DE102017123484A1 - Overvoltage protection circuit - Google Patents

Abstract

The invention relates to an overvoltage protection circuit (1) which has an electronic switch (7) which connects a supply voltage connection (2) and a load connection (3), the electronic switch (7) having a control connection which is connected to a first trigger circuit (9 ), wherein the first trigger circuit (9) comprises a transistor (10) whose control electrode is connected to a threshold arrangement (R1, D1) which turns on the transistor (10) when a voltage at the power supply terminal (2) is predetermined Value exceeds.
A consumer should be protected against overvoltage with a simple circuit.
For this purpose, a voltage-sensing terminal (12) is different from the supply voltage terminal (2) connected to a second trigger circuit (11), wherein the second trigger circuit (11) is connected to the first trigger circuit (9) and controls the transistor (10).

Description

The present invention relates to an overvoltage protection circuit having an electronic switch connecting a supply voltage terminal and a load terminal, the electronic switch having a control terminal connected to a first trigger circuit, the first trigger circuit comprising a transistor whose control electrode is provided with a threshold arrangement which turns on the transistor when a voltage at the supply voltage terminal exceeds a predetermined value.

Such an overvoltage protection circuit is for example off DE 41 10 495 A1 or DE 35 26 177 A1 known.

Such an overvoltage protection circuit is intended for use in a transportable system, in particular a vehicle. However, it can also be used in principle in other systems.

It is a common requirement for electronic circuits to withstand a certain amount of overvoltage on the power supply lines. This is especially true in automotive systems where the main power supply input to any particular vehicle electronics system must tolerate various overvoltage and transient voltage conditions, including load dump. Components within the electronic system that are downstream of the main power supply are then protected from the worst of the power supply conditions. Such components, when mounted remotely from the main electronics module, have additional line fault tolerance requirements because of their proximity to the vehicle wiring harness.

The object underlying the invention is to have a simple circuit that protects a consumer against overvoltage.

This object is achieved with an overvoltage protection circuit of the type mentioned above in that a voltage-sensing terminal is different from the supply voltage terminal connected to a second trigger circuit, wherein the second trigger circuit is connected to the first trigger circuit and controls the transistor.

In such an overvoltage protection circuit, it is possible to protect the load connected to the load terminal from an overvoltage occurring at the supply voltage terminal. Such an overvoltage may be caused for example by an overload or a disconnection from the battery and / or the alternator of the vehicle. Furthermore, the circuit is capable of protecting the load connected to the load terminal from an overvoltage appearing at a point downstream of the load terminal, provided that this voltage is detected by the voltage sensing terminal. The voltage-sensing terminal is capable of detecting a voltage other than the supply voltage supplied to the supply voltage terminal. However, the number of components that are additionally necessary is very limited.

Surge protection of mobile electronics is often needed in various sections of the electronic circuitry. Overload pulses have a very high energy and can destroy the power supply circuit and other circuits connected to the power supply. A high voltage switch is needed to protect the circuit from the high energy pulse.

A fault in the power supply circuit may destroy all the electronics powered by the power supply, and the same high voltage switching transistor may be used to protect the circuits powered by the power supply. This eliminates the need to integrate a separate power cut-off, reducing costs and power losses in an extra switch.

Different output supplies can be protected with the same high voltage switch that is needed anyway for high voltage pulse protection. All that is needed is a compact low-current and low-cost Zener diode, resistor and transistor for every power supply that needs to be protected.

In one embodiment of the invention, the first trigger circuit has a breakdown diode in series with a resistor connected to the control terminal of the transistor. The breakdown diode, such as a Zener diode, blocks current until a voltage applied to the Zener diode exceeds a threshold defined for each Zener diode. As soon as the voltage exceeds the threshold, the zener diode becomes conductive and, as a consequence, the transistor becomes conductive so that the electronic switch is actuated to be closed. The electronic switch can be formed for example by a transistor. The transistor can be a bi-polar Be transistor or he may be a field effect transistor.

In one embodiment, the second trigger circuit is connected to a point between the breakdown diode and the resistor. Accordingly, the second trigger circuit is used to turn off the electronic switch by again using the same parts already available in the first trigger circuit.

In one embodiment of the invention, the second trigger circuit comprises a second transistor between the first trigger circuit and a ground terminal, wherein a control terminal of the second transistor is connected to a second threshold arrangement which turns on the second transistor when a voltage at the voltage sensing terminal is a predetermined second one Value exceeds. The second threshold arrangement is in principle similar to the first threshold arrangement, with a difference that the threshold value of the second threshold arrangement is different from the threshold value of the first threshold arrangement. Therefore, the second trigger circuit turns off the electronic switch when a corresponding overvoltage value occurs at the voltage sensing terminal.

In one embodiment of the invention, the second transistor interrupts a connection between the voltage sensing terminal and the ground terminal as long as a voltage at the voltage sensing terminal is below the second threshold. The second transistor may be considered as a "normally closed" transistor which is opened only when the voltage at the voltage sense terminal exceeds the second value. In this case, the second transistor becomes conductive, activating the first transistor, which in turn turns off the electronic switch.

In one embodiment, the second transistor is of a complementary type to a type of the first transistor. For example, if the first transistor is a PNP transistor, then the second transistor is an NPN transistor.

In one embodiment of the invention, the second trigger circuit has a second breakdown diode in series with a second resistor. The function of the series connection of the second breakdown diode, for example Zener diode, and resistor is the same as in the first trigger circuit.

The invention also relates to an arrangement of an overvoltage protection circuit, a voltage reduction circuit connected to a load terminal of the overvoltage circuit, and a load connected to an output terminal of the voltage reduction circuit, the output terminal of the voltage reduction circuit being connected to a voltage sensing terminal.

In such an arrangement, an overvoltage caused by a defect of the voltage-reducing circuit can be detected and also turned off. If such a defect occurs, the normal supply voltage would be directed to the load, but only having the ability to withstand the lower voltage generated by the voltage reduction circuit. Such an overvoltage can now be avoided since the overvoltage is applied to the voltage-sensing terminal and to the second trigger circuit, which in turn will turn off the electronic switch.

• die einzige Fig. eine Überspannungsschutzschaltung zeigt.

An embodiment of the invention will now be described in more detail with reference to the drawing, in which:

• the only Fig. Shows an overvoltage protection circuit.

An overvoltage protection circuit 1 has a supply voltage connection 2 on. When such a surge protection circuit 1 is used in an automotive system, the supply voltage connection is normally connected to a battery of a vehicle and at the same time to a generator. Normally, the voltage applied to the supply voltage terminal is around 12V. However, during a load dump, the voltage can suddenly rise to 200V, which is dangerous for electronic components that are connected to the supply voltage terminal 2 are connected.

The circuit 1 has a consumer connection 3 on. A voltage reduction circuit 4 is with the consumer connection 3 connected. The voltage reduction circuit 4 may be in the form of a switched mode power supply (SMPS) which reduces the supply voltage from, for example, 12V to a lower voltage of 3.3V. An exit 5 the voltage reduction circuit 4 is with a consumer 6 connected. The consumer 6 must be protected against an overvoltage at the supply voltage connection 2 shows up. Furthermore, the load must be protected from a voltage that exceeds the above-mentioned 3.3V (plus a tolerance range) that could be generated when the voltage reduction circuit 4 becomes defective.

For this purpose, the circuit 1 an electronic switch 7 in the form of a PNP transistor. The emitter of the electronic switch 7 is with the supply voltage connection 2 connected. The collector of the switch 7 is with the consumer connection 3 connected. The base of the switch 7 is with a ground connection 8th about a resistance R1 connected.

Furthermore, the overvoltage protection circuit 1 a first trigger circuit 9 on. The first trigger circuit 9 has a transistor 10 on, which is also in the form of a PNP transistor. The emitter of the transistor 10 is with the supply voltage connection 2 connected. The collector of the transistor 10 is with the base of the electronic switch 7 connected. The base of the transistor 10 is with a series connection of a resistor R2 and a breakdown diode D1 , For example, a Zener diode, connected in turn to the ground terminal 8th connected is. The breakdown diode D1 has a breakdown voltage of 39V, which means that the first trigger circuit 9 becomes conductive when the voltage at the supply voltage terminal 2 exceeds a value of 40V. The voltage drop across the transistor 10 and at the resistance R2 is taken into account in this case.

When the first trigger circuit 9 becomes conductive, the current increased by the second resistor R2 flows, the voltage at the base of the first transistor 10 so that the first transistor 10 becomes conductive. The current through the first transistor 10 flows through the first resistor R1 , so that the voltage at the base of the electronic switch 7 increases. Accordingly, the electronic switch 7 closed and a connection between the supply voltage connection 2 and the consumer connection 3 is interrupted so that the voltage reduction circuit 4 and the consumer 6 are protected from an overvoltage at the supply voltage terminal 2 occurs.

A second trigger circuit 11 is provided, which with a voltage-sensing connection 12 connected is. The voltage-sensing connection 12 is at the output of the voltage reduction circuit 4 connected.

The second trigger circuit 11 points between the voltage-sensing connection 12 and the ground connection 8th a series connection of a second breakdown diode D2 , a third resistance R3 and a base-emitter path of a second transistor 13 on. The second breakdown diode D2 may also be a zener diode, but has a lower breakdown voltage of, for example, 3.3V.

The collector of the second transistor 13 is with a point 14 between the second resistor R2 and the first breakdown diode D1 connected.

If at the voltage-sensing connection 12 a voltage appears higher than the breakdown voltage of the second breakdown diode D2 (plus the voltage drop across the third resistor R3 and the voltage drop across the second transistor 13 ), becomes the second transistor 13 conductive. If the breakdown voltage is not reached, the second transistor is 13 not conductive.

If the second transistor 13 is conductive, it directs a current path through the second resistor R2 one, so the first transistor 10 also becomes conductive, passing a current through the first resistor R1 allows, as explained above, the voltage at the base of the electronic switch 7 raised to the switch 7 off.

Accordingly, the overvoltage protection circuit is not only able to protect the load from overvoltage at the power supply terminal 2 but also from an overvoltage caused by a malfunction of the voltage reduction circuit 4 is caused.

It is also possible to use third, fourth, etc. trigger circuits similar to the second trigger circuit 11 shown in the figure to use. Each of the other trigger circuits may have a different threshold voltage for the breakdown diode to the electronic circuit 7 if an overvoltage appears, switch off at the respective voltage-sensing connection which is the voltage-sensing connection 12 the second trigger circuit 11 equivalent.

Furthermore, the power supply connection 2 with a ground connection via a transient protective element 15 get connected. The overvoltage protection circuit may be used in an automotive system in which the consumer is, for example, a steering handwheel angle sensor.

The circuit shown has the advantage that the consumer 6 not only protected against overvoltages connected to the supply voltage connection 2 but also against surges caused by the voltage reduction circuit 4 be generated.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 4110495 A1 [0002]
• DE 3526177 A1 [0002]

Claims (8)

Overvoltage protection circuit (1) comprising an electronic switch (7) connecting a supply voltage terminal (2) and a load terminal (3), the electronic switch (7) having a control terminal connected to a first trigger circuit (9), wherein the first trigger circuit (9) comprises a transistor (10) whose control electrode with a threshold array (R1, D1) is connected, which turns on the transistor (10) when a voltage at the supply voltage terminal (2) exceeds a predetermined value, characterized characterized in that a voltage sensing terminal (12) different from the supply voltage terminal (2) is connected to a second trigger circuit (11), the second trigger circuit (11) being connected to the first trigger circuit (9) and controlling the transistor (10). Switching to Claim 1 characterized in that the first trigger circuit (9) comprises a breakdown diode (D1) in series with a resistor (R2) connected to the control terminal of the transistor (10). Switching to Claim 1 or 2 , characterized in that the second trigger circuit (11) is connected to a point (14) between the breakdown diode (D1) and the resistor (R2). Switching to one of the Claims 1 to 3 characterized in that the second trigger circuit comprises a second transistor (13) between the first trigger circuit (9) and a ground terminal (8), a control terminal of the second transistor (3) being connected to a second threshold arrangement (D2, R3), which turns on the second transistor (13) when a voltage at the voltage sensing terminal (12) exceeds a predetermined second value. Switching to Claim 4 characterized in that the second transistor (13) breaks a connection between the voltage sensing terminal (12) and the ground terminal (8) as long as a voltage at the voltage sensing terminal (12) is below the second value. Switching to Claim 4 or 5 characterized in that the second transistor (13) is of a type complementary to a type of the first transistor (10). Switching to one of the Claims 4 to 6 , characterized in that the second trigger circuit (11) comprises a second breakdown diode (D2) in series with a third resistor (R3). Arrangement of an overvoltage protection circuit (1), a voltage reduction circuit (4) connected to a load terminal (3) of the overvoltage protection circuit (1), and a load (6) connected to an output terminal of the voltage reduction circuit (4), characterized in that the output terminal of the voltage reduction circuit (4) is connected to the voltage-sensing terminal (12).

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