DE3536447C2 - Short-circuit and overload-proof transistor output stage - Google Patents

Description

The invention relates to a short-circuit and overload-proof Transistor output stage with one in series with a measuring resistor arranged transistor, which feeds a load, and with one of the Voltage drop across the measuring resistor applied first Monitoring device, whose output to the control electrode of the Transistor is placed, as well as with at least one of the voltage drop applied to the transistor second monitoring device whose Output signal via a time delay element in the event of overcurrents Transistor controlling signal delivers.

Such a transistor output stage is known (EP 0 111 028 A2). In this known transistor output stage is the second Monitoring device in a positive feedback circuit with the first Monitoring device connected. The transistor output stage, the contains a power transistor, is said to have very low control power are actuated and none in the event of a short circuit or overload generate significant power loss.

An integrated driver amplifier with a is also known Monitoring device in the event of an overcurrent Interruption or in the event of a short circuit in the load circuit Error signal generated. In series with a Darlington transistor is one Measuring resistor arranged with the Base of the Darlington bipolar transistor is connected, which continues is connected to a driver circuit (DE 34 11 900 A1).

Finally, circuit arrangements with transistors are known in the event of a short circuit or overload, the voltage drop across a the output current at a resistance monitoring circuit limit the current through the transistor (JP 59-2190190 A, Patents Abstr. of Japan, Sect. E. Vol. 9 (1985), No. 89, GB 21 38 644 A).

The invention has for its object a transistor output stage to further develop the genus described at the beginning such that with low drive power and faster in the event of a short circuit Output current limit when switching on the power transistor rapid saturation is achieved and when switching off inductive or inductive loads can be quickly de-excited.

The object is achieved by the features in claim 1 solved. By using a metal oxide field effect transistor as Output transistor becomes only a small one despite high output currents Driving current required. This also reduces the power loss in the Control circuits reduced. The control circuits can therefore be formed as an integrated circuit. In the event of a short circuit, feeds the monitoring and control arrangement has a current limiting potential directly into the gate electrode so that the via the MOSFET flowing current is limited very quickly. In the event of an overload, the Delayed current limitation only when, after the decay of current peaks caused by capacitive loading the permissible output current is exceeded.

Since there is a higher potential for a control signal via the driver stage is supplied as the operating potential of the MOSFET of the gate electrode MOSFET therefore highly saturated, so that the lowest possible Drain-source voltage arises. The power losses of the MOSFET low even at higher currents. If inductive loads or Inductive loads are switched off with the MOSFET negative voltages at the connection for the load. These tensions are used to apply negative potential to the gate electrode exploited to the MOSFET for quick de-excitation of inductive loads to use. Preferably, that between the negative pole is the Operating voltage source and the one operating voltage connection arranged diode a zener diode.  

The Zener diode is used when switching off inductive loads Operating voltage connection occurring voltage to one for the Driver circuit and the drain-source electrode of the MOSFET harmless, but for the rapid de-excitation of inductive loads limited optimal value.  

A particularly favorable embodiment is described in claim 4. With the measures specified in claim 4, the MOSFET can at outside to the step via the load or the connecting lines to Load coupled negative interference voltages protected from destruction will. Negative interference voltage pulses that are connected to the transistor output stage, lead to a reversal of the polarities of the Voltages at the inputs of the first monitoring device, so that the first monitoring device serving to limit the current becomes ineffective. This will result in destruction by exceeding the permissible reverse voltages avoided.

Another preferred embodiment is explained in claim 5. With this embodiment, one based on an overcurrent can Record the fault by setting a memory in the event of a fault, while at the same time the control of the MOSFET is interrupted. The Disturbance can be achieved by means of an optical downstream of the memory and / or acoustic device can be reported. Through the back After the fault has been remedied, the memory is reset gear stage released for operation again.

The positive operating potential for the driver scarf is preferred from the operating voltage for the load with a rectangular generator tor and a booster circuit generated, as one Capacitor the capacitance between the gate electrode and the source Electrode of the MOSFET is used, the gate electrode over a switchable from the driver circuit to negative operating potential Resistor is connected to a diode of the booster circuit. With this arrangement, the charging of the gate-source capacitance at Switching the MOSFET from the non-conductive to the conductive state  co-determined the resistance. The capacity does not load immediately on. By the one running according to a predetermined time constant Charging becomes a flattening of the rising edges of the load currents achieved. This is for the stress on the transistor output stage, Particularly favorable with capacitive loads at the output.

The invention is described below with reference to a drawing illustrated embodiment described in detail, from which further features and advantages result.

It shows

Fig. 1 is a block diagram of a short circuit and overload solid transistor output stage,

Fig. 2 details of the transistor output stage shown in Fig. 1.

A power MOSFET 1 is connected with its drain electrode to the positive pole 2 of an operating voltage source 3 . The source electrode of the MOSFET 1 is connected to a measuring resistor 4, which is connected in series with the drain-source path of the MOSFET 1 to an output 5 of the transistor output stage 6 shown in FIG. 1. An inductive load 7 is connected to the output 5 with a connection. The other connection of the load 7 is connected to the negative pole 8 of the operating voltage source 3 . The pole 8 is e.g. B. grounded. The gate electrode of MOSFET 1 is connected both to the output of a driver circuit 9 and to the output of a first monitoring device 10 . The driver circuit 9 is connected on the input side to an AND gate circuit 11 which has two inputs 12 , 13 , of which the input 12 can be supplied with a control signal for controlling the MOSFET 1 in the conductive state.

The first monitoring device 10 is connected to a first, not designated input to the ver connected to the source electrode of the MOSFET 1 end of the resistor 4 and to a second, not designated input to the one end of a resistor 14 , the other end is connected to the output 5 together with the resistor 4 .

The driver circuit 9 is connected to its operating voltage connection 15 for positive voltage via a step-up circuit 16 with the pole 2 . The operating voltage connection 17 of the driver circuit 9 for negative voltage is via a potential opposite the potential of the pole 2 in the forward direction polarized diode 18 with the opposing stand 14 or the one input of the first monitoring device 10 . Furthermore, the operating voltage connection 17 is connected to the anode of a Zener diode 19 , the cathode of which is connected to the pole 8 . A second monitoring device 20 contains two inputs, not specified, one of which is connected to the drain electrode of the MOSFET 1 and one to the end of the resistor 4 which is connected to the output 5 . The second monitoring device 20 feeds an input of an AND gate circuit 21 on the output side, the other input of which is connected to the output of the AND gate circuit 11 . The output of the AND gate circuit 21 is connected to the input of a time delay element 22 , the output of which is connected to the set input of a memory 23 , the reset input 24 of which can be acted upon with an externally generated reset signal. The output of the memory 23 is connected to the input of the AND gate circuit 11 . The monitoring device 10 responds when the voltage present at its inputs exceeds a certain threshold, ie when the voltage at the source electrode of the MOSFET 1 is higher than the voltage at the terminal 5 by a threshold value. The response of the first monitoring circuit 10 acts on the potential of the gate electrode of the MOSFET 1 in such a way that the current through the MOSFET is regulated to a constant limit value.

A simple implementation option for the monitoring device 10 is to use a bipolar transistor which is placed with its base on the source electrode of the MOSFET 1 and the emitter of which was connected via the counter 14 to the terminal 5 , while the collector is connected to the Gate electrode of MOSFET 1 is connected. For example, 2 A flow through the MOSFET 1 , which are required to actuate a solenoid valve. The resistor 4 is dimensioned such that in the event of a short circuit at the output 5, a voltage drop across the resistor 4 occurs which exceeds the base-emitter threshold voltage and thus controls the transistor in a conductive manner. At a rated current of 2 A, the voltage drop across resistor 4 does not exceed the threshold voltage, so that the transistor is non-conductive. In the event of a short circuit, a low potential passes via the emitter-collector path of the transistor to the gate electrode of MOSFET 1 and thus gently limits the current flowing through MOSFET 1 to a permissible value. The application of the gate electrode of the MOSFET 1 in this case is independent of the output potential of the driver circuit 9 , ie the first supervising device 10 pulls the signal generated for the control of the MOSFET 1 into the conductive state by the driver circuit 9 to the low level down, which is necessary for the current limitation.

The voltage boost circuit 16 supplies the operating voltage connection 15 of the driver circuit 9 with a potential which is at least higher than the operating voltage of the voltage source 3 by the gate-source saturation voltage of the MOSFET 1 . When a signal which triggers the switching on of the MOSFET 1 into the conductive state reaches the driver circuit 9 via the input 12 of the AND gate circuit 11 , this higher potential is applied to the gate electrode of the MOSFET 1 . The MOSFET 1 is therefore saturated, so that the voltage drop across the drain-source path is small. This also results in only small power losses, as a result of which undesirably high heating of the MOSFET 1 is avoided.

In order to control the MOSFET 1 in the non-conductive state, the potential at the operating voltage connection 15 is blocked by the elimination of the drive signal fed in via the input 12 , while at the same time a conductive connection is established between the gate electrode of the MOSFET 1 and the operating voltage connection 17 . For loads that are at least partially inductive, negative voltages occur at connection 5 due to the reduction in the load current.

These negative voltages pass through the resistor 14 and the diode 18 to the Zener diode 19 , which provides a certain negative level, which acts on the gate electrode of the MOSFET 1 via the operating voltage connection 17 and the driver circuit 9 . A negative gate voltage limited by the zener diode 19 also limits the negative voltages at the terminal 5 . A faster de-excitation of inductive loads is associated with the negative voltage, so that the transition of the MOSFET 1 to the non-conductive state takes place more quickly. A major advantage of the arrangement described above can therefore be seen in the fact that the MOSFET 1 switches more quickly to the non-conductive state without its own negative operating voltage source. The driver circuit 5 advantageously consists of a bipolar transistor, the emitter-collector path between the operating voltage connection 17 and the operating voltage connection 15 is arranged, while the output is connected via a resistor to the operating voltage connection 15 . The base of this bipolar transistor is connected to the output of the AND gate circuit 11 . Depending on whether the drive signal is present or not, the bipolar transistor is controlled in a non-conductive or conductive manner, as a result of which the conductive connection between the operating voltage connection 15 or the operating voltage connection 17 is established.

If a negative interference voltage is coupled in, for example, via the lines to the load 7 when the MOSFET 1 is blocking, this leads to voltage limitation in the arrangement explained above, in order to avoid a voltage breakdown of the MOSFET 1 in such a case. In the case of a coupled negative interference voltage at the output 5, the polarity of the voltages at the inputs is reversed at the first monitoring device 10 in comparison to the mode of operation when the MOSFET 1 is conductive. Therefore, the monitoring device 10 outputs an output signal with a high level, by means of which the MOSFET 1 is controlled to be conductive. The voltage stress on the MOSFET 1 is thus reduced to harmless values.

The voltage drop across the drain-source path of the MOSFET 1 and the measuring resistor 4 depends on the amount of current which flows when the MOSFET 1 is running. The second monitoring device 20 , which can be designed as a Schmitt trigger, is set in its response threshold to a voltage drop which occurred at an impermissibly high continuous current on the drain-source path and the measuring resistor 4 for the MOSFET 1 . In this case, the second monitoring circuit outputs an output signal which, in conjunction with the output signal of the AND gate circuit 11 , controls the AND gate circuit 21 in a permeable manner when there is a control signal at the input 12 . As a result, the timer 22 is triggered by the memory 23 is set after a set delay time Ver. The output signal of the memory 23 blocks the AND gate circuit 11 , so that the driver circuit 9 outputs a blocking signal to the gate electrode of the MOSFET 1 . By blocking the MOSFET 1 , the current flow and thus the impermissibly high overcurrent is switched off. Short-term current pulses that exceed the value of the permissible continuous current occur due to capacitive charging currents when switched on. These currents do not destroy the MOSFET 1 . In order to prevent the MOSFET 1 from being switched off in the case of such currents, the time delay element 22 is provided, the delay time of which is matched to the duration of these currents.

The second monitoring device 20 preferably contains a bipolar transistor, the base of which is subjected to a constant voltage while the emitter is connected to the terminal 5 via a diode. The base voltage is set so that the transistor blocks at permissible currents in MOSFET 1 . In the event of overcurrents, the transistor becomes conductive and applies a signal to the AND gate circuit 21 , which controls it in a permeable manner.

The voltage boost circuit 16 shown in Fig. 2 ent holds a square wave generator 24 , which is supplied by the operating voltage source 3 with operating voltage. The square wave signals generated by the generator 24 are fed via a capacitor 25 , two diodes 26 , 27 , one of which is connected to the pole 2 of the operating voltage source 3 with its anode. The cathode of the diode 26 and the anode of the diode 27 are each connected to one side of the capacitor 25 . The diode 27 is followed by two resistors 28 , 29 arranged in series. The gate electrode of the MOSFET 1 is connected to the resistor 29 , the drain electrode of which is connected to the potential of the pole 2 . The common connection point of the resistors 28 , 29 is connected to the operating voltage connection 15 . A voltage boost circuit is formed by the capacitor 25 , the gate-drain capacitance of the MOSFET 1 and the diodes 26 , 27 .

The state of charge of the gate-drain capacitance of the MOSFET 1 is determined in the rest by the driver circuit 9 and the device 10 , the first monitoring device. If a discharge z. B. on the driver circuit device 9 or the monitoring device 10 has taken place, then the charging will gradually proceed as a result of the resistors 28 , 29 . The edge of the current flowing through the MOSFET 1 is therefore somewhat flattened. This is favorable for the operation of the circuit described above.

Claims (9)

1. Short-circuit and overload-proof transistor output stage with a transistor arranged in series with a measuring resistor that feeds a load, and with a first monitoring device acted upon by the voltage drop across the measuring resistor, the output of which is connected to the control electrode of the transistor, and with at least one of the voltage drop across Transistor applied second monitoring device, the output signal via a time delay element supplies a signal controlling the transistor in the event of overcurrents, characterized in that the transistor is a MOSFET ( 1 ) controlled by a driver circuit ( 9 ) that the output of the first monitoring device ( 10 ) together with the output of the driver circuit ( 9 ) is connected to the gate electrode of the MOSFET ( 1 ), and that the time delay element ( 22 ) is connected to a gate circuit ( 11 ) which blocks the output signal of the driver circuit ( 9 ) in the event of overcurrents, di e driver circuit with an operating voltage connection ( 15 ) at a higher potential than the operating potential of the transistor output stage and with the other operating voltage connection ( 17 ) on the one hand via a polarity of the operating voltage in the reverse direction polarized first diode ( 18 ) to the connection ( 5 ) for the Load ( 7 ) and, on the other hand, is connected to the negative pole of the operating voltage source via a second diode ( 19 ) which is polarized in the forward direction with respect to the negative potential of the operating voltage source ( 3 ). 2. Transistor output stage according to claim 1, characterized in that the potential of the one operating voltage connection ( 15 ) by the gate-source saturation voltage is higher than the potential of the transistor output stage. 3. Transistor output stage according to claim 1, characterized in that the second diode is a Zener diode ( 19 ). 4. Transistor output stage according to claim 1, characterized in that an input of the first monitoring device ( 10 ) is connected via a resistor ( 14 ) to the connection ( 5 ) for the load ( 7 ) and that the first monitoring device ( 10 ) when the Polarities of the voltages at the input connected to the connection ( 5 ) for the load ( 7 ) and at the other input connected to the measuring resistor ( 4 ) do not emit a signal blocking the MOSFET ( 1 ). 5. Transistor output stage according to one of the preceding claims, characterized in that the output of the second monitoring device ( 20 ) in conjunctive link ( 21 ) with the output signal of an AND gate circuit ( 11 ) to the time delay element ( 22 ) is placed, at the output of which Set input of an externally resettable memory ( 23 ) is connected, the output of which is fed back to an input of the AND gate circuit ( 11 ), the other input ( 12 ) of which can be acted upon by a control signal and the output of which is connected to the driver circuit ( 9 ) . 6. Transistor output stage according to one of the preceding claims, characterized in that the positive potential for the driver circuit ( 9 ) from the operating voltage for the load with a rectangular generator containing voltage boosting circuit ( 16 ) is generated, as a capacitor, the capacitance between the gate and Drain electrode of the MOSFET ( 1 ) is used, and that the gate electrode of the MOSFET ( 1 ) is connected via a resistor ( 28 , 29 ) connected to the driver circuit ( 9 ) to a diode ( 27 ) of the step-up circuit ( 16 ) . 7. Transistor output stage according to one of the preceding claims, characterized in that the first monitoring device ( 10 ) is a bipolar transistor, the collector of which is connected to the gate electrode of the MOSFET ( 1 ), while in each case the base to the source electrode and the emitter are connected to the connection for the load ( 7 ) via a resistor ( 14 ). 8. Transistor output stage according to one of the preceding claims, characterized in that the driver circuit ( 9 ) is a bipolar transistor, the base of which is connected to the AND gate circuit ( 11 ), while in each case the collector is connected to a tap of voltage divider resistors in the step-up circuit and Emitters are connected to the second diode. 9. Transistor output stage according to one of the preceding claims, characterized in that the second monitoring device is a bipolar transistor, the emitter of which is connected via a diode to the connection ( 5 ) for the load ( 7 ), while the base is supplied with a constant voltage and that the collector is connected to the AND gate circuit ( 21 ).