DE102014221666A1 - lighting device - Google Patents

Abstract

The invention relates to a lighting device for a vehicle having at least one semiconductor laser light source and at least one light wavelength conversion element which is adapted to at least partially convert light generated by the at least one semiconductor laser light source into light of other wavelength, wherein a monitoring device is provided, which is adapted to sensor signals be evaluated by a sensor device and to control the light emission of the illumination device in response to a result of the sensor signal evaluation.

Description

The invention relates to a lighting device according to the preamble of claim 1.

I. State of the art

Such lighting devices are for example in the publications DE 10 2011 075147 A1 . WO 2012/007027 A1 . DE 10 2010 011029 A1 and DE 10 2010 028949 A1 such as DE 10 2010 063921 A1 disclosed.

A safety concept of the LARP light function is based on two pillars, namely internal safety functions of the light sources (detection of escaping laser light by means of internal sensors, such as photodiodes) and a beam trap for masking unwanted laser light, which is arranged, for example, in a reflector.

The distance limit provided by the internal sensor system is typically at a value of X (e.g., 8 m) plus tolerance, and thus above the required distance value X. The reason for this is that the internal sensor technology of the light sources has some blurring in the uniqueness of the error case detection. The beam trap therefore has the task of ensuring the required laser safety class at a distance X in the NIO case. The guarantee of the safety class in the IO case has hitherto been regulated by the fact that the maximum luminance is limited as a function of the individual functionality of the light function (for example residual divergence angle). The term "IO case" refers to the healthy state of the LARP light source, and the term "NIO case" refers to the defective state of the LARP light source. The terms LARP function and LARP light source are defined later in the text.

The distance limit of a required safety class in the IO case is greater, the higher the luminance of the LARP light source (with the same downstream optics).

II. Presentation of the invention

It is an object of the invention to provide a generic illumination device which makes it possible to control the light emission of the illumination device as a function of an evaluation of sensor signals of a sensor device, which serves, for example, for detecting a traffic situation in front of a vehicle.

This object is achieved by a lighting device having the features of claim 1.

The illumination device according to the invention makes it possible to maintain the laser safety class 2 and the photobiological safety class for lamps of class 2 at a defined distance (for example 2 m) in front of the vehicle. The requirement is met both in the case of a faultless LARP light source of the illumination device according to the invention (IO case) and in the case of a faulty working LARP light source of the illumination device according to the invention.

The illumination device according to the invention has at least one semiconductor laser light source and at least one light wavelength conversion element which is designed to at least partially convert light generated by the at least one semiconductor laser light source into light of a different wavelength. In addition, the illumination device according to the invention has a monitoring device which is designed to evaluate sensor signals from a sensor device and to control the light emission of the illumination device as a function of a result of the sensor signal evaluation.

The illumination device according to the invention preferably makes possible a so-called LARP light function, where the abbreviation LARP stands for Laser Activated Remote Phosphor. The LARP light function is preferably ensured by means of a LARP light source plus downstream optics. The at least one semiconductor laser light source and the at least one light wavelength conversion element of the illumination device according to the invention are used as the LARP light source. The LARP light source, that is, the combination of the semiconductor laser light source and the light wavelength conversion element, preferably generates white light having Lambertian light distribution. Preferably, at least one laser diode emitting blue light is used in combination with a phosphor based on YAG: cerium (yttrium aluminum garnet doped with cerium), which proportionally converts the blue light emitted by the at least one laser diode into yellow light, so that the illumination device according to the invention emits white light which is a mixture of non-converted blue light and converted yellow light.

The downstream optics consists for example of a primary and secondary optics, wherein the primary optics is formed, for example, as part of the illumination device according to the invention and the secondary optics is formed for example as part of a vehicle headlamp, in which the illumination device according to the invention is used. The primary and secondary optics are, for example, a combination of optical lenses or reflectors or of optical lenses and reflectors.

The peak values of the luminances of the LARP light source are preferably in the range of greater than 200 cd / mm ² to 5000 cd / mm ² . The luminance can be distributed approximately homogeneously over the emission surface or similar to a Gaussian profile.

The minimum possible and maximum allowable light levels are in the UN ECE 123 regulated. Here a maximum light intensity of 215000 cd (light emission from the headlamp) is permitted.

The limits of permissible radiation with regard to laser safety are in the Standard ICE 60825 regulated.

The limits of permissible radiation with regard to photobiological safety are in the CIE S009 / IEC 62471 regulated.

The light function of the illumination device according to the invention is preferably a high-beam high-beam spot with narrowed divergence angle (e.g., +/- 3.5 ° horizontal, + -2 ° vertical).

In order to be able to increase the luminance of the light source without the use of the safety measure beam trap (advantage: smaller optics possible or higher light intensity possible), a more precise sensor system in the light source is necessary in the NIO case. However, the higher safety class then remains in the IO case with regard to the photobiological safety class.

In order to fulfill the distance X in front of the vehicle with respect to the required safety class, the LARP light source of the illumination device according to the invention is preferably coupled to the CAN bus in the vehicle, so that via CAN bus interface sensor signals from sensors that the apron in front of the vehicle monitor, the monitoring device of the illumination device for the purpose of evaluation, to control the light emission of the illumination device or the LARP light source in response to a result of the sensor signal evaluation.

The sensors of the vehicle apron (eg camera and / or ultrasound and / or lidar and / or proximity sensor and / or collision detector, etc.) can be objects in the vehicle apron in a certain distance range greater than Y (eg> 1m) and smaller Z (eg <20m) detect. By evaluating these signals (for example, an object in front of the vehicle at a distance of 5 m) in the LARP light source (control unit of the light source), the required safety class for each driving situation can be ensured, for example by dimming the light source to the required intensity in accordance with the object distance.

This advantage results both for the IO case and for the NOK case. That Thus, the safety of the light source can be realized without the necessary in comparison to the prior art beam trap, which causes significant light losses in the system.

In addition, this feature also allows the use of the light function at low speeds and / or even when stationary (necessary for ASIL B → full high beam or low beam using LARP).

In principle, the schemes described above are also applicable to LED and lamp based light sources.

1 shows a vehicle with two vehicle headlights, in each of which a lighting device according to the invention is used to generate the LARP light function. The two vehicle headlights or their lighting devices are each connected to the CAN bus (not shown) of the vehicle, for example, to transmit sensor signals to the monitoring device of the lighting devices and control signals (for example, to turn on, turn off and dimming) to the lighting devices.

Realization of the brightness control or light dimming:

• – Einstellung des Duty Cycles der Pulsweitenmodulation (PWM) des Betriebsstroms für die mindestens eine Laserdiode
• – Einstellung eines geringeren Stromes für die mindestens eine Laserdiode
• – Mechanische Ausblendung von Teilen des blauen Pumplichtstrahles oder des konvertierten weißen Lichts (mechanische Shutter oder Graufilter oder eines als Blende dienenden optischen Elements) innerhalb der LARP Lichtquelle oder innerhalb des Scheinwerfers
• – Verschieben von optischen Elementen innerhalb der LARP Lichtquelle derart, dass der Pumpstrahl defokussiert wird, so dass die Leuchtdichte reduziert wird
• – Verschieben von optischen Elementen innerhalb des Scheinwerfers derart, dass der Abstrahlwinkel vergrößert wird
• – Mechanisches Drehen des Abstrahlprofils (realisiert durch Drehung der Beleuchtungseinrichtung im Scheinwerfer) derart, dass das Zielobjekt nicht mehr angestrahlt wird
• – Einschalten von elekro-optischen aktiven Schichten auf der Reflektor-Beschichtung des Fahrzeugscheinwerfers zur Reduzierung der Lichtintensität.

The brightness control takes place, for example, by:

• - Setting the duty cycle of the pulse width modulation (PWM) of the operating current for the at least one laser diode
• - Setting a lower current for the at least one laser diode
• - Mechanical blanking of parts of the blue pumping light or the converted white light (mechanical shutter or gray filter or an optical element serving as a shutter) inside the LARP light source or inside the headlamp
• - Moving of optical elements within the LARP light source such that the pumping beam is defocused, so that the luminance is reduced
• - Moving of optical elements within the headlight such that the radiation angle is increased
• - Mechanical rotation of the emission profile (realized by rotation of the illumination device in the headlight) such that the target object is no longer illuminated
• - Switching of electro-optical active layers on the reflector coating of the vehicle headlight to reduce the light intensity.

The brightness control or dimming can be carried out separately for the right and left vehicle headlights.

Use of the emitted light itself as a distance measurement:

By means of transit time measurement (for example correlation method, detection of the phase position), for example, the emitted light itself will be used to detect a relevant danger object in the beam path.

In this case, a signal (PWM itself or further modulation signal) is impressed on the light-emitting signal and the backscattered light is measured by at least one photodiode.

The PWM frequency should be at least 100Hz.

The photodiode may be mounted in the LARP light source, the headlight or the vehicle front. The rise time of the photodiode must be very short (<0.1μs) to measure the runtime. Depending on the phase position of the correlation signal, the light intensity is dimmed. Dimming can also be caused by traffic signs and / or road markings. Then the dimming can serve to reduce the driver's self-glare.

The advantage of this method is that it is possible to precisely monitor the emitting cone of light.

Realization of signal transmission:

The signal transmission of the sensor system for monitoring the vehicle apron to the LARP light source can take place by means of a CAN interface, LIN interface, Ethernet, wireless or a proprietary protocol.

Alternatively, parts of this sensor technology can also be contained redundantly in the headlight or in the LARP light source or the illumination device according to the invention itself.

In the 2 and 3 a schematic diagram of the control of the illumination device according to the invention for the left and right vehicle headlamp is shown schematically. The sensor signals are transmitted to the on-board computer BCM of the vehicle for evaluation. In addition, the sensor signals are also evaluated in the LARP light source or in the illumination device according to the invention. The monitoring device for evaluating the sensor signals for the LARP light source is, for example, a component of the illumination device according to the invention or the on-board computer in the vehicle.

Variants:

Instead of blue light emitting laser diode and yellow light-generating light wavelength conversion element (also called converter) UV laser plus blue and yellow converter can be used, wherein blue and yellow converter can be formed separately or as a common converter (realized in a converter or mixture of two Channels blue and yellow).

Likewise, the combination of blue light generating laser plus yellow converter is possible (in one channel or mixture of two channels blue and yellow).

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102011075147 A1 [0002]
• WO 2012/007027 A1 [0002]
• DE 102010011029 A1 [0002]
• DE 102010028949 A1 [0002]
• DE 102010063921 A1 [0002]

Cited non-patent literature

• UN ECE 123 [0013]
• Standard ICE 60825 [0014]
• CIE S009 / IEC 62471 [0015]

Claims (2)

Lighting device for a vehicle having at least one semiconductor laser light source and at least one light wavelength conversion element, which is adapted to at least partially convert light generated by the at least one semiconductor laser light source in light of different wavelengths, characterized in that a monitoring device is provided, which is adapted to sensor signals from a sensor device to evaluate and control the light emission of the illumination device in response to a result of the sensor signal evaluation. Vehicle headlight with at least one illumination device according to claim 1.

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