AT503580A4 - SUPPLY OPTICS SYSTEM FOR A LED LIGHT UNIT FOR MOTOR VEHICLES - Google Patents

Description

P10123

Front optics system for a LED light unit for motor vehicles

The invention relates to an attachment optics system for a LED light unit for motor vehicles, wherein the LED light unit comprises at least two LED light sources, and wherein each LED light source has at least one light emitting diode, and further provided for each LED light source in each case at least one attachment optics is.

Furthermore, the invention relates to an LED light unit for motor vehicles, wherein the LED light unit comprises at least two LED light sources, and wherein each LED light source has at least one light emitting diode, and further for each LED light source in each case at least one optical attachment is provided.

In addition, the invention also relates to an LED light unit for motor vehicles, wherein the LED light unit comprises at least two LED light sources, and wherein each LED light source has at least one light emitting diode, and further for each LED light source in each case at least one attachment optics is provided, and wherein at least two LED light sources radiate light away from one another with main emission directions via at least one reflector into the outer space of the light unit for generating a first light distribution, wherein at least one further LED light source is provided, which light with a different from the first two main emission directions beam direction radiates through a lens in the outer space of the light unit

Finally, the invention also relates to a vehicle headlight with at least one of the above-mentioned LED light units.

In order to achieve headlights for motor vehicles whose light image is generated by light emitting diodes, the necessary light levels, it is often necessary to use multiple LED light sources. The light sources are mounted on a light source mounting element, which also serves as a heat sink for the LEDs. The light from the light sources is decoupled via its own, separate attachment optics for each of the light sources and possibly radiated via a reflector surface in the outer space.

When assembling this arrangement consisting of LED light sources, attachment optics and possibly reflector complicated, time-consuming and costly adjustment work are necessary due to the large number of components in order to realize a legally prescribed and / or optimal photo. -2-

It is an object of the invention to enable a much simpler adjustment of the individual light images of the LED light sources.

This object is achieved with an attachment optics system mentioned in the introduction, in which, according to the invention, the attachment optics of the LED light sources are firmly connected to one another via a carrier element.

By connecting the attachment optics with each other, the number of lighting components to be adjusted decreases significantly, so that the adjustment is much easier.

Under " Carrier " is basically an arbitrary element to understand, with which it is possible to arrange the attachment optics in mutually fixed positions.

In a particularly easy and accurate to implement intent optical system, the attachment optics are integrally formed with the carrier.

Furthermore, it is for a simple and cost-effective production of advantage if the attachment optics and / or the carrier are formed of a translucent plastic. In addition, in this case, the optical attachment system only has a low weight, and when using a transparent plastic, it is also possible to form the attachment optics with the carrier in one piece.

In principle, in the attachment optics system, the support can however also be formed separately from the attachment optics and can have receptacles or holding means for receiving or holding the attachment optics.

In order to allow a simple and exact positioning of the carrier with respect to the LED light sources, in a concrete optical attachment system, the carrier has positioning means for positioning the carrier with respect to the LED light sources.

For example, these positioning means may simply be one or more openings or recesses, such as e.g. Slots in the carrier, in which corresponding projections, e.g. Pins which are arranged and fixed to a light source mounting member to which the LED light sources are fastened, are inserted or on which pins the slots are struck.

In order to further enable accurate positioning of a prismatic reflector, in the optical system according to the invention, the carrier has reflector positioning means for positioning the carrier with respect to a reflector, via which at least one of the light sources in operation light in the Outside space radiates.

The above-mentioned object is also achieved with an above-mentioned light unit, in which according to the invention the front optics of the individual LED light sources are connected to one another via a carrier element to a front optical system as described above.

In order to be able to easily generate a cornering light with such an LED light unit, it is provided that, with at least one of the LED light sources, there is essentially a front-end illumination in the light image of a low-beam light unit.

In this case, the at least one LED light source for generating substantially the apron illumination in the light image of a low-beam light unit emits light via at least one reflector into the outer space of the low beam light unit.

In addition, it is provided that with at least one of the LED light sources substantially the generation of the asymmetry component takes place in the light image of a low beam headlamp

In order to be able to easily realize the legal requirements for the light image, it is provided that the at least one LED light source for generating essentially the asymmetry component in the light image emits light through a lens into the outer space of the light unit.

It is particularly favorable if the lens is pivotable about a substantially vertical axis. In this way, simply a cornering light can be generated.

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

1 is a view of a vehicle headlamp according to the invention with two LED light units according to the invention,

2 shows the vehicle headlight from FIG. 1 with the reflector removed in one of the LED light units, FIG.

3 shows a light source mounting element with LED modules, -4-

FIG. 4 shows the light source mounting element from FIG. 3 with attachment lens system according to the invention fastened thereto in a first view obliquely from the front, FIG.

5 shows the light source mounting element of FIG. 4 in a further view obliquely from behind,

6 shows a front optical system according to the invention in detail,

7 is a schematic representation of the connection of a reflector with the optical attachment system of FIG. 6,

8 shows a reflector for a light unit according to the invention in a rear view,

9 shows the reflector from FIG. 8 with attachable optical system attached thereto, FIG.

10 shows the reflector from FIG. 9, in addition to the light source mounting element, FIG.

Fig. 11 light source mounting element with optical attachment system in a plan view, and Fig. 12 shows an LED module in detail.

FIGS. 1 and 2 show by way of example a vehicle headlight SCH with two LED light units LEH for generating a low beam.

Each LED light unit LEH in this example comprises three LED light sources UQ1, LIQ2, LIQ3, each LED light source LIQ1, LIQ2, LIQ3 in this example having four light emitting diodes LI-L4. The light-emitting diodes LI-L4 are each arranged on an LED module. FIG. 12 shows, by way of example, such an LED module MODI in detail with the four light-emitting diodes LI-L4. Furthermore, for each LED light source LIQ1, LIQ2, LIQ3, at least one (in this example and usually exactly one) attachment optics VOP1, VOP2, VOP3 is provided in each case. In principle, it is also possible that a light source consists of several modules.

The LED modules MOD1, MOD2, MOD3 are mounted on a light source mounting element BLC, which simultaneously serves as a heat sink for the light-emitting diodes (see FIGS. 2 and 3).

Two LED light sources LIQ1, LIQ3 of a light unit LEH emit light from each other PI0123 PI0123

directed away with main emission directions AS1, AS3 via a reflector REF in the outer space of the light unit LEH for generating a first light distribution. In this example of dipped-beam units, these two light sources LIQ1, LIQ3 essentially provide the apron illumination in the light image of a dipped-beam light unit (FIG. 11).

A further LED light source LIQ2 emits light with a main emission direction AS2 different from the first two main emission directions AS1, AS3 through a lens LIN into the outer space of the light unit LEH (FIG. 11).

This LED light source LIQ2 is essentially used to generate the asymmetry component in the light image of a low beam headlamp. It is particularly advantageous if, as shown, the lens LIN is pivotable about a substantially vertical axis VAC. In this way, simply a cornering light can be generated.

The attachment optics VOP1, VOP2, VOP3 of the LED light sources LIQ1, LIQ2, LIQ3 are fixedly connected to each other via a carrier element TRA to a front optics system VOS.

By connecting the attachment optics with each other, the number of lighting components to be adjusted decreases significantly, so that the adjustment is much easier.

In the example shown, the attachment optics VOP1, VOP2, VOP3 are formed integrally with the carrier TRA. The attachment optics VOP1, VOP2, VOP3 and the carrier TRA are made of a translucent plastic

In order to enable a simple and exact positioning of the carrier TRA with respect to the LED light sources IIQ1, LIQ2, LIQ3, in the shown intent optical system VOS the carrier TRA has positioning means POM1, POM2 for positioning the carrier TRA with respect to the LED Light sources LIQ1, OQ2, LIQ3 on.

For example, these positioning means POM1, POM2 may simply be one or more apertures POM1 or recesses, e.g. Slots FOM2 in the carrier TRA, in which corresponding projections, e.g. Pins POMT, POM2 ', which are on the light source mounting member BLC, arranged and fixed, inserted into which pins or POM2' the slots POM2 'are struck (Figures 3-6). P10123 • t · ♦ ········

In order to further enable an exact positioning of the reflector REF, in the illustrated optical attachment system VOS, the carrier TRA has reflector positioning means PRO for positioning the carrier TRA with respect to the reflector REF.

In the example shown, the reflector positioning means PRO are two legs (FIG. 7) which engage in corresponding guides PRO 'on the rear side of the reflector REF (FIGS. 7-11).

In addition, as can be seen in FIG. 3, the mounting element BLC also has two positioning elements ABR for the exact positioning of the reflector REF with respect to the mounting element BLC. With these positioning elements ABR, the reflector REF is spatially (i.e., in depth) positioned.

On the one hand, these positioning elements ABR serve as spacers, on the other hand, their arrangement also prevents tilting of the reflector REF.

The reflector REF can furthermore also have two recesses (as counterparts to the positioning elements) into which the positioning element ABR lockingly engages and further restrict the possible positions of the reflector REF with respect to the mounting element BLC.

Finally, it should be noted that, of course, in principle, the positioning could also be formed on the reflector, and optionally the recesses are formed in the mounting element BLC.

Vienna, jjj. Time 2006

Claims (18)

P10123 •··················································································································································································· A superimposed optics system (VOS) for a motor vehicle LED light unit (LEH), the LED light unit (LEH) comprising at least two LED light sources (LIQ1, LIQ2, LIQ3), and each LED light source (LIQ1, LIQ2, LIQ3) at least one light-emitting diode (LI - L4), and further for each LED light source (LIQ1, LIQ2, LIQ3) each at least one attachment optics (VOP1, VOP2, VOP3) is provided, characterized in that the attachment optics (VOP1 , VOP2, VOP3) of the LED light sources (LIQ1, LIQ2, LIQ3) are firmly connected to one another via a carrier element (TRA). 2. optical attachment system according to claim 1, characterized in that the attachment optics (VOP1, VOP2, VOP3) are formed integrally with the carrier (TRA). 3. optical attachment system according to claim 1 or 2, characterized in that the attachment optics (VOP1, VOP2, VOP3) and / or the carrier (TRA) are formed from a translucent plastic. 4. optical attachment system according to claim 1, characterized in that the carrier is formed separately from the attachment optics and has receptacles or holding means for receiving or holding the attachment optics. A head optical system according to any one of claims 1 to 4, characterized in that the carrier (TRA) comprises positioning means (POM1, POM2) for positioning the carrier (TRA) with respect to the LED light sources (LIQ1, LIQ2, LIQ3) has. 6. Auxiliary optics system according to one of claims 1 to 5, characterized in that the carrier (TRA) reflector positioning means (PRO) for positioning the carrier (TRA) with respect to a reflector (REF), via which at least one of the light sources ( LIQ1, LIQ3) emits light into the exterior during operation. 7. LED light unit (LEH) for motor vehicles, wherein the LED light unit (LEH) at least two LED light sources (LIQ1, LIQ2, LIQ3) tunes, and wherein each LED light source (LIQ1, LIQ2, LIQ3) at least one light emitting diode ( LI - L4), and further for each LED light source (LIQ1, LIQ2, LIQ3) each at least one optical attachment (VOP1, VOP2, -8- VOP3) is provided, characterized in that the auxiliary optics (VOP1, VOP2, VOP3) the individual LED light sources (LIQ1, LIQ2, LIQ3) are firmly connected to one another via a carrier element (TRA) to form a front optical system (VOS) according to one of claims 1 to 6. 8. LED light unit according to claim 7, characterized in that at least one of the LED light sources (LIQ1, LIQ3) is essentially an apron illumination in the light image of a low beam light unit. 9. LED light unit according to claim 8, characterized in that the at least one LED light source (LIQ1, LIQ3) for generating substantially the apron illumination in the light image of a low beam light unit via at least one reflector (REF) in the outer space of a Low beam light unit emitted. 10. LED light unit according to claim 8 or 9, characterized in that at least one of the LED light sources (LIQ2) is substantially the generation of the asymmetry component in the light image of a low beam headlamp. 11. LED light unit according to claim 10, characterized in that the at least one LED light source (LIQ2) for generating substantially the asymmetry component in the light image emits light through a lens (LIN) in the outer space of the light unit. 12. LED light unit according to claim 11, characterized in that the lens (LIN) about a substantially vertical axis (VAC) is pivotable. 13. LED light unit according to one of claims 9 to 12, characterized in that on the at least one reflector (REF) and / or on a light source mounting element (BLC) for mounting one or more of the LED light sources (LIQ1, LIQ2 , LIQ3) positioning means (ABR) for positioning the reflector (REF) with respect to the light source mounting member (BLC) are provided. 14. LED light unit (LEH) for motor vehicles, wherein the LED light unit (LEH) comprises at least two LED light sources (LIQ1, LIQ2, LIQ3), and wherein each LED light source (UQ1, LIQ2, LIQ3) comprises at least one LED ( LI-L4), and furthermore for each LED light source (LIQ1, LIQ2, LIQ3) at least one attachment optics (VOP1, VOP2, 1 P10123 ··· t ································································). ···· * * ······················································································································································································ Light sources (LIQ1, LIQ3) radiate light away from one another with main emission directions (AS1, AS3) via at least one reflector (REF) into the outer space of the light unit (LEH) to produce a first light distribution, characterized in that at least one further LED light source ( LIQ2) is provided, which light with one of the first two main radiation directions (AS1, AS3) different Hauptabstrahlrich-device (AS2) through a lens (LIN) radiates into the exterior of the light unit (LEH). 15. LED light unit according to claim 14, characterized in that the lens (LIN) about a substantially vertical axis (VAC) is pivotable. 16. LED light unit according to claim 14 or 15, characterized in that the two first main emission directions (AS1, AS3) enclose an angle of 180 ° to one another and the third main emission direction (AS2) of the further LED light source (LIQ2) normal to the two first main radiation directions (AS1, AS3) is. 17. LED light unit according to one of claims 14 to 16, characterized by a front optical system (VOS) according to one of claims 1 to 7. 18. A vehicle headlamp (SCH) with at least one LED light unit (LEH) according to one of claims 7 to 17. Vienna, the J 2 »M 31