DE19833224A1 - Electric load protection circuit e.g. for protecting power switch used for switching DC motors, asynchronous motors and similar devices - Google Patents

Abstract

A circuit arrangement for protection of an electrical load (3) with a MOSFET power switch (4) having a gate (control) electrode and first and second electrodes forming a load path. A load (3) is connected in series with the load path, between a first and a second supply terminal (1,2), and a resistance (6) is connected between the first supply terminal (1) and the gate electrode. A fuse device (5) is provided between the gate electrode of the MOSFET power switch (4) and the second electrode. The fuse device (5) is specifically an electronic fusible link or cut-out (7,8) with a fuse element (8).

Description

The present invention relates to a circuit arrangement to protect an electrical load with a power scarf ter, with a control electrode and a load path forming first and second electrodes, one with the load stretch load connected in series and one between the Control electrode and the second electrode located Siche device.

Circuit breakers used for switching loads e.g. B. Right away current motors, asynchronous motors or the like protection against short circuits in the load circuit exhibit. This is necessary because otherwise the performance switch or, in the worst case, even destroys the load could be.

For this purpose, the circuit breakers z. B. with a or provide several electronic temperature sensors, de signals can be evaluated by an evaluation circuit and that when a short circuit occurs that is a strong one Temperature rise in the circuit breaker causes Circuit breaker trips. If a be exceeded The circuit breaker is tuned to the correct temperature value switches and thus prevents destruction. In B. Morari, F. Bertotti, G.A. Vignola (Editor), Smart Power IC's, Technologie's and applications, Springer Verlag 1996, page 85 ff. Circuit breakers are described that are related to their Protection have a sensor. This is on the semiconductor Circuit breaker chip a sensor chip glued on. The Sensor chip is electrically connected to the circuit breaker the, the connection between the gate electrode and the Sour ceelectrode of the circuit breaker is made. The sen In this case, sorchip is designed as a thyristor, which at responds to a predetermined temperature of 150 ° C, and the  Circuit breaker when this temperature limit is exceeded switches off. The sensor chip is good for this purpose tend to be connected to the circuit breaker.

Circuit breakers are also known, in which a Diode or transistor sensor near the hottest The circuit breaker are integrated. The signal of the The sensor is then processed by an evaluation circuit that the opening of the circuit breaker or at least egg The output is reduced as soon as it is connected to the sensor temperature exceeds a predetermined threshold. The switching thresholds are normally between 150 ° C and 180 ° C.

The circuit breakers described are both in discrete and also available in a monolithically integrated design. A disadvantage of the described prior art is that in In the event of semiconductor electronics failure, e.g. B. by a poor bond between the sensor chip and the Circuit breaker, the load circuit is not interrupted is, so that the circuit breaker or the load could be damaged.

The object of the present invention is therefore to a circuit arrangement for protecting an electrical load to be provided in the event of an overload or a short the load circuit safely interrupts.

This object is achieved in accordance with the features of patent claim 1 solved.

Developments of the invention are the subclaims remove.

According to the invention the object is achieved in that the Circuit arrangement comprising a circuit breaker with a Control electrode and a first and a second electrode  has, with the load path through the first and the second electrode is formed, a load in series is switched, has a safety device between rule the control electrode and the second electrode of the Lei control switch is arranged. The safety device is executed as an electronic fuse.

The fuse has one fuse and one producing electrical signal and using the fuse element electrically connected signal generator, the melting point ter and the signal generator are in good thermal contact. The fuse element and the signal transmitter are in series interconnect. The series connection from the fuse element and the signal generator is between the gate electrode and the second electrode of the circuit breaker switched that the Fusible conductor is connected to the second electrode rend the signal generator in connection with the control electrode stands.

At the connection point between the signal generator and the enamel The conductor is a second supply connection, the one opposite a first supply connection to lower potential points, connected. The series connection from the load, the lei switch and the fuse element is between the first, a high potential supply connection and the Connect the second supply connection.

Furthermore, between the control electrode of the power switch and the first supply connection a resistor switched.

The protective circuit according to the invention therefore consists of egg ner safety device with a fuse element and a Signal generators that are coupled thermally and electrically pelt are. The properties of the signal generator are such create that when the signal generator is heated by the Fusible conductor, e.g. B. in the event of an overcurrent, the signal generator  becomes low resistance. Due to the connection of the signal generator and the resistance, which are connected in series, and de ren connection point with the control electrode of the power switch is connected, form the signal generator and the Wi stood a voltage divider. If the resistance of the Si gnalenders less when heated, so also decreases the voltage occurring at the control electrode. Through the Reduction of the voltage between the control electrode and two the electrode, the circuit breaker is reduced, i. H. the current over its load route decreases. An over hit zen of the circuit breaker or the load can this way be prevented.

The signal transmitter is advantageously in the form of a thyristor guided. At a temperature of approx. 150 ° C, which is caused by the Heating of the fuse element causes the thy to ignite ristor and turns off the circuit breaker. A destruction The circuit breaker and the load are thereby prevented prevents. The temperature at which the thyristor ignites is well above normal ambient temperatures in electrical Circuits so that a malfunction due to external influences can be excluded. On the other hand, this tempera However, the structure is not so high that it cannot be Fusible conductor in the transition or overload range is reached that can, d. H. the fuse element remains at this tempera structure intact. Should for some reason the performance do not turn off the switch, e.g. B. due to a malfunction of the signal generator, then the fuse interrupts the Load circuit and protects the device from a defect. After this Eliminate the cause of the error or replace the melt Protection is full functionality, d. H. protection against Overload, fully guaranteed again.

The advantage of the safety device according to the invention be is that it is easy and inexpensive to implement ren by a fuse with a signal transmitter, preferably a thyristor. In this case  it is not necessary to consider the circuit breaker as intelligent circuit breaker with a protective function.

In one embodiment, the fuse element and the Signal generators can be arranged in a common housing. In In this case, the safety device is designed as a three-pole leads, d. H. the protection circuit is with only three external connections conclude. The thyristor and the fuse element have then a common entrance.

The invention is explained in more detail below with reference to the single FIG. 1. Fig. 1 shows the circuit arrangement according to the invention for protecting an electrical load with an electronic fuse device.

Fig. 1 shows a power supply having a first versor 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 is at a fixed potential, e.g. B. mass. The figure also shows a load 3 to be protected, which is connected in series with a circuit breaker 4 . The power switch 4 has a control electrode and a first electrode and a second electrode. The power switch 4 is designed as a MOSFET, ie the control electrode is the gate, the first electrode is the drain connection, the second electrode is the source connection. The circuit breaker can also be another voltage-controlled component. The protective circuit is shown in the figure as a so-called low-side switch ter, that is, the load 3 is connected to the drain circuit of the circuit breaker 4 . A fuse device 5 is connected between the gate connection and the source connection of the circuit breaker 4 . The Sicherheitsvor direction 5 consists of a signal generator 7 and a fuse 8th The signal generator 7 and the fuse element 8 are connected in series. Here, the fuse element 8 is connected to the source connection of the circuit breaker 4 , while the signal generator 7 is connected to the gate connection of the circuit breaker 4 . At a connection point 9 between the signal generator 7 and the Schutelzleiter 8 , the second supply connection is connected. The first supply connection 1 is connected to the load 3 . Between the first supply connection 1 and the gate connection of the circuit breaker 4 there is a resistor 6 . The resistor 6 and the signal generator 7 form a voltage divider. The load 3 can e.g. B. a lamp or an electric motor with full or half bridges drive. However, any other load is also conceivable. It only has to be ensured that the circuit breaker 4 and the fuse element 8 are connected in series to the main current path of the load.

Increases z. B. by a malfunction in the main current path of the load 3, the current, this is reflected in a heating of both the circuit breaker 4 and the fuse element 8 . Because of the good thermal coupling between the signal generator 7 and the fusible conductor 8 , the signal generator 7 becomes low-resistance. As a result, the gate-source voltage of the circuit breaker 4 drops and regulates the current back over the load path. The signal generator 7 is preferably designed as a thyristor. If a certain limit temperature of the thyristor is exceeded, it ignites and switches the circuit breaker 4 off. A defect of the load 3 is thus prevented.

If for some reason the circuit breaker 4 does not switch off, the fuse element 8 is heated further until it reaches its melting point and burns out. The melting temperature of a fuse element in the hotspot is approx. 900 ° C. The fuse element has a response characteristic which ensures that its fuse element burns out before the circuit breaker 4 or the load 3 suffers a defect.

The advantage of the invention is that the power switch 4 does not need its own protective device. This saves costs and simplifies production. If the fuse element melts in the event of an overload, the function of the load 3 can be easily restored by simply replacing the fuse element.

A thyristor which ignites at a temperature of approximately 150 ° C. is preferably used as the signal transmitter 7 . However, it is also conceivable to design the signal transmitter as a temperature sensor logic. This means that a temperature sensor is thermally well-connected to the fuse element and passes the temperature on to an evaluation logic which reduces the resistance between the gate electrode and the connection point 9 or else reduces the gate voltage in another way.

The protective circuit shown in Fig. 1 is realized as a low-side switch ter. However, it is of course also possible to arrange the load on the source side of the circuit breaker 4 , ie to implement the protective circuit as a so-called high-side switch. The principle of the invention is to run the circuit breaker, the load and the fuse as a series connection, so that in the event of too high a current and a possible malfunction of the circuit breaker Lei 4, the current is interrupted by the melting of the fuse.

Claims (7)

1. Circuit arrangement for protecting an electrical load ( 3 ) with

• - A circuit breaker ( 4 ) with a control electrode and a first and second electric de forming a load path.
• - A load ( 3 ) connected in series with the load path between a first and a second supply connection, ( 1 , 2 ),
• - A resistor ( 6 ) located between the first supply connection ( 1 ) and the control electrode,

a safety device ( 5 ) being present between the control electrode and the second electrode. 2. Circuit arrangement according to claim 1, wherein the fuse device ( 5 ) is an electronic fuse ( 7 , 8 ) with a fuse element ( 8 ) and an electrical signal producing signal generator ( 7 ), the fuse element ( 8 ) and the signal generator ( 7 ) are in good thermal contact. 3. Circuit arrangement according to claim 2, wherein the fuse element ( 8 ) is connected in series with the signal generator ( 7 ) ge, such that the fuse element ( 8 ) is connected to the second electrode. 4. Circuit arrangement according to claim 3, wherein the connection point ( 9 ) between the signal generator ( 7 ) and the fuse element ( 7 ) is connected to the second supply connection ( 2 ). 5. Circuit arrangement according to claim 4, wherein the second supply connection ( 2 ) is at a fixed potential. 6. Circuit arrangement according to one of the claims 2 to 5, wherein the signal transmitter ( 7 ) becomes low-resistance when heated. 7. Circuit arrangement according to one of claims 2 to 6, wherein the signal generator ( 7 ) is a thyristor.