DE10215486C1 - Automobile lighting device uses light-emitting diode (LED) lamp with incorporated function monitoring circuit and provision of current or voltage pulse for switching parallel load simulating standard light bulb - Google Patents

Abstract

The lighting device has an LED lamp (1) employing at least one light-emitting diode (12) supplied with current via a control device, with the supplied current monitored via a current monitoring circuit for function control of the lamp. A current or voltage pulse is supplied within a defined control window to the line (VL) connecting the lamp to the control device upon failure of the light-emitting diode, detected by a bias circuit (2) for switching in an electrical load (20) connected in parallel with the lamp for simulating a standard light bulb. An Independent claim for a bias circuit for an automobile lighting device is also included.

Description

The invention relates to a lighting device for vehicles with a at least one light emitting diode (LED) having a lamp arrangement, which via a Connection line is connected to a control unit for power supply, the current flowing from the control unit to the lamp arrangement of one Current monitoring circuit in the control unit for checking the function of the lamp arrangement is measured. A current value below a predetermined threshold value of the current monitoring circuit is rated as lamp failure.

Such a control unit can be, for example, a flasher unit to control a Indicator lamp arrangement, which has an integrated current monitoring circuit. The current monitoring circuit is operational with regard to its threshold value designed by incandescent lamps. However, the current consumption of an LED lamp arrangement is in Compared to an incandescent lamp arrangement much smaller, so that one for the Monitoring of incandescent flasher in the event of an LED Lamp arrangement would always incorrectly detect a lamp failure. The trend However, there are more and more turn signals with incandescent lamps with turn signals with LEDs to replace. The flasher units already installed in the vehicle are and should be removed Cost reasons cannot be exchanged.

In order to counter the associated problem, DE 101 07 578 A1 (according to published) proposed in the LED lamp, a parallel to the LED lamp arrangement switchable electrical list to provide, which simulates an incandescent lamp. Besides, is there a failure control circuit for the LEDs is provided in the LED light, which at Failure of at least one LED switching on the load and thus the Incandescent simulation prevents the lamp failure in this case correctly is recognized by the current monitoring circuit in the flasher unit. Between the flasher and according to DE 101 07 578 A1, only one connecting line is provided for the LED light, wherein the switchable electrical load is arranged in the LED lamp, which is disadvantageous since the switchable load in the vicinity of the LEDs generates annoying heat loss.  

This is particularly problematic when the load is on for the entire duration of the Flashing pulse remains switched on. The simulation of a light bulb by switching on a load for the entire duration of the flashing pulse is necessary, however, as LED Turn signal lights serve as a retrofit kit for vehicles with a wide variety of flasher units, the current monitoring circuits of various flasher units to the lamp current check at different times within the flashing pulse. To the whole To be able to cover the range of monitoring times, it is therefore necessary to: Current characteristic of an incandescent lamp, especially the cold inrush current peak during the to reproduce the entire duration of the flashing pulse.

From DE 201 15 409 U1 it is known that the switchable simulation load in one of the LED Lamp arrangement upstream matching circuit / ballast to provide, so that the heat loss is not generated near the LEDs. It is switched on and off the simulation load connected in parallel to the lamp arrangement by one of the Lamp arrangement assigned monitoring circuit via one of the Supply line separate signal line.

In addition, DE 198 52 351 A1 describes a diagnostic system for an LED light described, in which neither the LED light nor the control unit has a simulation load Incandescent simulation is provided. There is a control circuit in the LED light provided that completely switches off the LED matrix in the event of an LED failure. This System is designed for LEDs from the outset and does not rely on the current measurement in a control unit that is actually designed for checking the light bulb. The feed or There is no switching off of a simulation load to simulate an incandescent lamp addressed. In the diagnostic system known from DE 198 52 351 A1 instead, diagnostic information about the nature of the failure via the Supply line sent to the control unit.

The object of the invention is therefore that known from DE 201 15 409 U1 Develop lighting device in such a way that even if only a connecting line between the ballast and the lamp assembly at Failure of at least one LED reliably prevents the incandescent lamp simulation is and on the other hand continues to ensure a power supply to the lamp assembly is.

This object is achieved according to the invention by the features of claims 1 or 2 solved. Advantageous embodiments are in the Subclaims described.

The lamp arrangement has in addition to the Failure control circuit on a pulse generator, the failure of at least one LED in a certain time window as an error signal a current or Voltage pulse generated on one connecting line. In addition, the Ballast has a circuit for detecting the current or voltage pulse, which prevents the switchable load from being switched on when the pulse is detected. there has the circuit for detecting the current or voltage pulse in the ballast Control window has that with the time window for the generation of the current pulse is synchronized.

Since the status of the supply line is not permanently changed in the event of a fault, Example is set to low, but an error pulse only in a certain time window generated on the supply line, which leads to the simulation load being switched off the power supply to the lamp assembly can still be used safely.

The invention will be explained in more detail below with the aid of the accompanying drawings. It shows:

Fig. 1 is a block diagram of the lighting device

Fig. 2 is an LED lamp with failure control circuit according to the invention and pulse generator,

Fig. 3 shows the current curve on the connecting line between the ballast and LED lamp with error pulse,

Fig. 4 is a trailing means of pulse width modulation current characteristic of an incandescent lamp.

The lighting device according to the invention - see FIG. 1 - consists of a lamp arrangement which has at least one light-emitting diode, preferably an LED matrix. Such a lamp arrangement can be, for example, a lamp or a headlight. This lamp arrangement is now connected to a control device (for example a flasher unit) via a single connecting line, the current flowing from the control device to the lamp arrangement being measured by a current monitoring circuit in the control device for checking the function of the lamp arrangement. According to the invention, the lamp arrangement is now preceded by a ballast which is connected in the connecting line between the control device (not shown) and the lamp arrangement. The lamp arrangement has a failure control circuit for the at least one LED and a pulse generator. If at least one LED fails, the pulse generator generates a current or voltage pulse on the connecting line to indicate the fault to the ballast. The switchable load is located in the ballast with the aid of which the incandescent lamp, more precisely the current characteristic curve of an incandescent lamp, is simulated. The "simulation load" is switched on and off (ie activated) via a switch, preferably a semiconductor switch, which is controlled by a control and monitoring circuit arranged in the ballast. The current monitoring circuit in the control unit now does not directly measure the current that flows into the lamp arrangement, but rather the current that flows into the ballast. This is made up of the LED current of the lamp arrangement and the current through the load connected in parallel in the ballast, which simulates the current through an incandescent lamp. According to the invention, a circuit for detecting the error pulse generated by the pulse generator is also provided in the ballast. This detection circuit consists, for example, of a current measuring circuit which determines the fault current pulse via a shunt resistor and sends a corresponding signal to the control and monitoring circuit in the ballast. The control and monitoring circuit then prevents the load from being connected in the event of a fault. This means that no more incandescent lamp current is simulated and the current monitoring circuit in the control unit correctly detects an error in the lamp arrangement. The switchable load only has to generate a current flow at a height which corresponds to the difference between the incandescent lamp current to be simulated and the current into the lamp arrangement, since the current in the LED lamp arrangement is present as an offset anyway. In this context, the current measuring circuit in the ballast not only detects the fault current pulse, but also measures the current into the LED lamp arrangement.

The current pulse that is generated in the event of failure of at least one LED is in one generated certain time window during the flashing pulse, the detection circuit has a control time window in the ballast that coincides with the time window for generation of the residual current pulse is synchronized. If the detection circuit within the Control time window detects a fault current, the "simulation load" is no longer switched on. For example, it is provided in one embodiment, in the case of a Failure error 100 milliseconds after the start of the flashing pulse an error pulse of Generate 10 to 20 milliseconds duration. The first flash after a Failure errors are then still connected to the "simulation load". The detected Error pulse is however stored by the control and monitoring circuit, so that the activation of the "simulation load" is already stopped at the next flashing pulse and so on the error is recognized by the control unit / flasher unit. To the error information too during the flashing break, in which the ballast is also not using electrical energy is supplied in the control and monitoring circuit (e.g. a microcontroller) To be able to save, is in the ballast an electrolytic capacitor (not shown) as Supply buffer provided.

For failure control (see FIG. 2), for example, the currents through the parallel strands of the LED matrix are compared with one another. An error signal is only forwarded to the pulse generator if the currents do not match within a certain tolerance range because one LED has failed in one strand.

In order to simulate the current characteristic curve of an incandescent lamp, in particular the cold switch-on current peak, as well as possible (see FIG. 4), the ballast provides periodic activation of the switchable load (e.g. current sink), the pulse width (duty cycle: ratio of high level -time to low-level-time) of the control signal is modulated according to the current profile to be simulated. The duty cycle is higher at the start of the flashing pulse and then decreases continuously or in stages. The duty cycle at the beginning of the flashing pulse is preferably almost 100% and only 10% towards the end of the flashing pulse.

The lamp arrangement in the form of a lamp or a headlamp in which a LED matrix, a failure control circuit and a pulse generator located adjusts independent commercial product of the lighting device according to the invention. The same applies to the ballast in which the detection circuit for the Error pulse and the switchable load is located.

Claims (5)

1.Lighting device for vehicles with at least one light-emitting diode lamp arrangement ( 1 ) which is connected via a connecting line (VL) to a control unit for the power supply, the current flowing from the control unit to the lamp arrangement ( 1 ) flowing from a current monitoring circuit in the control unit for function control of the Lamp arrangement ( 1 ) is measured, wherein
the lamp arrangement ( 1 ) has a failure control circuit ( 10 ) for the at least one light-emitting diode and a pulse generator ( 11 ), the pulse generator ( 11 ) generating a current or voltage pulse on the connecting line (VL) if the at least one light-emitting diode fails,
the lamp assembly is upstream of (1) a ballast (2), which is connected into the connecting line (VL) between the control unit and the lamp assembly (1),
the ballast ( 2 ) has a switchable electrical load ( 20 ) that can be connected in parallel to the lamp arrangement ( 1 ), the current monitoring circuit in the control device for checking the function of the lamp arrangement ( 1 ) measures the current into the ballast ( 2 ),
the ballast ( 2 ) has a circuit ( 21 A, 21 B) for detecting the current or voltage pulse, the connection of the switchable load ( 20 ) being prevented when the pulse is detected,
the current or voltage pulse is generated in the event of a failure of the at least one light emitting diode in a specific time window, the circuit ( 21 A, 21 B) for detecting the current or voltage pulse in the ballast ( 2 ) having a control time window which corresponds to the time window for the Generation of the current pulse is synchronized. 2. Light or headlights for vehicles with at least one light emitting diode lamp arrangement ( 1 ) which is supplied with current via a connecting line (VL), characterized in that
the lamp or the spotlight has a failure control circuit ( 10 ) for the at least one light-emitting diode and a pulse generator ( 11 ), the pulse generator ( 11 ) generating a current pulse on the connecting line (VL) if the at least one light-emitting diode fails,
the current or voltage pulse is generated in the event of a failure of the at least one light emitting diode in a specific time window, which is synchronized with a control time window of a detection circuit ( 21 A, 21 B) in a ballast ( 2 ) connected upstream of the lamp or the headlight. 3. Ballast ( 2 ) for a lamp or a headlight according to claim 2, which is connected in the connecting line (VL), characterized in that
the ballast ( 2 ) has a switchable electrical load ( 20 ) which can be switched parallel to the lamp arrangement ( 1 ),
the ballast ( 20 ) has a circuit ( 21 A, 21 B) for detecting the current pulse, the connection of the switchable load ( 20 ) being prevented when the current pulse is detected. 4. Ballast according to claim 3, characterized in that the load ( 20 ) in the ballast ( 2 ) is controlled periodically and pulse width modulated, the pulse width of the control signal being modulated in time in accordance with a current profile to be simulated. 5. Lighting device according to claim 1, characterized in that the load ( 20 ) in the ballast ( 2 ) is controlled periodically and pulse width modulated, the pulse width of the control signal being modulated in time in accordance with a current profile to be simulated.