DE10236862B4 - Circuit arrangement for power supply and for controlling light-emitting diode arrangements, in particular in vehicle lights - Google Patents

Abstract

Circuit arrangement (1) for the power supply and for controlling light-emitting diode arrangements (21, 22, ..., 2n), in particular in vehicle lamps, wherein
The circuit arrangement (1) has a plurality of outputs (61, 61 ', 62, 62', ..., 6n, 6n ') for connecting light-emitting diode arrangements (21, 22, ..., 2n),
The circuit arrangement (1) has means for current monitoring,
- exactly one output (61, 61 ', 62, 62', ..., 6n, 6n ') is assigned to each current monitoring means,
- the current monitoring means monitor the load currents (I ₁ , I ₂ , ..., I _n ) flowing through the outputs (61, 61 '; 62, 62';...; 6n, 6n '),
The circuit arrangement (1) furthermore has switching means,
- The switching means at a strong deviation of the load currents (I ₁ , I ₂ , ..., I _n ) of a setpoint, the load currents (I ₁ , I ₂ , ..., I _n ) at all outputs (61, 61 ' 62, 62 ', ..., 6n, 6n'),
and the circuit arrangement
characterized in that
- The circuit arrangement (1) at least one integrated ...

Description

The The present invention relates to a power supply circuit and for controlling light emitting diode arrangements, in particular in vehicle lights.

The technical background for the present invention forms ECE Regulation No. 7 which technical regulations for Limit, tail and brake lights are. This ECE Regulation No. 7 is last in the BGBI. II 1995, 34. ECE Regulation No. 7 dictates that lights with more than one bulb so have to be designed that in case of failure of a bulb, the remaining bulbs the photometric minimum requirements, in particular with regard to to meet the brightness of the lamp. In today's lights with light-emitting diode arrangements as lighting means is the circuit arrangement for Power supply and for controlling the LED arrangements so realized that the requirement of the ECE regulation No. 7 is complied with. That is, there will be more light emitting diode arrangements used in such a luminaire, as to achieve the required photometric minimum requirements would be necessary. The Circuit arrangements are designed so that at a Failure of a light-emitting diode arrangement by the remaining still operable LED arrangements the minimum lighting requirements is met.

One Disadvantage of this known circuit arrangements is that because the required redundancy of the circuit a variety of outputs for powering and controlling the light emitting diode assemblies must be provided. Furthermore, must in lights produced with these circuits as well a plurality of redundant light emitting diode arrays are provided at the outputs be.

Of the ECE Regulation No. 7 is sufficient a lamp further, if a lamp with more than one bulb in case of failure behaves like this How a luminaire behaves with a single light source. Provided So a lamp with several bulbs the behavior of a Lamp with a single bulb in case of failure simulates need redundant light emitting diode arrangements and the associated circuit parts the circuit arrangement for power supply and for driving the Light emitting diode arrangements should not be provided. A lamp with a circuit arrangement for power supply and for driving of several bulbs so then also corresponds to the ECE regulation No. 7, when the failure of a bulb, the circuitry the remaining bulbs controls so that the entire lamp is shut down.

A circuit arrangement for power supply and for driving lights with a plurality of bulbs, wherein after the failure of a light source and the other bulbs are turned off, for example, from the patent DE 197 08 659 C1 known. The invention protected by this patent is based on the idea that the change in the power consumption of a light-emitting diode turn signal becomes greater the more light-emitting diodes are switched off in the event of a defect of a single light-emitting diode. D. h., In addition to the defective light emitting diode according to the invention further LEDs are turned off, so that the current consumption of the LED turn signal changes significantly. This significant change in the power consumption of the LED turn signal causes a control circuit detects the failure of the LEDs and indicates by an optical signal. In order to change the current consumption as significantly as possible by switching off additional LEDs to the defective LED, the entire number of existing LEDs of the turn signal can be switched off. The patent DE 197 08 659 C1 Therefore, already discloses a circuit arrangement for power supply and for controlling LED arrangements in the case of failure of a light emitting diode array, the circuit arrangement, the entire number of existing light emitting diode arrays off. However, the cited patent does not disclose a concrete realization for this case. The publication DE 197 08 659 C1 Rather, it merely discloses a concrete solution in which only about half of the light-emitting diode arrangements connected to the circuit arrangement are switched off in order to achieve the necessary change in the power consumption, which is detected by the control circuit as an error and displayed by means of an optical signal.

From the publication with the publication number DE 201 07 482 U1 a circuit arrangement of the aforementioned type is known, are provided in the turn-off power sources that switch off the load currents at all outputs in case of large deviations of the load currents from a desired value. Thus, the whole formed by the light-emitting diode bulbs can be shut down in case of failure.

The circuit arrangement has means for current monitoring, which detects the reduction of the load current in the event of a fault in a light-emitting diode of the light-emitting diode arrangements and switches off all light-emitting diode arrangements which are connected to the circuit arrangement via switching means. It is advantageous in such a circuit arrangement in this case that each means for current monitoring is assigned exactly one output for connecting the light-emitting diode arrangements. Here in the circuit arrangement differs, namely fundamentally from a circuit arrangement as it is known from the publication DE 197 08 659 C1 is known. In the circuit arrangement described in detail there, several outputs are simultaneously monitored by a means for current monitoring.

This has the disadvantage that, after having determined in a fault, which means for current monitoring via the switching means has switched off the light-emitting diode arrangements, can not easily determine which of the monitored light-emitting diode arrays is defective and so has caused the means for current monitoring to Trigger switching means. In a circuit arrangement according to the document DE 201 07 482 U1 on the other hand, if it has triggered the means for current monitoring, it is possible to determine that the light-emitting diode arrangement monitored by this means for current monitoring has a defect and is thus responsible for switching off the entire luminaire.

The supervision the load currents takes place in each branch and in addition the entire load current flowing through the assemblies is monitored. As soon as a strong deviation of one of the currents is detected takes place the shutdown in a central location, namely by switching off the switchable power source. This must therefore be with any means of power monitoring the load currents be connected and have a corresponding number of terminals, via which the means of current monitoring can signal the deviation from the setpoint.

One Disadvantage of this circuit arrangement is that this particular because of the star-shaped connections between the means of current monitoring and the switching means is not readily expandable.

Circuit arrangements with switching means for the simultaneous switching off of all light-emitting diode arrangements of a lighting means are also known from the documents DE 199 50 135 A1 . DE 100 17 878 A1 . AT 005 190 U1 and FR 2 724 749 A1 known.

Of these documents, the published patent application DE 199 50 135 A1 a circuit arrangement with a plurality of light-emitting diode arrangements, wherein the light-emitting diode arrangements are not all connected identically. This also leads to the disadvantage that the circuit arrangement is not readily expandable.

The same applies to the circuit arrangement as in the published patent application DE 100 17 878 A1 is disclosed. In order to expand this circuit arrangement, a new dimensioning of the selected components is necessary.

Also in the pamphlets AT 005 190 U1 and FR 2 724 749 A1 disclosed solutions do not lead to easily expandable circuitry.

Of the The present invention is therefore based on the object, a circuit arrangement for powering and controlling light emitting diode arrays to propose, in which case in case of failure a light emitting diode array, the entire number of existing light emitting diode arrays switched off and at the same time expandable with simple means.

These Task is according to the invention with a Circuit arrangement according to claim 1 solved.

The Circuitry comprises an integrated circuit. Everyone integrated circuit includes exactly one of the means of current monitoring and exactly one switching means. Furthermore, each integrated circuit has a first terminal located within the integrated circuit with the means for current monitoring connected is. Such an integrated circuit has a second port on, over a connection outside the integrated circuit with the first terminals of all integrated circuits connected is. This second connection is according to the invention within the integrated circuit with a control terminal of the switching means connected.

Everyone integrated circuit can according to the invention having a controlled current source whose output is connected to one terminal the output of the circuit is connected.

Two circuit arrangements 1 for power supply and for controlling LED arrangements are described in more detail with reference to the drawing. It shows

1 a known from the prior art circuit arrangement with connected light-emitting diode arrangements with a common switching means and

2 a circuit arrangement according to the invention with connected light emitting diode arrangements with an integrated circuit per output.

In the 1 shown circuit arrangement has an input 8th . 8th' and outputs 61 . 61 '; 62 . 62 ';...; 6n . 6n ' on. The connection 8th of the entrance 8th . 8th' is at a positive potential while connecting 8th' is at ground potential. about the entrance 8th . 8th' Therefore, the voltage U ₁ from. At the exits 61 . 61 '; 62 . 62 ';...; 6n 6n ' are light emitting diode arrangements 21 . 22 , ..., 2n connected. These light-emitting diode arrangements 21 . 22 , ..., 2n each consist of series-shaped light-emitting diodes. The connections 61 . 62 , ..., 6n the outputs of the circuit arrangement 1 are with the connection 8th the input of the circuit arrangement 1 connected and are therefore at the same potential as the connection 8th , The connections 61 62 ' , ..., 6n ' the outputs of the circuit arrangement 1 are with inverting inputs of operational amplifiers 31 . 32 , ..., 3n connected. The non-inverting inputs of these operational amplifiers 31 . 32 , ..., 3n are via measuring resistors R ₁ , R ₂ , ..., R _n also with the connection 61 ' . 62 ' , ..., 6n ' connected. Between the inputs of the operational amplifiers, therefore, the voltage drops across the measuring resistors R _1, R _2, ..., R _n to falling. The outputs of the operational amplifier 31 . 32 , ..., 3n are diodes D ₁ , D ₂ ,..., D _{n associated} with each other and simultaneously with a control terminal 41 a switching means 4 connected. The input of the switching means 42 is via a controlled current source I _q with the non-inverting inputs of the operational amplifier 31 . 32 , ..., 3n and thus simultaneously connected to the negative potential of the measuring resistors R ₁ , R ₂ , ..., R _n . The exit 43 of the switching means 4 is about the connection 8th' of the entrance 8th . 8th' the circuit arrangement 1 connected to the ground potential.

As already stated is located at the inputs of the operational amplifier 31 . 32 , ..., 3n the voltage across the measuring resistors R ₁ , A ₂ , ..., R _n . The voltage dropping across the measuring resistors R ₁ , R ₂ ,..., R _n results from the magnitude of the resistance of the measuring resistor R ₁ , R ₂ ,..., R _n and the current flowing through the measuring resistors. The current flowing through the measuring resistors R ₁ , R ₂ ,..., R _n corresponds to that in the operational amplifiers 31 . 32 , ..., 3n no electricity flows in, via the outputs 61 . 61 '; 62 . 62 ';...; 6n . 6n ' flowing load currents I ₁ , I ₂ , ..., I _n . By a change in voltage across the measuring resistors R ₁ , R ₂ , ..., R _n falling voltage can thus change the by the LED assemblies 21 . 22 , ..., 2n flowing load currents I ₁ , I ₂ , ..., I _{n are} measured. If this voltage, which drops across the measuring resistors R ₁ , R ₂ ,..., R _n, deviates from a desired value, the output of the operational amplifier becomes 31 . 32 . 3n supplied with a signal which via the control input 41 the switching means 4 opens and so the current flow through all light emitting diode array 21 . 22 , ..., 2n , which are connected to the circuit 1 connected, are interrupted.

In the 2 illustrated circuit arrangement according to the invention has an input 8th . 8th' on, with the connection 8th of the entrance 8th . 8th' is at a positive potential while connecting 8th' of the entrance 8th . 8th' is at ground potential. Therefore falls over the entrance 8th . 8th' a voltage U ₁ from. The circuit arrangement 1 also has exits 61 . 61 '; 62 . 62 ';...; 6n . 6n ' on. At these outputs are light emitting diode arrangements 21 . 22 , ..., 2n connected. These light-emitting diode arrangements 21 . 22 , ..., 2n consist of series-connected LEDs. To supply the light-emitting diode arrangements 21 . 22 , ..., 2n be in the circuit 1 Load currents I ₁ , I ₂ , ..., I _n generated, which via the outputs 61 . 61 '; 62 . 62 ';...; 6n . 6n ' thus also by the light-emitting diode arrangements 21 . 22 , ..., 2n flow. The power supply of the LED arrangements 21 . 22 , ..., 2n via the connections 61 . 62 , ..., 6n which with connections 714 . 724 . 7n4 of integrated circuits 71 . 72 , ..., 7n are connected.

The integrated circuits 71 . 72 , ..., 7n are about connections 710 . 720 , ..., 7N0 with the positive potential of the voltage U ₁ at the terminal 8th of the entrance 8th . 8th' connected to the circuit arrangement. Further, the integrated circuits 71 . 72 , ..., 7n over connections 713 . 723 , ..., 7n3 with the ground potential, ie with the connection 8th' the entrance 8th . 8th' connected. Furthermore, the integrated circuits have 71 . 72 , ..., 7n first connections 711 . 721 , ..., 7N1 and second connections 712 . 722 , ..., 7n2 on. The first connections 711 . 721 , ..., 7N1 and the second connections 712 . 722 . 7n2 are interconnected and are therefore at the same potential. Between this potential and the ground potential there is an electrical connection via a resistor R.

The first connections 711 . 721 , ..., 7N1 are inside the integrated circuits 71 . 72 , ..., 7n with means of current monitoring of the connection 714 . 724 , ... 7n4 flowing load currents I ₁ , I ₂ , ..., I _n connected. Ie. the means for current monitoring within the integrated circuits 71 . 72 , ..., 7n monitor the light through the LED arrays 21 . 22 , ..., 2n flowing load currents I ₁ , I ₂ , ..., I _n . If the means for current monitoring detect a deviation of the load currents I ₁ , I ₂ ,..., I _n from a setpoint, this will be at the first terminals 711 . 721 , ..., 7N1 indicated by a potential change. This simultaneously becomes the potential of the second terminals 712 . 722 . 7n2 all integrated circuits 71 . 72 , ..., 7n changed. The potential change at the second inputs 712 . 722 , ..., 7n2 the integrated circuits 71 . 72 , ..., 7n initiated in the integrated circuits 71 . 72 , ..., 7n integrated switching means to interrupt the over the connections 714 . 724 . 7n4 to the connections 61 . 62 , ..., 6n flowing load currents I ₁ , I ₂ , ..., I _n . The light-emitting diode arrangements 21 . 22 , ..., 2n are switched off by the interruption of the load currents I ₁ , I ₂ ,..., I _n .

Claims (2)

Circuit arrangement ( 1 ) for power supply and for controlling LED arrangements ( 21 . 22 , ..., 2n ), in particular in vehicle lamps, wherein - the circuit arrangement ( 1 ) several outputs ( 61 ; 61 '; 62 ; 62 ';...; 6n ; 6n ' ) for connecting light-emitting diode arrangements ( 21 . 22 , ..., 2n ), - the circuit arrangement ( 1 ) Means for current monitoring, - each means for current monitoring exactly one output ( 61 . 61 '; 62 . 62 ';...; 6n . 6n ' ), - the means for current monitoring via the outputs ( 61 . 61 '; 62 . 62 ';...; 6n . 6n ' ) current load currents (I ₁ , I ₂ , ..., I _n ) monitor, - the circuit arrangement ( 1 ) further switching means, - the switching means at a strong deviation of the load currents (I ₁ , I ₂ , ..., I _n ) from a setpoint the load currents (I ₁ , I ₂ , ..., I _n ) at all outputs ( 61 . 61 '; 62 . 62 ';...; 6n . 6n ' ), and the circuit arrangement is characterized in that - the circuit arrangement ( 1 ) at least one integrated circuit ( 71 . 72 , ..., 7n ), - each integrated circuit ( 71 . 72 , ..., 7n ) comprises precisely one of the current monitoring means as well as exactly one of the switching means, - each integrated circuit ( 71 . 72 , ..., 7n ) a first connection ( 711 . 721 , ..., 7N1 ), which is connected to the means for current monitoring, wherein the means for current monitoring the deviation of the load currents (I ₁ , I ₂ , ..., I _n ) of the desired value in each case by a potential change at the first terminal ( 711 . 721 , ..., 7N1 ), - each integrated circuit ( 71 . 72 , ..., 7n ) a second port ( 712 . 722 , ... 7n2 ) connected to the first terminals ( 711 . 721 , ..., 7N1 ) of all integrated circuits ( 71 . 72 , ..., 7n ), which is why a potential change at one of the first terminals ( 711 . 721 , ..., 7N1 ) simultaneously to a potential change at the second terminals ( 712 . 722 , ... 7n2 ), - the second connection ( 712 . 722 , ... 7n2 ) is connected to a control terminal of the switching means and - the potential change at all second terminals ( 712 . 722 , ... 7n2 ) causes the switching means to an interruption of the load currents (I ₁ , I ₂ , ..., I _n ). Circuit arrangement according to the preceding claim, characterized in that each integrated circuit ( 71 . 72 , ..., 7n ) has a controlled current source whose output is connected to a terminal ( 61 . 62 , ..., 6n ) of the outputs ( 61 . 61 '; 62 . 62 ';...; 6n . 6n ' ) of the circuit arrangement ( 1 ) connected is.