DE4110495A1 - Excess voltage protection circuit esp. load-dump voltage e.g. for vehicle battery - incorporates non-linear, controllable electrical resistor through which user current flows, and Zener diode regulates user voltage - Google Patents

Abstract

The circuit arrangement has a non-linear, controllable electrical resistor (T1) via which the user appts. (2) is connected to the voltage source (3), and a regulating circuit (1'), which by control of the non-linear resistor brings about a rough regulation of the user voltage (Uv), and which at the onset of excess voltage, i.e. as soon as the output voltage (UE) of the generator-battery set exceeds a predetermined limit value, stops the current flow to the user appts. The non-linear resistor (T1) comprises the collector-emitter extent of a power transistor. USE - For protection of user appts. against excess DC voltage e.g. for vehicle battery.

Description

The invention relates to a circuit arrangement for Protection of consumers from surges, especially from so-called load-dump overvoltages when used a generator-battery unit as a DC voltage source arise with electronic circuits for limitation of surges.

Electronic circuits and other electrical Consumers that supply power to a battery and are known to have to be connected to a generator the so-called load-dump surges are protected. Vehicles with internal combustion engines are usually with one such a generator-battery unit, namely with one Alternator and a starter battery, equipped. Such Load-dump surges occur especially in the case of sudden Interruption of the connection to the battery and currently high consumer current. Voltage peaks occur up to approx. 100 volts, which only after approx. 200 milliseconds tolerable values have dropped. To protect Consumers, especially those who are relatively sensitive electronic circuits, such as electronic Anti-lock regulators, voltage regulators and the like Today so-called load-dump diodes, namely heavy-duty Zener diodes, or - Varistors used. These components are located at the entrance to the Consumers and limit the load-dump voltage to approx. 40  Volt. As short-term power losses up to approx. 2000 watts Such components can be relatively expensive. In addition, there is the disadvantage that they are only destroyed a few times with the full-load load dump voltage can be applied.

Furthermore, the sensitive electronic consumers usually equipped with a reverse polarity protection diode, which not only for the maximum consumer current, but must also be designed for the load-dump current.

Finally, it is usually still required at the entrance of electronic circuits for damping Surges and to compensate for voltage drops to provide an electrolytic capacitor. This capacitor must now also for the relatively high voltage of about 40 volts designed for the load dump voltage by the load dump diode is reduced, although the operating voltage at the input of the consumer is only about 12 to 14 volts. The above information relates to today's Motor vehicles with 12 volt starter batteries.

Protection circuits of this type are relatively expensive because of the described components for the mentioned high Power losses and can be designed for high voltages have to.

The invention is therefore based on the object overcome the disadvantages and a Develop circuitry with little effort  is to be manufactured and which provides effective protection against provides load-dump surges.

It has been shown that this task with a Circuit arrangement is to be solved, which essentially consists of a non-linear controllable electrical resistance, via which the consumer is connected to the voltage source, and consists of a control circuit that by control of the non-linear resistor a pre-regulation or Coarse regulation of the consumer voltage and the Occurrence of overvoltages, d. H. as soon as the Output voltage of the generator-battery unit one exceeds the predetermined limit, the current flow to the Consumer interrupts.

According to the invention, the voltage of Generator battery unit pre-regulated to the Longitudinal voltage of the smoothing capacitor to one to set comparatively low value, and to others when a load dump overvoltage occurs Current path interrupted. In contrast to the ones described known measures cause the surges in the Protection circuit only low power losses. The Manufacturing expenditure for the protective circuit is thereby low. In addition, repeated occurrences of load dump surges do not destroy the Lead protective circuit. The entire protection circuit, including the protection diode, can even be integrated Circuit.  

According to an advantageous embodiment of the invention as a non-linear resistor of the circuit according to the invention the collector-emitter path of a power transistor, wherein the control circuit is a circuit branch for Control of this transistor has a zener diode to generate a reference voltage for the pre-regulation of the Consumer voltage includes. Power transistor and Zener diodes are advantageously connected such that the Breakdown voltage of the Zener diode, reduced by the voltage over the base-emitter path of the power transistor that Output voltage of this pre-regulation stage is determined.

According to a further embodiment of the invention the control circuit one with a circuit branch Control of the non-linear resistor connected Voltage divider with a second Zener diode, the Breakdown voltage (Zener voltage) above the operating voltage the voltage source and which becomes conductive when the Overvoltage exceeds the specified limit and the thereby the current flow through the non-linear resistor locks.

It's convenient and affordable, not just that Protection circuit and the reverse polarity protection diode, but also one integrated circuit which is the pre-regulated Output voltage of the protective circuit or the Consumer voltage to that required for the electronics regulates exact value in a single integrated Unite circuit. For other consumers, that's enough the limitation of the  DC voltage source.

Other features, advantages and possible uses of the Invention proceed from the following description of a Embodiment with reference to the accompanying drawings which, in a simplified representation, the most important components of a circuit arrangement according to the Invention reproduces.

In the exemplary embodiment shown, it is a protective circuit 1 for an electronic circuit 2 , namely for a voltage regulator, which is used to generate a constant DC voltage U _k . At the input of this voltage regulator 2 is the pre-regulated output voltage of the circuit arrangement 1 or the consumer voltage U _V. The reference number 3 symbolizes a generator-battery unit of a motor vehicle, the z. B. consists of an alternator and a starter battery with the nominal voltage 12 volts. As is known, the output voltage of such a unit or the input voltage U _{E of} the protective circuit 1 can already rise to a value of approximately 18 volts during normal operation, which is reduced here by the pre-regulation to a consumer voltage U _V of approximately 10 volts. The voltage regulator 2 z. B. the supply voltage of U _k = 5 volts required for certain types of electronic circuits.

In the exemplary embodiment shown here, the protective circuit 1 according to the invention is equipped with a power transistor T 1 , which serves as a non-linear, controllable electrical resistor. A control circuit 1 'for controlling this power transistor T 1 contains a circuit branch which is composed essentially of an ohmic resistor R 1 and a Zener diode Z 1 . The breakdown voltage or Zener voltage U _{Z1 of} the Zener diode Z 1 , reduced by the voltage across the base-emitter path BE of the power transistor T 1 , determine the level of the consumer voltage U _V. The base current for opening the power transistor T 1 consequently flows via the resistor R 1 to the base B of the transistor LT. Since it is only a precontrol or rough control, it is sufficient to select a Zener diode Z 1 , the voltage of which is significantly higher than the required consumer voltage U _V. Such Zener diodes, for the voltage of which a relatively large tolerance is permissible and which carry only very little current, are relatively cheap.

A transistor T 2 , which is parallel to the Zener diode Z 1 , is normally blocked, ie as long as no load-dump overvoltages occur, because the breakdown voltage of a second Zener diode Z 2 is above the maximum output voltage UE of the generator-battery unit 3 . The breakdown voltage U _{Z2 of} this second Zener diode Z 2 is preferably approximately 25 volts.

If the input voltage U _E now exceeds a limit value which is above the breakdown voltage U _{Z2 of} the Zener diode Z 2 , plus the forward voltage of the diode D and the base-emitter path of the transistor T 2 , the transistor T 2 becomes conductive. This leads to a reduction in the drive base current of the power transistor T 1 and finally to a complete blocking of this transistor. If the input voltage U _E is clearly above the limit value, which is given above all by the breakdown voltage of the Zener diode U _Z2 , the consumer voltage U _V becomes zero after the capacitor C is discharged. The transistor T 1 consequently needs only a relatively low power loss, which is given by the maximum consumer current through this transistor T 1 and the upper limit value of the nominal input voltage U _E. The blocked transistor T 1 also has a maximum of the full load-dump overvoltage of approximately 100 volts.

A resistor R 2 , which is connected in series with the Zener diode Z 2 , limits the drive current of the transistor T 2 , when a load-dump overvoltage occurs, to a value which is just sufficient for the total current flowing through the resistor R 1 to conduct over the collector-emitter path of the transistor T 2 . R3 also keeps the transistor T 2 blocked as long as the second Zener diode Z 2 is non-conductive.

A diode D serves to protect against polarity reversal. Since the maximum current flowing through this diode D is only slightly above the highest nominal current, a low-power diode is sufficient, which can be included in the integrated circuit when the circuit 1 is integrated.

The dash-dotted frame indicates that both the circuit arrangement 1 according to the invention and the voltage regulator 2 can be incorporated individually or together in a single integrated circuit. Only the capacitor C, if a high capacity electrolytic capacitor is required, will have to be added as a discrete device. However, the nominal voltage of this capacitor C is limited to the consumer voltage U _V , because when a load-dump overvoltage occurs, the current flow through the transistor T 1 is blocked in the manner described.

Claims (9)

1. Circuit arrangement for protecting consumers from overvoltages, in particular from so-called load-dump overvoltages, which arise when using a generator-battery unit as a DC voltage source, with electronic circuits for limiting the overvoltages, characterized in that they essentially consist of a non-linear one , controllable electrical resistance (T 1 ), via which the consumer ( 2 ) is connected to the voltage source ( 3 ), and consists of a control circuit ( 1 '), which by controlling the non-linear resistor, a precontrol or rough control of the consumer voltage (U _V ) and which interrupts the current flow to the consumer ( 2 ) when overvoltages occur, ie as soon as the output voltage (U _E ) of the generator-battery unit exceeds a predetermined limit value. 2. Circuit arrangement according to claim 1, characterized in that the collector-emitter path of a power transistor is used as a non-linear resistor (T 1 ) and that the control circuit ( 1 ') has a circuit branch (R 1 , Z 1 ) for controlling the power transistor (T 1 ) has a Zener diode (Z 1 ) for generating a reference voltage for regulating the consumer voltage (U _V ). 3. Circuit arrangement according to claim 2, characterized in that the power transistor (T 1 ) and the Zener diode (Z 1 ) are switched such that the Zener voltage (breakdown voltage) of the Zener diode (Z 1 ), reduced by the voltage across the base-emitter path of the power transistor (T 1 ), determine the output voltage of this pre-regulation stage or the consumer voltage (U _V ). 4. Circuit arrangement according to one or more of claims 1 to 3, characterized in that the control circuit ( 1 ') one with the circuit branch (R 1 , Z 1 ) for controlling the non-linear resistor (T 1 ) connected voltage divider (Z 2 , R 2 , R 3 ) with a second Zener diode (Z 2 ), whose Zener voltage (breakdown voltage) is above the operating voltage of the voltage source ( 3 ) or the generator-battery unit ( 3 ) and which becomes conductive when the overvoltage meets the specified Limit value exceeds, and thereby blocks the flow of current through the non-linear resistor (T 1 ). 5. A circuit arrangement according to one or more of claims 1 to 4, characterized in that the non-linear resistance (T 1) and the control circuit (1 ') are combined to form an integrated circuit (1). 6. Circuit arrangement according to claim 5, characterized in that the integrated circuit ( 1 ) additionally contains a polarity reversal protection diode (D). 7. Circuit arrangement according to one or more of claims 1 to 6, characterized in that it is provided for connecting a consumer ( 2 ), which is a voltage regulator constructed in the form of an integrated circuit. 8. Circuit arrangement according to one or more of claims 1 to 7, characterized in that this ( 1 ) together with a voltage regulator ( 2 ) is housed in a common IC housing. 9. Use of the circuit arrangement according to one or several of claims 1 to 8 for the protection of the Alternator and a starter battery Motor vehicle connected consumers.