DE3934421C1 - Protective circuit for circuitry with light indicator in motor vehicle - has transistor breaking current flow in dependence on information voltage from resistor measuring current - Google Patents

Abstract

A resistor (2) in series with the transmitter emitter (4), measures the current. A reference voltage (3) to the base causes the transistor to switch when the current exceeds a set level. A further transistor (16) completes the multivibrator circuit, its emitter-collector path being in parallel with the reference source (3) and having a divider (14,15) at its base. The resistances are such that, for bringing into operation the first transistor (4) regulation zone, the further transistor (16) conducts. Via the second transistor, the voltage from the common node of the reference and the measuring resistors is applied to the base of the first (4). USE - Protecting, e.g. LEDs, a car display against current overload.

Description

The invention relates to a protective circuit for a Circuit arrangement with a light-emitting element, such as Light-emitting diode, in a motor vehicle against current overload, wherein the light indicator element by means of a control circuit is adjustable to several intensity lighting levels and being a Transistor with its collector emitter range with the light indicator element is connected in series, with a flip-flop circuit that the transistor at Control insert switches from a defined conductive state to a blocked state.

The general requirement for motor vehicles is that cables coming out of electronic control plates must be short-circuit proof. This also applies to such lines that with indicator lights in Dashboard are connected. As display elements are in usually light emitting diodes, i.e. LED displays and incandescent lamps, as Single display elements or as multi-digit Symbol display elements used. The display elements current flowing through can be changed via stepless controllers or step controllers, such that the luminous intensity of the luminous display element be adapted to the outside light conditions can. This is how the intensity regulator works during the day high set that the light indicator element the highest Has luminous intensity. In contrast, during the night the intensity regulator is reduced, d. H. then only a lower current flows through the Illuminated display element, the illuminated display element still has a sufficient light intensity to the To clearly recognize the operating state of the indicator element can.  

An example is the LED display for an electronic one Air conditioning and heating control unit for Motor vehicles called, their function or at which too several functions that it can control in detail, with such LED displays in the dashboard.  

A protective circuit of the type described in one Dimmer circuit is known from US 47 39 226. In row with a lamp that can be connected to a power supply source is the collector of one in the prior art Switched transistor whose emitter is at ground potential lies. This transistor is based on a base of one Pulse generator controlled. As a protective circuit against Current overload of the transistor is one of a variety provided by components built circuit, the consists essentially of a detection circuit which the saturation voltage (collector emitter voltage) of the Power transistor detected and one from the Saturation voltage derived short-circuit protection signal generates a transistor that controls the base of the Power transistor in the event of current overload to ground potential sets and thereby blocks the power transistor. The Circuit works on the principle of voltage feedback, wherein a separate memory circuit is provided in the determined depending on the switched Saturation voltage increases stepwise a voltage is built, which is the base of the power transistor short-circuiting transistor only turns on when a certain value is exceeded.

A protection circuit working on the same principle is furthermore from DE 33 25 742 A1 for the protection of a Power transistor in an electrical Circuit arrangement for controlling a direct current, especially for a brightness changeable Dashboard lighting of vehicles, known. This too  Circuit is very complex and requires several Transistor gain stages to with impermissible current flow through the power transistor against the base of the transistor Switch mass. Has been disadvantageous in such Circuits proved that the protective effect depends on the current gain of the power transistor and not on a certain value, even if the Power transistors, is adjustable.

The invention has for its object a Protection circuit, explicitly a short circuit protection circuit, for a circuit arrangement with a light indicator element to train in a motor vehicle so that with only efficient protection, especially for a few components Short-circuit protection of those that feed the LED display Circuits or the control circuits controlling them, including the indicator element itself, against offers impermissible current increase.

This task is solved by the im Characteristics of claim 1 specified technical teaching.  

Advantageous developments of the invention are in the Sub-claims specified in detail, including some too protective circuits in the power supply branch the indicator element are switched to z. B. display different functional states or one of the To effect light-dependent intensity control. It goes without saying that z. B. at one Intensity regulator in the form of an electronic resistor, e.g. B. a field effect transistor to the gate of Field effect transistor the required Information control voltage must be applied to the linear resistance of the source-drain path to control accordingly. But it can also be a mechanical one Contact, e.g. B. a relay contact, in the circuit be turned on, the z. B. when switching on the heating is switched on. Another circuit enables one Control of the current flowing through the LED.

The invention is described below with reference to a drawing illustrated practical circuit embodiment explained in more detail.

The circuit arrangement according to the figure consists of a diode 1 for protection against polarity reversal, which is connected to an operating voltage source U _B , for. B. + 12V, is present. The diode 1 is connected to a measuring resistor 2 , the voltage drop of which is compared with the voltage present at a flux diode 3 . The flux diode, this is a diode arrangement that can be regarded as a replacement diode arrangement for a single Zener diode, which cannot be used due to the low reference voltage (1.5 V), is with its anode with the common coupling point of the diode 1 and connected to the measuring resistor 2 and connected with its cathode to the base of the transistor 4 . The diode 3 determines the comparison potential U _S. The base of transistor 4 is also connected to ground potential via a base current limiting resistor 5 . The emitter of the pnp-doped transistor 4 is connected to the lower connection point of the measuring resistor 2 . The collector leads to the input of a downstream circuit stage for a day / night light control for the light indicator element 6 of an LED. The downstream control circuit consists of a pnp-doped transistor 7 , which is connected with the emitter to the collector of transistor 4 and whose collector is connected to the anode of the downstream light-emitting diode 6 . The cathode of the light-emitting diode 6 is connected via a current limiting resistor 8 to a transistor 9 used as a switch, specifically to the collector, while the emitter of this transistor 9 is connected to ground. The transistor 9 is switched on or off by its base connection as a function of a control voltage U _S2 . If e.g. B. the heating control is switched on, there is a positive potential at the base of the npn-doped transistor 9 , ie the transistor 9 becomes conductive, so that a current flows through the circuits through the light-emitting diode 6 , which causes it to light up to the Display function that is currently set.

The day / night circuit is implemented with a transistor 7 , to whose emitter-collector path a zener diode 10 is connected in parallel, which is connected to the emitter with the cathode and to the collector with the anode. The transistor 7 is driven via its base, to which a control voltage U _{S1 is applied} via a diode 11 . Between the diode 11 , which is provided as a decoupling diode, and the transistor 7 , a voltage divider comprising the resistors 12 and 13 is connected upstream. The Zener diode 10 is ineffective during daytime operation, that is to say the light-emitting diode 6 is intended to reach the highest luminous intensity level during daytime operation and thus the highest-rated current flows through it. This presupposes that the transistor 7 is fully conductive, ie there is a control voltage U _S1 at the control input which is 0 or negative with respect to the collector-emitter voltage and thus causes the transistor 7 to switch on fully. If a positive voltage U _S1 is applied to the night position by switching a switch, the transistor 7 is blocked and the current flows exclusively via the diode 10 . This current is so great that the light-emitting diode 6, when the switching transistor 9 is turned on, indicates the functional state with a lower light intensity. The control voltage U _S1 can e.g. B. be coupled to the light control circuit of the vehicle.

In the normal operating state, when the desired normal current flows through the transistor 4 and the LED display 6 lights up, the transistor 4 is turned on . The collector-emitter potential is approx. 200 mV. As soon as the current through the measuring resistor 2 increases as a result of a short circuit, the transistor is fed back via the emitter base and the diode 3 . The transistor 4 regulates and, viewed as a switch, it is continuously closed or opened. However, it can occur that the transistor is driven into an undefined state with the appropriate dimensions, so that the power dissipation on it becomes so high that it can "burn off". To avoid this effect, which can in principle be switched off by appropriate dimensioning and attachment of a cooling plate, the circuit limiting the short-circuit current is coupled to a flip-flop circuit, which causes the transistor 4 to either have one switching state, namely the normal one, or the other one locked state. As a result, transistor 4 , which normally acts as a control transistor, is set into defined switching states with a declining characteristic. The flip-flop suddenly increases the voltage UCE across transistor 4 ; the base of the transistor 4 is set to the operating voltage potential 12V. The circuit consists of a voltage divider with resistors 14 and 15 which are connected in parallel to the emitter-collector path of transistor 4 . The base of a further transistor 16 , a pnp-doped transistor, is connected to the center tap.

The emitter of this transistor is connected with the upper coupling point between the diode provided as reverse polarity protection and the measuring resistor 2 . The collector of transistor 16 , however, is connected to the base of transistor 4 . The capacitor 17 provided between the base and emitter of the transistor 16 serves to suppress conducted interference so that the circuit does not become dependent on it. This trigger circuit interacts with the circuit limiting the short-circuit current and with the transistor as follows:

The transistor 16 is normally blocked because the voltage drop across the resistor 14 is too small to open the transistor 16 . This is the case when the transistor 4 is fully conductive. However, as soon as a sufficient current flows through the shunt from the resistors 14 , 15 , the voltage potential at the resistor 14 and thus at the base increases. If the necessary 0.7 V or 0.5 V is exceeded, the transistor 16 becomes conductive. As soon as the transistor 16 is conductive, the base of the transistor 4 is practically set to the operating voltage potential, that is to say the transistor 4 is blocked, so that no more current can flow through it. This state occurs when the base emitter potential of transistor 16 drops below 0.7V. The tipping state is maintained so that a short-circuit protection is given. With the flip-flop, the actual short-circuit current limiting circuit is practically triggered, so that no current flows to the sequential circuit with the transistor 7 and the LED 6 and thus these circuits are protected. The state is maintained as long as the operating voltage source is present and the transistor 9 is turned on. If the transistor 9 is blocked and a short circuit is not in the upstream circuits, for. B. the day light switch, before, the flip-flop is switched back again; the normal operating state of the circuit is restored. The circuit can also be put into operation again by switching off the operating voltage source and switching it on again if there is no short circuit.

A dimensioning example is given below:

1 diode BAV 103
2 measuring resistor 3.3 Ohm
3 diode 1.5V
4 transistor BC 638
5 resistor 3.3 kOhm
6 LEDs
7 transistor BC 327/40
8 resistor 330 ohms
9 transistor BC 337
10 Zener diode 6.2V / 1.3W
11 diode LL 4148
12 resistance 1 kOhm
13 resistance 2.2 kOhm
14 resistor 4.7 kOhm
15 resistance 47 kOhm
16 transistor BC 557
17 capacitor 10 µF

Claims (7)

1.Protection circuit for a circuit arrangement with a light-emitting element, such as light-emitting diode, in a motor vehicle against current overload, the light-emitting element being adjustable to a plurality of intensity light levels by means of a control circuit and with a transistor having its collector-emitter path connected in series with the light-emitting element, with a toggle switch which switches the transistor during control use from a defined conductive state into a blocked state, characterized in that a measuring resistor ( 2 ) for measuring the instantaneous current is connected in series with the emitter of the transistor ( 4 ), that the transistor ( 4 ) with the Base is connected to a reference voltage source ( 3 ) connected in parallel to the measuring resistor ( 2 ) and regulates as soon as the voltage drop generated by the current at the measuring resistor ( 2 ) and the base voltage drop exceed the reference voltage, and that the toggle switch g consists of a further transistor ( 16 ) which is connected with its emitter collector path parallel to the reference voltage source ( 3 ), and whose base is connected to a voltage divider ( 14 , 15 ) connected in parallel to the base collector path of the first transistor ( 4 ), the resistors of which are so are dimensioned so that when control operation of the first transistor ( 4 ) begins, the further transistor ( 16 ) switches on, via which the voltage potential at the base of the first transistor ( 4 ) from the common connection point of the measuring resistor ( 2 ) and the reference voltage source ( 3 ) is present. 2. Protection circuit according to claim 1, characterized in that the first transistor ( 4 ) is a pnp-doped transistor, and that the second transistor ( 16 ) is a pnp-doped transistor, and that the emitters in each case at the upper measuring point of the measuring resistor ( 2 ) are connected, which is connected to the operating voltage source (U _B ), and that is connected to the connection point of the anode of a diode provided as a reference voltage source ( 3 ), the cathode of which is connected to the base of the first transistor ( 4 ) is connected to ground via a resistor ( 5 ), and that the collector of the second transistor ( 16 ) is connected to the base of the first transistor ( 4 ). 3. Protection circuit according to one of the preceding claims, characterized in that in series with the collector of the first transistor ( 4 ), a third switching transistor ( 7 ) is connected with its emitter collector path, which is controlled via the base in two switching positions (day / night switching ) can be brought in, and that a zener diode ( 10 ) is connected in parallel with the collector-emitter path of the third transistor ( 7 ) with a polarity such that a minimum current when the circuit is switched on via the zener diode ( 10 ) when the third transistor ( 7 ) is blocked flows through the light indicator element ( 6 ). 4. Protection circuit according to claim 3, characterized in that the third transistor is a pnp-doped transistor and with its emitter with the collector of the first Transistor is connected and with its collector the indicator element is connected, and that parallel to the collector-emitter path the Zener diode with the Cathode on the emitter and with the anode on the collector is switched on, and that the base has a Decoupling diode connected to a control circuit is. 5. Protection circuit according to one of the preceding claims, characterized in that the light indicator element a Light-emitting diode or a light-emitting diode arrangement (LED). 6. Protection circuit according to one of the preceding claims, characterized in that in series with the Illuminated display element a mechanical or a is switched by an electronic switch Function display circuit is controlled. 7. Protection circuit according to claim 1, characterized in that an electrically controllable resistor, such as Field effect transistor, in series with the indicator element is arranged.