoltage protection component 2 , with the result that in case of overvoltage the overvoltage protection component 2 not sure to respond. Because the fuse 20 to the maximum permissible operating current I _B is designed, is at too much operating current I _B the fuse 20 address and the current path of the parallel branch 7 separate. Has the fuse 20 addressed, is the second protection diode 21 no longer by the fuse 20 shorted, leaving at the second protection diode 21 a tension U _D drops. In the illustrated embodiment, the voltage U _D an evaluation circuit 23 fed as a failure indicator 9 the voltage signal at the second protection diode 21 evaluates.

By the in the parallel branch 7 to the overvoltage protection component 2 lying fuse 20 can be easily evaluated by evaluating the on the protection diode 21 declining voltage U _D on the state of the surge protection component 2 and the protection circuit 1 to be self-closed. A faulty state of the overvoltage protection component 2 is recognizable from the outside without special measures and / or via a signal line 24 display.

The second protection diode 21 is especially as a suppressor diode 22 educated. In the embodiment shown is a preferred embodiment of the suppressor diode 22 shown as bidirectional suppressor diode. The suppressor diode 22 is in particular a fail-safe suppressor diode with a fail-safe voltage of 24 volts.

The protective diode connected in the reverse direction 21 falling voltage U _D provides the necessary electrical energy to operate the evaluation circuit 23 to disposal. The evaluation circuit 23 controls the failure indicator 9 to, in the embodiment according to 1 as a local optical display, in particular as an LED 12 is trained.

The evaluation circuit 23 may alternatively or additionally a signal output 24 for a remote display of the state signal A have.

It is advantageous with the at the second protection diode 20 declining voltage U _D a relay via a rectifier and a smoothing capacitor 13 with z. B. controlled a closing contact. The output of the adhesive relay 13 may be a visual display, in particular an LED 12 turn.

Of particular advantage is that a destroyed fuse 20 can be seen not only when an overvoltage occurs, but also at one of the monitored line 10 applied supply voltage. As the surge protection component 2 is electrically open, one on the line 10 pending supply voltage substantially at the first protection diode 3 fall off. At an AC voltage of the essential voltage component falls z. B. on the filter 4 from. Regardless, at the first protection diode 3 a partial voltage drop regardless of whether the fuse 20 has addressed or not. Has the fuse 20 addressed, is the second protection diode 21 no longer short-circuited, so that at the second protection diode 21 also a partial voltage drops. The at the second protection diode 21 falling voltage U _D is both at the line 10 applied supply voltage as well as overvoltage on. The at the second protection diode 20 falling voltage U _D is used for failure indication.

In particular 1 shows is the protection circuit 1 in particular together with the overvoltage protection component 2 in a module housing 15 arranged. Such a module housing 15 can be designed as a plug-in component for control cabinets and the like. According to the invention, the failure indication according to the invention is provided 9 in the module housing 15 the overvoltage protection component 2 to arrange, in particular without changing the outer dimensions of the module housing 15 , As an optical failure indicator is an LED 12 advantageous.

The basic principle of the protection circuit according to the invention 1 is in 2 shown as a block diagram. At the input E of the overvoltage protection component 2 is the line to be protected 10 connect at the output the earth potential P. The parallel branch 7 is formed by the series connection of a filter 4 with the first protection diode 3 and the in-line fuse 20 that the parallel branch 7 connects to the ground potential P. Electric parallel to the fuse 20 is the particular as a suppressor diode 22 trained second protection diode 21 arranged. The at the second protection diode 21 decreasing voltage is the evaluation circuit 23 fed, which via a signal output 24 outputs a status signal A for error indication.

To increase the reliability can - as the block diagram in 3 shows - in parallel circle 7 several backups 20a . 20b and 20c be arranged in series, with the fuses 20a . 20b and 20c have different values of current limiting. Advantageously have the fuses 20a . 20b and 20c increasing current values; so can the first backup 20a a current limit of z. B. 80% of the operating current I _B have the second backup 20b a current limit of z. B. 100% of the operating current I _B have and the third backup 20b a current limit of z. B. 120% of the operating current I _B to have. To every backup 20a . 20b and 20c is each a protective diode 21a . 21b and 21c connected in parallel, being connected to a protective diode 21a . 21b and 21c only then a tension U _D falls off if its associated fuse 20a . 20b or 20c responds, ie the current path separates. Each protection diode 21a . 21b and 21c is an evaluation circuit 23a . 23b . 23c assigned, wherein the first evaluation circuit 23a an output signal A , the second evaluation circuit 23b an output signal B and the third evaluation circuit 23c an output signal C outputs. Such a cascade circuit can also trend ads because z. B. a prone to failure first protection diode 3 or suppressor diode 14 an increasing operating current I _B shows. A future expected failure of a surge protection component 2 can be displayed with high reliability.

Claims (20)

Protection circuit (1) against overvoltage on a live electrical line (10), wherein the electrical line (10) via a Protective diode (3) to a reference potential (P) is connected, characterized in that electrically in series with the protective diode (3), an electrical fuse (20) is connected, and electrically connected in parallel to the fuse (20) a failure indicator (9) is that indicates a failure of the protection circuit (1). Protection circuit after Claim 1 , characterized in that the fuse (20) limits the current flowing through the protective diode (3) operating current (IB) to a predetermined value. Protection circuit after Claim 1 , characterized in that the fuse (20) to the maximum operating current (I _B ) of the protective diode (3) is designed. Protection circuit after Claim 1 , characterized in that the failure indicator (9) comprises an evaluation circuit (23), and the evaluation circuit (23) evaluates a voltage (UD) dropping across the fuse (20). Protection circuit after Claim 1 , characterized in that the protective diode (3) electrically connected in series with the fuse (20) forms a first protective diode (3), and a second protective diode (21) is electrically connected in parallel with the fuse (20) and connected to the second protection diode (21) falling voltage (UD) of the failure indicator (9) is supplied. Protection circuit after Claim 1 , characterized in that electrically in series with the series circuit of protective diode (3) and fuse (20) an ohmic resistor (8) is arranged. Protection circuit after Claim 1 , characterized in that an overvoltage protection component (2) is arranged electrically parallel to the series circuit of protective diode (3) and fuse (20). Protection circuit after Claim 7 , characterized in that electrically in series with the series circuit of protective diode (3) and fuse (20), a coil (5) is arranged. Protection circuit after Claim 7 or 8th , characterized in that electrically in series with the series circuit of protective diode (3) and fuse (20), a filter (4) is arranged. Protection circuit after Claim 1 , characterized in that the protective circuit (1) in a module housing (15) is arranged and the failure indicator (9) is accommodated in the space of the module housing (15). Protection circuit after Claim 1 , characterized in that the failure indicator (9) is a local visual display, in particular an LED (12). Protection circuit after Claim 1 , characterized in that the failure indicator (9) is designed as a remote display. Protection circuit after Claim 1 , characterized in that the overvoltage protection component (2) is a separating spark gap (11), a gas discharge gap or a varistor. Protection circuit after Claim 1 , characterized in that in series with the fuse (20) lying protective diode (3) is a suppressor diode (14), preferably a bidirectional suppressor diode, in particular a fail-safe suppressor diode. Protection circuit after Claim 5 , characterized in that parallel to the fuse (20) lying second protective diode (21) is a suppressor diode (22), preferably a bidirectional suppressor diode, in particular a fail-safe suppressor diode. Protection circuit after Claim 1 , characterized in that the electrical line (10) is a data line. Protection circuit after Claim 1 , characterized in that the reference potential (P) is the ground potential. Protection circuit after Claim 1 characterized in that in series with the first protection diode (3) is a series connection of at least two fuses (20a, 20b, 20c) with different current values, that each fuse a second protection diode (21a, 21b, 21c) is electrically connected in parallel, and that the voltages dropping at the second protection diode (21a, 21b, 21c) are evaluated in an evaluation circuit (23) of the failure indicator (9) for a trend display. Protection circuit after Claim 1 , characterized in that the energy for operating the failure indicator (9) via the at the second protection diode (21) falling voltage (UD) is tapped. Protection circuit after Claim 1 , characterized in that the failure indicator (9) comprises an adhesive relay (13), which electrically switches an optical or acoustic display.

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