DE9311361U1 - Reverse polarity protection circuit - Google Patents

Description

93G 33970E

Siemens AG

Reverse polarity protection circuit
5

The present invention relates to a reverse polarity protection circuit for an electronic circuit, in particular a digital output circuit, which can be connected to two supply potentials via two supply connections.

Input and output circuits are generally used in programmable logic controllers and machine tools. As a rule, a large number of connections for input and output signals, typically 8, 16, or 32, are combined into one module. Furthermore, such modules usually have two connections for connecting the power supply, e.g. ground and + 24 V.

With such assemblies, to which supply lines are connected from the outside, it can happen that lines are connected incorrectly, i.e. not connected to the corresponding connections. Particularly critical is the case where the supply lines are connected incorrectly, for example, that the ground line is connected to the 24-volt connection and vice versa, the 24-volt line to the ground connection. Such incorrect wiring can destroy the entire assembly if protective measures are not taken.

0 To protect the module, it is known to arrange reverse polarity protection diodes between the supply connections and the electronic circuit. These diodes prevent thermal destruction of the module in the event of incorrect wiring, but due to the relatively high currents

(e.g. 32 channels of 0.5 A each) however, undesirably high power losses occur in the diode and also on the module itself during normal operation. The use of

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Diodes with low forward voltage do not provide sufficient relief.

In practice, the supply connections are therefore connected using a diode, which is operated in reverse direction when the supply lines are connected correctly, so that, conversely, if the supply connections are swapped, a short-circuit current path is created. Due to the short circuit, a very high current then flows, which triggers a fuse that is connected between the electronic circuit and one of the supply connections. However, this solution is still not satisfactory. The disadvantages of the fuse include:

- inaccurate response depending on the ambient temperature,

- Aging of fuse and diode,

- thermal race between the fuse and the diode carrying the short-circuit current,

- Costs of fuse and/or diode are not negligible,

- the power loss at the fuse is not negligible.

In addition, to avoid contact resistance, the fuse is usually soldered in firmly, so that if the fuse blows due to a faulty connection, the assembly must be sent in for repair.

The object of the present invention is therefore to create a reverse polarity protection circuit which has only a low power loss in normal operation, responds reliably in the event of an incorrect connection and is nevertheless cost-effective.

5 The task is solved by

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- that the reverse polarity protection circuit consists of an electronic main switching element with a control input which is connected to a control circuit,

- that the main switching element between the electronic

circuit and one of the supply connections and when activated, the electronic circuit is connected to the supply connection with almost the same potential and

- that the control circuit is connected to the supply terminals and only controls the control input if the signed difference of the supply potentials connected to the supply terminals is greater than a minimum potential difference.

A too early response of the main switching element can be avoided simply by connecting the control input of the main switching element to the one supply connection via an additional electronic switching element that has a control input, whereby the additional switching element connects the control input of the main switching element to the one supply connection when not activated and releases the control input of the main switching element when activated.

The minimum potential difference can be easily determined by connecting the control input of the additional switching element to the supply terminals via a (suitably dimensioned) voltage divider.

0 A particularly simple design of the control circuit is obtained if the control circuit has an oscillator with a downstream charge pump and the charge pump is connected to the control input of the main switching element.

Further advantages and details emerge from the following description of an embodiment,

93G 33970E

based on the drawings and in conjunction with the other subclaims.

FIG 1 is a schematic diagram of a digital output circuit and

FIG 2 is a block diagram of the control circuit.

According to FIG 1, the digital output circuit has a plurality, e.g. 32, of drivers 1, to which signals to be output are fed via lines 2. Depending on the signals to be output, the drivers 1 output a signal of 24 volts via lines 3, which can have a current of typically 0.5 A to 2 A per line 3. The signals output via lines 3 are fed to actuators (not shown) via signal connections 4.

The internal structure of the drivers 1 is generally known and is not the subject of the present invention.

Depending on the number of drivers 1 controlled and the current required per driver 1, the current consumption of the circuit can be up to 16 A. In order not to have to supply this high current to the drivers internally via a power distribution system (not shown for the sake of clarity), the drivers 1 are supplied with power via two supply connections 5, 6. Connection 5 is the ground connection, and the supply voltage Uq of e.g. + 24 volts is connected to connection 6.

As can be seen from FIG 1, a protective circuit 7 is arranged between the drivers 1 and the connection 6. The protective circuit 7 consists of a self-blocking MOSFET 8, which is controlled by a control circuit 9. The MOSFET 8 consists of the actual MOSFET 8' and the substrate diode 8". Structure and mode of operation of the

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Control circuit 9 is explained in more detail below with reference to FIG 2.

For the sake of simplicity, the case in which the supply connections 5, 6 are wired incorrectly is explained first, i.e. the supply connection 6 is connected to ground and the supply connection 5 to the potential Uq. In this case, the MOSFET 8 is blocked, whereby the substrate diode 8" is also polarized in the reverse direction. Due to the Zener diode 10, only a very low (negative) voltage is applied to the oscillator 11, so that the oscillator 11 is not destroyed. At the same time, the current through the Zener diode 10 is limited by the resistor 12, so that the Zener diode 10 is not destroyed either. Because the MOSFET 8 is blocked, the drivers 1 (see FIG. 1) are not loaded by impermissible voltages and are thus protected from destruction.

If, however, the supply connection 5 is properly connected to ground M and the supply connection 6 is properly connected to the supply voltage Uq, the protection circuit 7 reacts as follows:

The Zener diode 10 applies the Zener voltage Uz to the oscillator 11 with charge pump 13 and the resistors 14, which form a voltage divider. This causes the oscillator 11 to operate properly, i.e. it alternately connects the connecting line 15 to the potential Uq and the potential Uq - Uz. This causes the capacitor 16 to be continuously recharged via the diodes 17, 18.

Furthermore, the normally-on N-channel MOSFET 19 is blocked due to the dimensioning of the resistors 14. Due to the interaction of these two measures, namely the blocking of the normally-on MOSFET 19 and the recharging of the capacitor 16, the gate of the MOSFET 8' becomes positive relative to the source. The MOSFET 8' is thereby turned on.

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The MOSFET 8' is preferably an N-channel power MOSFET, which can, for example, conduct up to 20 A with a voltage drop of only 10 to 20 mV. In principle, however, solutions using a P-channel FET are also feasible. The low voltage drop in the MOSFET 8' can be achieved by appropriately dimensioning the chip area of the MOSFET 8'. This results in a maximum power loss of only 0.4 watts in the MOSFET 8 ¹ .

If the supply voltage Uq falls below a minimum potential difference U _m i _{n ,} the MOSFET 19 becomes conductive. This puts the gate of the MOSFET 8' at the same potential as the source, so that the MOSFET 8' is blocked. In this case, current flows through the substrate diode 8", where it causes a voltage drop of approximately IV. The minimum potential difference U _m -j_ _n is determined by the Zener voltage U^ and the resistors 14. It is typically placed in the range of less than half the supply voltage Uq. A typical value for the minimum potential difference U _m j_ _n is 0, e.g. 10 volts, if the normal supply voltage Uq is 24 volts.

At this voltage value U _m -j_ _n, the capacitor 16 is still charged via the oscillator 11. This ensures that the MOSFET 8 is switched through in a very small voltage range. This voltage range can be reduced to zero if the control circuit 9 has a switching hysteresis, e.g. is designed as a Schmitt trigger.

The reverse polarity protection circuit 7 described above can of course be constructed either discretely or integrated into an integrated circuit. The circuit is used particularly advantageously in input and/or output modules for programmable logic controllers or machine tool controllers.

Claims (10)

93G 33970E Protection claims 1. Reverse polarity protection circuit for an electronic circuit (1), in particular for a digital output circuit (1), which can be connected to two supply potentials (Uq/M) via two supply connections (5,6), - wherein the reverse polarity protection circuit (7) consists of an electronic main switching element (8 ¹ ) with a control input which is connected to a control circuit (9), - wherein the main switching element (8 ¹ ) is arranged between the electronic circuit (1) and one (6) of the supply terminals (5,6) and when activated, the electronic circuit (1) is connected to the supply terminal (6) connects almost equal potential and - wherein the control circuit (9) is connected to the supply terminals (5,6) and only controls the control input if the signed difference of the supply potentials (Uq,M) connected to the supply terminals (6,5) is greater than a minimum potential difference (U _m i _n ). 2. Reverse polarity protection circuit according to claim 1, characterized in that the main switching element (8 ¹ ) is designed as a self-blocking MOSFET. 3. Reverse polarity protection circuit according to claim 1 or 2, characterized in that the control input of the main switching element (8 ¹ ) is connected via an electrical 3Ö electronic additional switching element (19) with a control input which is connected to a supply connection (6), wherein the additional switching element (19) connects the control input of the main switching element (8 ¹ ) to the one supply connection (6) when not activated and releases the control input of the main switching element (8 ¹ ) when activated. 93G 3397OE 4. Reverse polarity protection circuit according to claim 3, characterized in that the additional switching element (19) is designed as a self-conducting MOSFET. 5. Reverse polarity protection circuit according to claim 3 or 4, characterized in that the control input of the additional switching element (19) is connected to the supply connections (5, 6) via a voltage divider (12, 14). 6. Reverse polarity protection circuit according to one of the above claims, characterized in that the control circuit (9) has an oscillator (11) with a downstream charge pump (13) and that the charge pump (13) is connected to the control input of the main switching element (8'). 7. Reverse polarity protection circuit according to one of the above claims, characterized in that the control circuit (9) is designed as a control circuit with switching hysteresis. 8. Reverse polarity protection circuit according to one of the above claims, characterized in that at least the electronic main switching element (8) and the control circuit (9) are integrated into an integrated circuit. 9. Input or output circuit, characterized in that it has a protective circuit (7) according to one of the above claims. 10. Input or output circuit according to claim 9, characterized in that it is used in an industrial automation system, e.g. a storage 93G 3397OE programmable control or a machine tool control.