AT504949B1 - CIRCUIT ARRANGEMENT FOR DETECTING A SHORT-CIRCUIT OF LUMINOUS DIODES - Google Patents

Description

2 AT 504 949 B1

The invention relates to a circuit arrangement for detecting a short circuit of one or more light emitting diodes, wherein the light emitting diodes are provided for the realization of at least one light function for a headlight or a light unit of a motor vehicle, and the light emitting diodes are connected to each other in series and via a constant current source to a Supply voltage source are.

A luminaire with LEDs for a bicycle and a circuit arrangement for the LEDs is known from DE 38 32 109 A1. Other circuit arrangements for light-emitting diodes are known e.g. from JP 11 288 252 A, WO 2005/079121 A2, as well as from JP 2006 131 138 A, WO 2007/069200 A1 and JP 2007 182 158.

In the automotive sector, the importance of light emitting diodes for generating light functions in light units or vehicle headlights is constantly increasing. For example, with light emitting diodes light functions such as parking lights, city lights, low beam, high beam, fog light, cornering light, etc. can be realized.

To produce such a light function, a number of light-emitting diodes are usually connected in series with one another, as mentioned above, wherein the light-emitting diodes are connected to a supply voltage via a constant current source.

The failure of light sources comes in vehicle headlights or light units for motor vehicles usually by interruption to conditions, such as lamps with a filament. Even when using light-emitting diodes as light sources is usually in the event of failure of one or more light emitting diodes before a break. With less probability but can also be a short circuit of one or more light emitting diodes.

On the part of the automotive industry there is a demand to be able to detect the short circuit of a single or of several light-emitting diodes.

Due to the large tolerance of the forward voltage of the light-emitting diodes, however, it is very difficult and with great expense in the case of series connection of a plurality of light-emitting diodes, i. only by consuming electronics possible to detect a short circuit of one or more light emitting diodes by means of total voltage monitoring of the light-emitting diode strand.

It is an object of the invention to find a circuit arrangement by means of which a simple and efficient detection of a short circuit of one or more light-emitting diodes in a series connection of light-emitting diodes, which are provided for the realization of at least one light function in a light unit or a headlight of a motor vehicle.

This object is achieved with a circuit arrangement mentioned in the fact that according to the invention each LED is associated with an electronic switch, wherein at least one pole of each switch via a common load resistor to the power source, and wherein further a falling voltage to the LEDs a control input of the respective LED is assigned associated with the light switch, and wherein the switch of an open state / closed state in the normal operation of the associated light emitting diode in a closed state / open state in the short circuit case of the light emitting diode passes, and the resulting change in the voltage drop across the load resistor is detected.

In the circuit arrangement according to the invention occurs in a short circuit of one or more LEDs to a significant change in the voltage drop across a load resistor. This change can be easily detected and a short circuit detected.

In a first variant of the circuit arrangement according to the invention it is provided that one pole of each switch at the beginning of the diode path of its associated light emitting diode is 3 AT 504 949 B1 and the switches in the normal operation of the LED open, i. are not conducting current and in the short circuit of a light emitting diode of its associated switch in a closed, i. Current conducting state transitions so that current can flow through the switch and the working resistor.

This leads to an increase in the voltage drop across the working resistor, which is originally 0 or practically zero in practice. The increase of the voltage or the voltage difference can be detected by suitable means and thus closed on the short circuit of one or more light emitting diodes back.

In this variant, the switches are advantageously designed as field effect transistors.

In another embodiment of the invention, the switches are connected to each other in series and a switch is from a closed state during normal operation of the associated diode, in which current can flow through the switch, in the short circuit to the open state.

The switches are expediently designed as NPN transistors, and the voltage dropping across a light-emitting diode is supplied to the control input of the associated switch via a PNP transistor. With the PNP transistors, the switches can be decoupled from the light-emitting diodes, whereby the series connection of the switches is possible.

In both circuit arrangements, only one additional line is required in order to be able to detect the criterion for the presence of a short circuit at one or more light-emitting diodes, namely a change in the voltage drop across the load resistor.

In the following the invention is explained in more detail with reference to the drawing. In this shows

Fig. 1 shows a first variant of a circuit arrangement according to the invention, and Fig. 2 shows a further variant of a circuit arrangement according to the invention.

FIG. 1 shows a first variant of a circuit arrangement for detecting a short circuit of one or more light-emitting diodes L1-L4. In the circuit shown, by way of example, four light-emitting diodes L1-L4 are provided for realizing at least one light function for a headlight or a light unit of a motor vehicle. In principle, however, more or fewer light emitting diodes can be provided, and the invention also works with only one light emitting diode.

The light emitting diodes L1 - L4 are connected in series with one another and are connected to a supply voltage source UBQ via a constant current source IQK.

Each light-emitting diode L1 - L4 is associated with an electronic switch SCH1-SCH4. A pole D of each switch SCH1 - SCH4 is connected to the current source IQK via a common working resistor R2. In series with the light-emitting diodes L1-L4, a series resistor R1 is connected. This is needed to create a voltage drop across the load resistor R2 along with the switches. Each of a light-emitting diode L1 - L4 falling voltage Ug is a control input G of the respective light emitting diode L1 - L4 associated switch SCH1 - supplied SCH4.

A pole S of each switch SCH1 - SCH4 is at the beginning of the diode path of its associated light emitting diode L1 - L4 and the switches SCH1 - SCH4 are open during normal operation of the light emitting diode L1 - L4, i. not conducting electricity. In the event of a light-emitting diode L1-L4 short-circuiting, the switch SCH1-SCH4 assigned to it switches into a closed, i. Current conducting state passes, so that current can flow through the switch SCH1 - SCH4 and the working resistor R2. 4 AT 504 949 B1

This results in a significant change (increase) in the voltage U2 dropping across the load resistor R2, which is originally 0 or practically zero in practice. The increase in the voltage U2 can be detected by suitable means as explained in more detail below and thus closed on the short circuit of one or more light emitting diodes back. For the realization of such a circuit, it is expedient if the switches SCH1 - SCH4 are designed as field-effect transistors, since with these the required properties of the switches can be realized in a simple manner.

If current flows through the light emitting diodes, a voltage Ug drops across them. This voltage Ug is respectively between the gate terminal G and the source terminal S of the field effect transistors, which are designed as a self-conductive type. If a light-emitting diode is in normal operation, ie without a short circuit, then this voltage Ug ensures that the field-effect transistor becomes high-impedance and thus blocks.

It sets a voltage U2 on the working resistor R2, formed by the voltage divider R2 itself and the source-drain resistance of the field effect transistor, which is zero in the ideal case (as already mentioned above), but in reality determined by the characteristic properties of the field effect transistor and practically never becomes completely zero.

In a concrete embodiment as shown, this voltage U2 is differentially measured with an integrated circuit IC1A, AU2 = U2-U1, since in the example shown, the potential U2 at the working resistor R2 is floating and can not be related to ground.

With an integrated circuit IC1B, a comparator is realized, which has a reference voltage Uref applied to its negative input, and compares this voltage Uref with its positive input to which the voltage difference AU2 is applied.

The reference voltage is made adjustable by R8 and R9, in that the threshold can be set via the resistors R8, R9.

If a short circuit occurs in one of the light-emitting diodes, the potential between gate and source terminal of the associated field-effect transistor SCH1-SCH4 becomes zero and the associated field effect transistor becomes conductive, low-resistance.

This results in a higher voltage at the working resistor R2. This voltage is, as already explained, differentially measured with the integrated circuit IC1A and thus referred to ground. The integrated circuit IC1B compares this now higher voltage at the positive input with its reference voltage at the negative input and the integrated circuit IC1B responds. As a result, its output switches to a positive potential, which is measured at the diagnostic output DIA, so that a short circuit is detected by one or more light emitting diodes.

This explained principle of short-circuit detection is independent of the number of LEDs.

Another advantage of this circuit is that, in the event that the driver electronics board EPCB and the LED board LPCB are space-wise separated as shown, the wiring effort with only 3 additional lines is very low.

In addition, the component cost on the LED board LPCB to realize the short circuit detection is low.

Claims (6)

The resistors R3, R4, R5, R7 are a necessary circuit of the integrated circuit IC1A for use as a differential amplifier. FIG. 2 shows a further variant of a circuit according to the invention. In this embodiment of the invention, the switches SCH1 '- SCH4' are connected in series with each other and a switch SCH1 '- SCH4' goes from a normally closed state of the associated diode L1 - L4, in which current through the switches SCH1 '- SCH4' flow may, at the short circuit in the open state over. The switches SCH1 '- SCH4' are designed as NPN transistors, and the voltage Ug falling across a light-emitting diode L1 '- L4' is connected to the control input B of the associated switch SCH1 '- SCH4' via a PNP transistor Tpn1, Tpn2, Tpn3, Tpn4 supplied. With the PNP transistors, the switches can be decoupled from the light emitting diodes, whereby the series connection of the switches SCH1 '- SCH4' is possible. The switches SCH1 '- SCH4' are connected in series via the poles C, E with a load resistor R2 '. If the light-emitting diodes L1-L4 are not short-circuited, then the forward voltage Ug is applied to them. This voltage controls the PNP transistors SCHT - SCH4 ', which pass on a corresponding signal to the respectively associated NPN transistor SCH1' - SCH4 '. The NPN transistors also drive through, i. Current can flow through the series connection of the NPN transistors and the collector potential of the NPN transistors is pulled to ground or almost to ground via the very low resistance R1. Basically, of course, another potential can be used. The evaluation signal (voltage drop U2 ') at the load resistor R2'_ follows the potential of the NPN transistors and also goes to almost ground or ground. If one (or more) of the LEDs has a short circuit, a voltage Ug at 0V is applied to the short-circuited LED, thereby blocking the associated PNP transistor and also the associated NPN transistor. The collector potential at the NPN transistor becomes high and thus also the evaluation signal at the load resistor R2 '. The change of the voltage drop across the load resistor R2 'can then be further processed as well to detect a short circuit as in the first variant described above. The evaluation of the voltage drop across the load resistor takes place in the variant of Figure 2 in principle that of Figure 1. However, here is the voltage across the load resistor R2 'not floating, so that the voltage signal can be applied directly to the positive input of the integrated circuit IC1B and the Differential amplifier IC1A can be omitted, whereby the evaluation circuit can be simplified. 1. Circuit arrangement for detecting a short circuit of one or more light-emitting diodes (L 1 - L 4), wherein the light-emitting diodes (L 1 - L 4) are provided for realizing at least one light function for a headlight or a light unit of a motor vehicle, and the light-emitting diodes ( L1 - L4) are connected in series with one another and are connected to a supply voltage source (UBQ) via a constant current source (IQK), characterized in that each light emitting diode (L1 - L4) is assigned an electronic switch (SCH1 - SCH4, SCH1 '- SCH4') is, wherein at least one pole (D, C) of each switch (SCH1 - SCH4, SCHT - SCH4 ') via a common load resistor (R2, R2') to the power source (IQK), and wherein further one of the light emitting diodes (L1 - L4) falling voltage (Ug) to a 6 AT 504 949 B1 control input (G, B) of the respective light emitting diode (L1 - L4) associated switch (SCH1- SCH4, SCHI '- SCH4') is supplied, and wherein the switch ( SCH1 - SCH4, SCH1 '- SCH4') transitions from an open state / closed state in normal operation of the associated light emitting diode (L1 - L4) to a closed state / open state in the event of a short circuit of the light emitting diode (L1 - L4), and the resulting change in the Voltage drop (U2, U2 ') to the load resistor (R2, R2') is detectable. 2. A circuit arrangement according to claim 1, characterized in that a pole (S) of each switch (SCH1 - SCH4) at the beginning of the diode path of its associated light emitting diode (L1 - L4) and the switches (SCH1 - SCH4) in normal operation of the light emitting diode ( L1 - L4) open, ie are not conducting current and in the short circuit of a light emitting diode (L1 - L4) of its associated switch (SCH1 - SCH4) in a closed, i. Current conductive state passes so that current can flow through the switch (SCH1 - SCH4) and the working resistor (R2). 3. A circuit arrangement according to claim 1, characterized in that the switches (SCH1 '- SCH4') are connected to each other in series and a switch (SCH1 '- SCH4') of a closed state in normal operation of the associated diode (L1 - L4), in which current can flow via the switch (SCH1 '- SCH4'), at the short circuit in the open state passes. 4. Circuit arrangement according to claim 2, characterized in that the switches (SCH1 - SCH4) are designed as field effect transistors. 5. Circuit arrangement according to claim 3, characterized in that the switches (SCH1 '- SCH4') are designed as NPN transistors. 6. Circuit arrangement according to Claim 5, characterized in that the voltage (Ug) dropping across a light-emitting diode (L1 '- L4') is applied to the control input (B) of the associated switch (SCH1 '- SCH4') via a PNP transistor (Tpn1, Tpn2, Tpn3, Tpn4) is supplied. For this purpose 2 sheets of drawings