DE4439967A1 - Overvoltage protection for automobile electronic appts. - Google Patents

Abstract

The circuit has a low-ohmic load (VB) switched in via a relay or a power semiconductor switch (1) when a voltage above a given overvoltage threshold (Uref) is detected for a timed duration or the duration of the overvoltage.Pref. an RC timing stage, or a monostable multivibrator is used to maintain the switched load in operation for a timed duration which is longer than the overvoltage duration, only when the initial overvoltage exceeds a min. duration.

Description

The invention relates to a circuit arrangement for Protection of electrical circuits circuit components, sensitive consumers etc. from high-energy surge mentions.

There are numerous, very different types of measures to be taken Protection of electronic circuits against overvoltages known. Such overvoltages can cause malfunctions Overloading and even destroying the electronic scarf lead arrangements or the connected consumers. The amount of overvoltages that can occur is up to you very different depending on the application.

Electronic circuits in motor vehicles used for chip Power supply to a generator-battery unit are connected, must be known before the so-called. load- protected against surge voltages. Such load dump Surges occur especially when there is a sudden interruption the connection to the battery, e.g. B. with a loose con clock, and a currently high charging current. The load dump Overvoltages can cause voltage peaks of up to approx. 100 V. take that after approx. 200 msec to harmless values have sunk. It is therefore high-energy Surges. To protect electronic circuits and of sensitive consumers from these surges  are so-called load-dump diodes these days heavy-duty suppressor diodes, zener diodes or varistors, used the overvoltages depending on the circuit design on z. B. limit 40 V and the short-term power losses from Z. B. can record 2000 W. Such components are relatively expensive and some also have a limited lifespan.

The invention is therefore based on the object of a scarf to develop the arrangement of the type mentioned at the outset effective protection against high-energy surges offers that works reliably and with low costs is to be produced.

It has been shown that this task by the attached claim 1 circuit arrangement can be solved. According to the invention, when a Overvoltage that is above a predetermined limit, an existing, relatively powerful or low-resistance consumer for a specified period of time or switched on for the duration of the overvoltage. To the Switching on the consumer is expediently on already existing circuit breaker, namely a relay, a power transistor or the like.

Of course, a consumer is chosen at which the brief switch-on to dampen the overvoltage for the Function is irrelevant or at least not a malfunction leads. For example, the circuit arrangement belongs to protect is to a motor vehicle control system like an anti-lock braking system (ABS), Traction control system or the like. That with a Hydraulic pump is equipped, it lends itself to this  Switch on the pump briefly when the overvoltage occurs switch. Other low-resistance, high-performance consumers of the type in question here are, for example, heating elements elements, lamps or other electric motors (e.g. Wiper motors) of the vehicle.

The brief switching on of these consumers is also therefore irrelevant, because the high-energy surges rarely occur.

According to an embodiment of the invention is a There is a timing element that occurs when an overvoltage occurs the consumer for a given, over the duration of Turns on the overvoltage period. Thereby you can switch the on and off too often Prevent consumers. It is also possible with the help of a Delay element the response of the timing element to very to prevent short surges.

Some further advantageous embodiments of the invention Application and possible uses are in the subclaims called.

Further details of the invention follow from the following Be description of exemplary embodiments with reference to the accompanying Illustrations.

They show a schematic simplification

Fig. 1 shows the basic structure of a circuit arrangement according to the invention,

Fig. 2 shows an example of a circuit arrangement according to Fig. 1 and

Fig. 3 shows another embodiment of a circuit arrangement according to the invention.

In principle, the circuit arrangement according to the invention shown in FIG. 1 consists only of a circuit breaker I, which is closed when an overvoltage occurs in the supply network, which is symbolized here by the battery voltage + U _B. Switch 1 is used to switch on one or more consumers VB. A circuit breaker which is already present is expediently used to dampen the overvoltage.

The circuit breaker 1 is controlled and closed via a signal 51 , which supplies a logic circuit 2 . This logic circuit has two inputs a1 and a2, of which the input a1 is used for the normal switching on of the consumer VB with the help of the switch 1 , while at the input a2 only when there is overvoltage there is a signal that closes the switch 1 and thus the consumer VB switches on.

An input signal i _a, the voltage at the occurrence of a surge on the supply network (+ U _B) via the link circuit 2 controls the switches 1, for example by means of a low-power Zener diode Z1 obtained, which only permits a flow of current i _a through this zener diode, if - due to the occurrence of the overvoltage - the breakdown voltage U _{one of} this Zener diode Z1 is exceeded.

In Fig. 1 it is indicated that such a signal triggered by an overvoltage signal at the input a2 of the combination circuit 2 can in principle also be obtained with the aid of a differential amplifier 3 , which provides an output signal b as soon as the one at the input a of this amplifier 3 Supply voltage + U _B exceeds a predetermined limit. This limit value is set with the aid of a comparison or reference voltage U _Ref arranged symmetrically at the second input of the amplifier 3 .

There are of course other possibilities known to the person skilled in the art to trigger an input signal and thereby close switch 1 as soon as the supply voltage + U _B exceeds a predetermined limit value.

As a consumer VB, which "normally" via input a1, for rendering an energy-rich overvoltage harmless input a2 are basically all relatively low-resistance consumers. In one Motor vehicles come as consumers among other things various auxiliary engines, d. H. Pump motors, Wiper motors etc., lamps and heating elements in question.

As illustrated in FIG. 2, a semiconductor relay, a transistor 1 'or another semiconductor element is particularly suitable for switching on the consumer. The use of a mechanical relay, a contactor or the like would also be conceivable. In normal operation, the transistor 1 'is controlled via the terminal a1' and the transistors T1, T2, when an overvoltage occurs in the supply network + U _B via a terminal a2 ', a Zener diode Z2, an ohmic resistor R1 and also via the transis gates T1, T2.

In Fig. 2 U _H symbolizes an auxiliary voltage that increases the potential at the gate of this transistor 1 'when the consumer VB is switched on so that the internal resistance across the drain-source path of the transistor 1 ' is minimal. A Zenderdiode Z3 limits the allowable voltage drop at the gate-source path of the transistor 1 'to the permissible maximum value.

The Zener diode Z2 determines the voltage limit value, which leads to the switching on of the consumer VB when an overvoltage occurs on the supply source + U _B. If the overvoltage on the supply source exceeds the limit value, the Zener diode Z2 becomes permeable and increases the potential at the terminal a1 'so far that the transistor 1 is turned on via the transistors T1 and T2 and thus the consumer VB is switched on.

In FIG. 2, a capacitor C1 is connected in parallel to the voltage divider R1, R2, via which current flows when an overvoltage above the predetermined limit occurs. The connecting line shown in dashed lines symbolizes that the capacitor C1 is only present in special cases. This capacitor C1 or the time constant dependent on the capacitance of this capacitor and the ohmic resistors R1, R2 influences the duty cycle of the consumer VB when short-term surge peaks occur. Due to the integrating effect of this RC element, a constant switching on and off of the consumer is prevented when a sequence of short overvoltage signals occurs.

Finally, a further Zener diode Z4 is shown in FIG. 2, which, if necessary, absorbs the remaining energy which is not completely used up by switching on the consumer VB. The function of the Zener diode Z4 is comparable to that of a conventional load-dump diode, but now, as a result of the circuit arrangement according to the invention, a low-power and therefore inexpensive component is sufficient to absorb this residual energy. The Zener diode Z4 works mainly at the moment of switching on. Instead of the Zener diode, of course, another suppressor diode or a varistor can also be used.

According to FIG. 3, a circuit breaker or Leistungstransi is stor 1 '', which in turn is used to switch the consumer VB, controlled by a differential amplifier 4, a monostable multivibrator 6 preceded by a delay element 5, an OR gate 7 and a driver 8. The monostable multivibrator 6 serves as a timer and extends and defines the switch-on time of the consumer VB after an overvoltage switch-on. A charge pump 9 takes over the function of the auxiliary voltage source U _H according to FIG. 2 in a known manner.

The differential amplifier 4 is controlled via a voltage divider R3, R4. It compares the overvoltage with a reference voltage U _Ref , as has already been described with reference to FIG. 1.

A signal line 10 is connected in parallel with the timing element 6 with the upstream delay element 5 . This has the result that when an overvoltage occurs, which leads to an output signal at the differential amplifier 4 , the switch 1 '' is activated via the signal line 10 and via the OR gate 7 and thus the consumer VB is switched on. In addition, the delay element 5 when the overvoltage for a minimum period of z. B. 100 µsec, the monostable multivibrator 6 switched. The output signal of the multivibrator 6 has a duration of z. B. 200 msec, which means that if the overvoltages persist longer than 100 µsec, the consumer remains switched on for this period. This prevents frequent switching on and off of the consumer in the event of overvoltages with voltage dips. Very short overvoltages, ie under e.g. B. 100 microseconds and thus under the response time of the delay element 5 , also reach the consumer and are damped; however, as a rule, they lead to a reaction that is barely detectable.

A variant of the circuit according to FIG. 3, not shown, consists in that the parallel signal line 10 is dispensed with. In this case, the suppressor diode provided for low-energy overvoltages, Zener diode Z4 'or the like must absorb the energy occurring until the timer 5 or the multivibrator 6 responds.

Commercial diodes of this type are able to do this.

According to the invention is thus in a very simple manner and with protection from high-energy surge achieved. The effort is very low because about already existing circuit breakers Consumers can be used to absorb energy and because the consumer has a very simple, on the  Overvoltage responsive control circuit switched on can be.

Claims (11)

1. Circuit arrangement for the protection of electronic circuits, circuit components, sensitive consumers etc. from high-energy overvoltages, characterized in that when an overvoltage occurs which is above a predetermined limit value (U _Ref ), an already existing, powerful or low-impedance consumer ( VB) for a predetermined period of time or for the duration of the overvoltage. 2. Circuit arrangement according to claim 1, characterized in that the consumer (VB) by activation of an already existing circuit breaker ( 1 , 1 ', 1 ''), such as a relay, a power transistor or the like, is switched on. 3. Circuit arrangement according to claim 1 or 2, characterized characterized in that this is a timing element (R1, C1, 6) contains that when an overvoltage occurs Consumer (VB) for a given, over the duration the overvoltage period turns on. 4. Circuit arrangement according to claim 3, characterized in that the timing element in the form of an RC element (R1, C1) or a monostable multivibrator ( 6 ) is realized. 5. Circuit arrangement according to claim 3 or 4, characterized in that the timer ( 6 ) is only switched on when the occurrence of the overvoltage exceeds a predetermined minimum duration. 6. Circuit arrangement according to claim 5, characterized in that the timing element ( 6 ) is preceded by a delay element ( 5 ) which only emits a signal when the overvoltage exceeds a predetermined minimum duration. 7. Circuit arrangement according to claim 5 or 6, characterized in that parallel to the switching on of the consumer (VB) via the delay element ( 5 ) and the timing element ( 6 ) a signal line ( 10 ) is provided, via which the consumer (VB) directly is controlled for the duration of the overvoltage. 8. Circuit arrangement according to one or more of the Claims 1 to 7, characterized in that additionally a circuit (Z4, Z4 ') to protect against low-energy overvoltage or before a residual energy, which is switched on for surge protection Consumer (VB) does not record, is provided. 9. Circuit arrangement according to claim 8, characterized characterized that to protect against low energy Overvoltage a Zener diode (Z4, Z4 '), a varistor or the like. is provided. 10. Application of a circuit arrangement according to one or several of claims 1 to 9 to protect a  electronic circuit and / or a sensitive Consumer of a motor vehicle, thereby characterized in that the protection circuit when occurring of the overvoltages (on the vehicle electrical system) one or more high-performance consumers (VB), such as electric motors, Heating elements, lamps or the like. 11. Application of a circuit arrangement according to one or several of claims 1 to 10 to protect the electronic circuit of a motor vehicle Control system, which is an electric motor driven Contains hydraulic pump, characterized in that the Protection circuit when the overvoltage occurs Drive motor of the hydraulic pump as a consumer (VB) switches on.