DE19833224B4 - Circuit arrangement for protecting an electrical load - Google Patents

Abstract

Circuit arrangement for protecting an electrical load (3) with
A circuit breaker (4) having a control electrode (G) and a first and second electrode forming a load path,
- An electronic fuse (5) with a fusible conductor (8) and to the fusible conductor in good thermal contact signal generator (7),
- Wherein the load path of the circuit breaker and the fuse element of the electronic fuse to the load (3) in series between two supply terminals (1, 2) are connected, and
- The signal generator (7) together with a resistor (6) forms a voltage divider (6, 7) which is arranged parallel to the series circuit (3, 4, 8) at the supply terminals and via the center tap the control electrode (G) of the circuit breaker ( 4) with a control signal or control signal of the signal generator (7) can be controlled.

Description

The The present invention relates to a circuit arrangement for protection an electrical load with a circuit breaker, with a control electrode and a load path forming first and second electrodes, a load connected in series with the load path and a located between the control electrode and the second electrode Securing device.

Circuit breakers, for switching loads z. As DC motors, asynchronous motors or the like, be used protection against short-circuits have in the load circuit. This is necessary because otherwise the circuit breaker or in the worst case, even the load could be destroyed.

To For this purpose, the circuit breaker z. B. with one or more electronic temperature sensors provided whose signals from a Evaluation circuit are evaluated and the occurrence of a Short circuit, which causes a strong temperature rise in the circuit breaker Consequence, the circuit breaker switches off. When crossing a certain temperature value, the circuit breaker is switched off and thus a destruction prevented. In B. Morari, F. Bertotti, G. A. Vignola (Editor), Smart Power IC's, Technology's and applications, Springer Verlag 1996, page 85 et seq. Circuit breakers are described, which have a sensor for their protection. This is done on the semiconductor chip of the circuit breaker glued on a sensor chip. The sensor chip is electrically connected to the circuit breaker, wherein the interconnection between gate electrode and source electrode of the circuit breaker is made. The sensor chip is in this case as a thyristor executed which responds at a predetermined temperature of 150 ° C, and the circuit breaker when exceeded switches off this temperature limit. The sensor chip is to this Purpose good heat-conducting connected to the circuit breaker.

It Circuit breakers are still known in which a diode or a transistor sensor near the hottest point of the circuit breaker are integrated. The signal of the sensor is then from an evaluation circuit processed so that the shutdown of the circuit breaker or at least a power reduction takes place as soon as the temperature applied to the sensor exceeds a predetermined threshold. Normally, the switching thresholds are between 150 ° C and 180 ° C.

The described circuit breakers are both in discrete as well available in monolithic construction. A disadvantage of the described state the technique is that in the Case of failure of semiconductor electronics, z. B. by a poor bond between the sensor chip and the circuit breaker, the load circuit is not interrupted, so that the circuit breaker or the load is damaged could become.

The DE 44 01 956 A1 describes a power semiconductor device having a temperature sensor that controls the power semiconductor device by switching a controllable switch from the conductive state to a region of higher resistance when the temperature in the semiconductor body of the power semiconductor device reaches a critical value.

The DE 27 58 890 C3 describes a semiconductor device which is connected by a thin lead wire to a terminal. This lead wire is designed such that it melts at a current which is above a predetermined current.

The The object of the present invention is therefore a circuit arrangement to provide protection of an electrical load in the event of overload or a short circuit safely interrupts the load circuit.

These Task is performed according to the characteristics of Patent claim 1 solved.

further developments The invention can be found in the dependent claims.

According to the invention Task solved by that the Circuit arrangement comprising a circuit breaker with a control electrode and a first and a second electrode, wherein with the load path formed by the first and the second electrode If a load is connected in series, a safety device between the control electrode and the second electrode of the circuit breaker is arranged. The safety device is designed as an electronic fuse.

The Fuse has a fusible conductor and an electrical one Signal producing and electrically connected to the fusible conductor Signaling on, wherein the fusible conductor and the signal generator in good thermal contact. The fusible conductor and the signal generator are interconnected in series. The series connection of the fusible conductor and the signal generator is so between the gate electrode and the second electrode of the circuit breaker switched that the fusible link connected to the second electrode, while the signal transmitter with the Control electrode is in communication.

At the Connection point between the signal transmitter and the fusible conductor is a second supply connection, the one opposite one first supply connection lower Potential, connected. The series connection of the load, the circuit breaker and the fusible conductor is between the first, a high potential supply connection and the interconnect the second supply connection.

Farther is between the control electrode of the circuit breaker and the first supply connection Resistor switched.

The Protection circuit according to the invention therefore consists of a safety device with a fusible link and a signal generator, which are thermally and electrically interconnected are coupled. The characteristics of the signal generator are such that at a warming the signal transmitter through the fusible conductor, z. B. at an overcurrent, the Signal generator is low impedance. Due to the interconnection of the signal transmitter and the resistor, which are connected in series, and their connection point is connected to the control electrode of the circuit breaker form the switch and the resistor a voltage divider. Will the Resistance of the signal transmitter when heated lower, so reduced also the voltage occurring at the control electrode. By the reduction of the voltage between control electrode and second Electrode is the power switch back regulated, d. H. the electricity over his Last stretch goes back. Overheating the Circuit breaker or the load can be prevented in this way become.

advantageously, the signal generator is designed as a thyristor. At a temperature of about 150 ° C, by the warming of the fusible conductor, the thyristor fires and switches the Circuit breaker off. A destruction of the circuit breaker and the load is thereby prevented. The temperature at which the thyristor ignites, lies clearly over normal ambient temperatures in electrical circuits, causing a malfunction be excluded by external influences can. On the other hand, this temperature is not so high than that not of a fusible conductor in the transition or overload range can be achieved, d. H. the fusible conductor remains with this Temperature intact. Should for some reason the circuit breaker do not turn off, eg. B. due to a malfunction of the signal generator, so the fuse interrupts the load circuit and protects it Device in front a defect. After removing the cause of the error or replacing the Fuse is the full functionality, d. H. Protection against overload, fully guaranteed again.

Of the Advantage of the security device according to the invention is that these easy and inexpensive is realized by a fuse with a signal generator, preferably a thyristor. In this case is it is not necessary to use the circuit breaker as an intelligent circuit breaker to provide with a protective function.

In an embodiment can the fusible conductor and the signal generator are arranged in a common housing be. In this case, the securing device is designed as a three-terminal, d. H. the protection circuit is provided with only three external terminals. The thyristor and the fusible conductor then have a common Entrance.

The invention will be described below with reference to the single 1 explained in more detail. 1 shows the inventive circuit arrangement for protecting an electrical load with an electronic security device.

1 shows a power supply with a first supply terminal 1 and a second supply terminal 2 , The supply connection 2 is at a lower potential than the supply connection 1 , Preferably, the supply connection 2 at a fixed potential, z. B. mass. The figure also shows a load to be protected 3 that come in series with a circuit breaker 4 is switched. The circuit breaker 4 has a control electrode and a first electrode and a second electrode. The circuit breaker 4 is designed as a MOSFET, ie the control electrode is the gate, the first electrode is the drain, the second electrode is the source. The circuit breaker may also be another voltage-controlled component. The protection circuit is designed in the figure as a so-called low-side switch, ie the load 3 is connected to the drain of the circuit breaker 4 connected. Between the gate and the source of the circuit breaker 4 is a safety device 5 switched. The safety device 5 consists of a signal generator 7 and a fusible link 8th , The signal generator 7 and the fusible conductor 8th are connected in series. Here is the fusible link 8th with the source of the circuit breaker 4 connected while the signaler 7 with the gate of the circuit breaker 4 communicates. At a connection point 9 between the signal generator 7 and the fusible conductor 8th the second supply connection is connected. The first supply connection 1 is with the load 3 connected. Between the first supply connection 1 and the gate of the circuit breaker 4 there is a resistance 6 , The resistance 6 and the signal generator 7 form a voltage divider. Weight 3 can z. B. a lamp or an electric motor with full or Be half-bridge drive. However, every other load is conceivable. It only has to be ensured that the main current path of the load is the circuit breaker 4 as well as the fusible link 8th connected in series.

Increases z. B. by a malfunction in the main current path of the load 3 the current, this is in a heating of both the circuit breaker 4 as well as the fusible conductor 8th noticeable. Due to the good thermal coupling between the signal generator 7 and the fusible conductor 8th becomes the signal generator 7 low resistance. As a result, the gate-source voltage of the circuit breaker decreases 4 and regulates the power back over the load path. Preferably, the signal generator 7 executed as a thyristor. When a certain limit temperature of the thyristor is exceeded, this ignites and switches the circuit breaker 4 out. A defect of the load 3 is thus prevented.

Should for some reason the circuit breaker 4 do not turn off, then the fusible link 8th heated until it reaches its melting point and burns. The melting temperature of a fusible conductor in the hotspot is approx. 900 ° C. The fuse element has a response characteristic that ensures burnout of its fuse conductor before the circuit breaker 4 or the load 3 to suffer a defect.

The advantage of the invention is that the circuit breaker 4 no own protection device needed. This saves costs and simplifies production. When melting the fusible conductor in case of overload, the function of the load 3 be easily restored by simply replacing the fusible conductor.

Preferably, as a signal generator 7 a thyristor, which ignites at a temperature of about 150 ° used. However, it is also conceivable to execute the signal generator as a temperature sensor logic. This means that a temperature sensor is thermally well connected to the fusible conductor and passes the temperature to a Auswertelogik that reduces the resistance between the gate electrode and the connection point 9 or reduces the gate voltage in other ways.

In the 1 shown protection circuit is realized as a low-side switch. However, it is of course also possible, the load on the source side of the circuit breaker 4 to arrange, ie to realize the protection circuit as a so-called high-side switch. The principle of the invention is to perform the circuit breaker, the load and the fusible conductor in series, so that in case of too high a current and a possible malfunction of the circuit breaker 4 the current is interrupted by the melting of the fuse conductor.

Claims (6)

Circuit arrangement for protecting an electrical load ( 3 ) with - a circuit breaker ( 4 ) with a control electrode (G) and a load path forming first and second electrode, - an electronic fuse ( 5 ) with a fusible conductor ( 8th ) and to the fusible conductor in good thermal contact signal generator ( 7 ), - the load path of the circuit breaker and the fuse link of the electronic fuse with the load ( 3 ) in series between two supply connections ( 1 . 2 ), and - the signal generator ( 7 ) together with a resistor ( 6 ) a voltage divider ( 6 . 7 ) parallel to the series connection ( 3 . 4 . 8th ) is arranged at the supply terminals and via the center tap the control electrode (G) of the circuit breaker ( 4 ) with a control signal or control signal of the signal generator ( 7 ) is controllable. Circuit arrangement according to Patent Claim 1, characterized in that the signal generator ( 7 ) becomes lower impedance with increasing temperature and controls the control terminal with a temperature-dependent control signal or control signal. Circuit arrangement according to one of the preceding claims, characterized in that the signal generator ( 7 ) and the fusible link ( 8th ) each with the same supply connection ( 2 ) are connected. Circuit arrangement according to Patent Claim 3, characterized in that the signal generator ( 7 ) and the fusible conductor ( 8th ) connected supply connection ( 2 ) has a reference potential. Circuit arrangement according to one of the preceding claims, characterized in that the signal generator ( 7 ) is a thyristor which ignites when a first limit temperature is exceeded and the circuit breaker ( 4 ) turns off. Circuit arrangement according to one of the preceding claims, characterized in that the fusible conductor ( 8th ) when a second limit temperature is exceeded, which is higher than a first limit temperature of the signal generator ( 7 ), melted.