This application is based upon and claims priority to German Patent Application DE 10 2013 206 488.8 filed on Apr. 11, 2013.
1. Field of the Invention
The present invention relates generally to a light module of a lighting equipment of a motor vehicle and, more specifically, to lighting equipment having one or several light modules.
2. Description of Related Art
Various approaches are known in the art for implementing glare-free high beam without the use of variable speed motors by utilizing special light modules designed as projection systems. To this end, intermediate images are generated from several semiconductor light sources (for example, LEDs) with a primary optics array. Using a lens system, the intermediate images are projected on the road in front of the vehicle so as to generate the resulting light distribution of the light module. For example, such a light module is known from DE 2008 013 603 A1.
Currently, projection modules generate light-dark boundaries as well as dark-light boundaries. Specifically, it is not specified which side of the road should be illuminated. As such, single-lens projection systems can be used only to a limited extent because of their color aberrations. For example, to solve this problem, DE 10 2010 029 176 A1 proposes using achromatic, two-lens systems.
In lens systems, the problem of a chromatic aberration can be avoided by using a reflector as secondary or projection optics. Unlike lens systems, reflector systems have no aberrations, can be produced in a simple and cost-effective manner (especially when large optical areas are required), and do not cause any stray light through Fresnel reflections. However, reflector systems have the disadvantage of developing aperture distortions in larger numeric apertures (for example, different reflector zones have different extensions). Furthermore, in reflector systems, off-axis rays result in a displacement (referred to in the art as “coma”). As a result, a square light source is not represented as a square but rather in the deformed shape of a trapeze or mushroom, wherein size, position and orientation of the image largely depend on the position of the light source in the object field. However, a system generating from multiple semiconductor light sources and having several straight, strictly limited light distributions with definite positions of the individual light-dark boundaries inherently includes imaging properties. Thus, an appropriate total light distribution of a light module needs to be constructed or composed of light source images of the same size and orientation.
In addition, matrix high beam modules known in the art usually use single-chip LEDs, especially SMD (surface mounted device) LEDs in conjunction with a primary optics array. The primary optics array generates intermediate images on the light emitting surfaces of the primary optics elements of the optics array, which are then projected on the road by the secondary optics located downstream in the beam path. Due to the distances between the LEDs, the areas of the intermediate images (referred to in the art as “pixels”) are large, which necessitates using projection lenses with great focal width. Consequently, the resulting light modules are relatively large, which is disadvantageous in motor vehicles because of the relatively limited installation space available for the light modules or the lighting equipment provided with these light modules.
With regard to prior art, in addition to the two above-mentioned publications, reference is also made to the following publications: DE 10 2008 005 488 A1, DE 10 2007 052 742 A1, DE 10 2009 053 581 B3, DE 10 2010 023 360 A1, EP 2 045 515 A1, EP 2 388 512 A2, U.S. Pat. No. 6,758,582 B1 and U.S. Pat. No. 7,055,991 B2.
It is the object of the present invention to provide a light module for generating a resulting total light distribution from the light of matrix-like light sources in such a way that an especially homogenous total light distribution is achieved while, at the same time, providing light module having a compact size and short length. Moreover, by switching (selectively switching on and off) the different light modules, it is possible to switch between the different adjacent intermediate light distributions on the light emitting surfaces of the primary optics elements in order to obtain a glare-free high beam as resulting total light distribution. In operation, the projections of one or several intermediate light distributions are selectively removed from the areas of the total light distribution where other road users are located.
The present invention is directed toward a light module of a lighting equipment of a motor vehicle including a light source assembly with multiple separately controllable light sources combined to an array for emitting light, multiple primary optics elements combined to a primary optics array in the form of collective lenses each of which has a light ingress surface, and a light-emitting surface wherein the primary optics elements are designed to concentrate at least a portion of the light emitted by the light sources and to generate intermediate light distributions on the light emitting surfaces. Further, the invention includes secondary optics system for reproducing the emitted light on a road in front of the motor vehicle as resulting total light distribution of the light module, wherein the secondary optics system for reproducing the intermediate light distributions on the road in front of the motor vehicle as resulting total light distribution of the light module is focused at least on one of the light-emitting surfaces of the collective lenses.
The light module includes several primary optics elements combined to the primary optics array, in which each primary optics element has a light ingress surface and a light emitting surface. The primary optics elements are designed for concentrating at least a portion of the light emitted by the light sources and for generating intermediate light distributions on the light emitting surfaces of the primary optics elements. The secondary optics system is focused on the reproduction of the intermediate light distributions on the road in front of the motor vehicle as resulting total light distribution of the light module on at least one of the light emitting surfaces. It is possible that the secondary optics has not only one focal point but multiple focal points, wherein several of the focal points can be focused on several of the light emitting surfaces. Therefore, it is required (and in practice, difficult to implement) that the focal point or focal points of the secondary optics are focused on the light emitting surfaces of all primary optics elements.
Consequently, the light module includes a semiconductor light source array, as well as a primary optics array, wherein the intermediate light distributions generated on the light-emitting surfaces of the optics array are projected on the road by the secondary optics system. Therefore, not reproductions of the light sources but only illuminated areas are projected on the road. Subsequently, the combination of light source array and primary optics array is also depicted as substitute light source array. A light source and the attached primary optics array is also depicted as substitute light source, wherein several substitute light sources can be arranged to an array directly next to each other or above each other. At the same time, the primary optics elements arranged next to each other in one or several lines form the primary optics array. Usually the primary optics elements are larger than the light sources respectively attached to the primary optics elements, resulting in relatively large distances between the individual light sources of a substitute light source array.
Compared with conventional projection systems, in the invention-based light module, the collective lenses in the Petzval surface of the object-side secondary optics do not generate reproductions of the light sources. In the invention-based light module, only the light-emitting surfaces of the collective lenses are illuminated. The secondary optics is focused on one or several of these illuminated areas. On the light-emitting surfaces, the collective lens array includes a plane luminance without maxima. Specifically, this applies to the light distribution in the sections extending vertically to the light-dark boundaries or pixel limits. As such, the secondary optics focuses on the exit pupil of the primary optics array.
Advantageously, compared with conventional projection systems, in an invention-based light module the formation of the light distribution (for example, the vertical and/or horizontal course of the pixels) is performed at least partially by the secondary optics in order to implement the total light distribution. In one embodiment, the formation of the light distribution is performed completely or almost completely by the secondary optics. In particular, this is possible with a primary optics array in the form of a collective lens array because here no important luminance differences can be generated in the exit pupil of the primary optics. At the same time, light shaping can be performed almost completely by, for example, toric secondary optics.
Advantageously, the light sources are designed in the form of semiconductor light sources, especially in the form of LED light sources, LED arrays, single chip LEDs or SMD LEDs.
In various embodiments of the invention, the secondary optics can be designed: in the form of a parabolic reflector, especially a faceted parabolic reflector; in the form of a collective lens, especially an aplanatic collective lens; in the form of an achromatic system with a combination of a collective lens having minor color dispersion and a dispersing lens having major color dispersion; in the form of a combination of a hyperbolic reflector and a collective lens, wherein an object-side focal point of the collective lens coincides with an image-side focal point of the hyperbolic reflector; or in the form of a combination of an elliptic reflector and a dispersing lens, wherein an object-side focal point of the dispersing lens coincides with an image-side focal point of the ellipsoid reflector.
Further, the primary optics array can be designed: in the form of a collective lens array, especially an array having plano-convex lenses, advantageous is a lens array with toric lens surfaces; in the form of a reflector array, especially with polygonal cross-sectional areas, particularly with square, rectangular, or triangular reflector cross-section, where thee reflector areas may be designed as plane minor surfaces or cylindrical hyperboloid surfaces; in the form of a light conductor array, wherein the individual light conductors may be designed as conical light conductors with a cross-sectional area that is increasing from its light ingress surface toward its light-emitting surface wherein the light conductors may have a polygonal cross-section (such as triangular, rectangular, or square), with a light ingress surface of a light conductor designed as a plane surface and arranged orthogonal to the primary beam direction of the attached semiconductor light source, in particular parallel to the surface extension of a semiconductor chip, where a light-emitting surface of a light conductor may have a convex curvature; in the form of a light conductor array with multiple disc-shaped light conductors wherein each of the light conductor discs includes a light ingress surface, a light-emitting surface, a reflector area and two transport areas on which light coupled into the light conductor is transported via total reflection to the light-emitting surface, where the reflector area may be located between the light ingress and light-emitting surfaces, where the light ingress and light-emitting surfaces may form together with the reflector area two focal lines which are subject to the figure law such that the optical paths between the object-side and the image-side focal line have the same optical path lengths: the sumi (si×ni)=constant.
When using two-piece or multi-piece optics, the image-side focal point which prepends the primary optics in beam direction coincides with the object-side focal point of the subsequent secondary optics. Both optics have equal optical axes (rotation axes of lenses and reflectors). A secondary optics with multiple reflectors or mirrors connected in series makes it possible to fold the beam path, thus considerably reducing the structural length of the light module.
In one embodiment, the focal point of the secondary optics is situated on a light-emitting surface of the substitute light source array and reproduces it on the road. In order to achieve high imaging quality, the secondary optics is designed in such a way that all optical paths between the focal point and the (infinitely distant) pixel have the same length. For example, when using reflectors as primary optics and/or secondary optics (paraboloid, hyperboloid or ellipsoid reflectors), this is achieved as discussed below.
The light source or substitute light source array may radiate at an acute angle into the reflector against driving direction of the motor vehicle or in transversal direction (for example, the beam path is folded by the reflector at an acute angle). Furthermore, the reflector may be facetted in such a way that all faceted surfaces have almost the same distances to a mutual focal point of the reflector. All facet edges facing away from the optical axis (rotation axis) of the light module have larger distances to the mutual focal point of the reflector than the internal facet edges located on the side of the optical axis. Further, the facet edges may extend in vertical direction to the light-dark boundaries of the resulting total light distribution (for example, vertical light-dark boundary at the strip beam→horizontal facet edges). It is also advantageous to use annular reflector facets arranged concentrically about the optical axis.
The subsequent list provides different combinations of light sources, primary optics and secondary optics. All combinations included in the subject matter of the present invention are marked with an X. Those combinations which represent an interesting solution from a technical viewpoint or from the aspect of being achievable are marked with X′:
Further characteristics and advantages of the present invention are included in the following description with reference to the figures. At the same time, the invention-based light module can have the characteristics and advantages mentioned with regard to the different embodiments also on an individual basis or in any combination different from the combinations described in the embodiments, wherein:
The present invention relates to a light module which is depicted in its entirety in the figures and which has the reference numeral 1. The light module 1 is intended to be installed in lighting equipment of a motor vehicle. The lighting equipment may be designed as a motor vehicle headlamp. However, it can be designed also as a motor vehicle lamp. Typically, the lighting equipment includes a housing with a light emitting aperture which is closed by a transparent cover panel. The light module 1 can be arranged in the housing in rigid or flexible manner. By moving the light module 1 relative to the housing, it is possible to provide headlamp range adjustment and/or adaptive headlight function. It is possible to install in the housing multiple invention-based light modules 1. However, it is also possible to install in the housing the invention-based light module 1 in conjunction with light modules that are not based on the present invention.
The invention-based light module 1 includes a light source array 15 (see
In one embodiment, the secondary optics 4 focuses on the light-emitting surfaces 25 of the substitute light source array 2 or the primary optics elements 18. In the light module 1, the intermediate light distributions generated by the light sources on the light-emitting surfaces 25 of the primary optics array 17 may be combined in such a way that the individual light distributions 6′ are at least partially superimposed or added and thus form the resulting total light distribution 5 of the light module 1. For example, the total light distribution 5 is a so-called glare-free high beam. In the invention-based light module 1, the secondary optics 4 reproduces on the road only the intermediate light distributions on the light-emitting surfaces 25 of the primary optic elements 18 (for example, the illuminated surfaces 25) and not the images of the light sources 16. In this way, the secondary optics 4 is not focused on images of the light sources 16 but on the light-emitting surfaces 25 of the primary optics elements 18.
The LED chip 16 is located between the lens 18 and its object-side focal point F. The LED chip 16 is enlarged by the lens 18 in such a way that the (upright) virtual image 16′ of the chip (in light-emitting direction in front of the object-side focus of the lens F) has almost the same size as the lens 18 (for example, B′LED˜T). The following combinations apply to the indicated approximate sizes:
The collective lenses 18 of the lens array 17 do not have the purpose of generating real intermediate images of the light sources 16, but form only an illuminated surface on the light-emitting side 25 of the collective lenses 18. The light sources 16 are arranged between the light ingress surfaces of lenses 18 and the object-side focal points F of the lenses 18 in such a way that the edges of the light sources 16 are located on geometric connections between the focal points F and the lens edges. The light-emitting surfaces of the light sources 16 are arranged perpendicularly to the optical axes of the lenses 18. This results in a very even illumination of the lenses 18 and an especially homogeneous light distribution, the so-called intermediate light distribution, on the light emitting surfaces 25 of the lenses 18. With the secondary optics array 4, the intermediate light distributions are reproduced on the road in front of the vehicle for generating the resulting total light distribution of the light module 1. The optical axes of the individual lenses 18 of the array all run in one plane, and advantageously run parallel to each other. On the side facing the primary optics 17, the axis of the secondary optics 4 runs parallel to the axis of at least one of the lenses 18.
In the example shown, the secondary optics system 4 is designed in the form of a horizontally facetted reflector, especially a parabolic reflector. Thus, in a vertical section the reflector 4 includes several facets arranged on top of each other. The secondary optics system 4 focuses on the light-emitting surfaces 25 of the primary optics elements 18 or the substitute light source array 2. A resulting total light distribution 5 of the light module 1 is represented in an exemplary manner on a measuring screen 6 which is arranged in a definite distance to the light module 1. The total light distribution 5 includes a plurality of individual light distributions 6′ which are generated by the individual elements 16, 18 of the substitute light source array 2 in interaction with the secondary optics system 4.
Furthermore,
In
In the embodiment shown in
Furthermore,
The reflectors 18 expand in conical fashion from light entry to light exit 25. Vertically to an optical axis 23 or to the primary beam direction 29 of the light sources 16 (see
The individual light conductors 18 may have a convex curved light-emitting surface 25. The light conductor array 17 includes organic or inorganic glass or of silicone rubber (LSR). For example, organic glasses include PMMA, COC, COP, PC, PSU or PMMI. The light-emitting surfaces 25 of the conical light conductors 18 follow the course of a Petzval surface of the secondary optic system 4 and are thus located on a convex curved disc (when the projection optics 4 comprises a reflector) or on a concave curved disc (when the projection optics 4 comprises a lens).
In the example shown in
In
The secondary optics system 4 of the invention-based light module 1 may also include a collective lens which is focused on the light-emitting surfaces 25 of the primary optics elements 18. The collective lens can be designed in the form of a toric (astigmatic) collective lens which includes different sheet strengths in the meridian and sagittal section 8, 9. Furthermore, the collective lens can be designed also in the form of an astigmatic collective lens. Finally, the secondary optics system 4 may also include a color-correcting two-lens system (achromatic): a collective lens with minor color dispersion and a dispersing lens with major color dispersion.
In the embodiment of an invention-based light module 1 shown in
As described above,
The embodiment shown in
In the embodiment shown in
Referring to the embodiments shown in
The hyperboloid reflector 4′, 4′″ can also have a faceted design. In the hyperboloid reflector 4′, 4′″, the image 21′ of the object-side focal point 21 is not located in the infinite. Therefore, the arrangement of the reflector facets would differ from a spherical surface. The facets may be arranged in such a way that the respective distances to the object-side and image-side focal points (hyperbolic: virtual image) for all reflector facets are as equal as possible, making it possible to achieve for all reflector zones the most equal reproduction scales.
As shown in the embodiment of the invention-based light module 1 shown in
In the embodiment shown in
The ellipsoid reflector 4′″″ may be designed in the form of a faceted ellipsoid, especially with horizontal faceting. In the ellipsoid reflector 4′″″ the image 32 of the object-side focal point 31 is not located in the infinite. The arrangement of the reflector facets differs therefore from a spherical surface. The facets may be arranged in such a way that the respective distances to the object-side and image-side focal points (ellipse: real image) for all reflector facets are as equal as possible, making it possible to achieve for all reflector zones the most equal reproduction scales. The secondary optics system 4 has a mutual optical axis 7 and includes multiple mirrors and/or lenses which provide no sharp, undistorted intermediate image 2′ of the substitute light source array 2. However, in the sum, they have an object-side focal point 31 which is reproduced in an image-side focal point in the infinite. As a result, the optical system 1 is also subject to the figure law according to which all optical paths between the two focal points are equal in length: sumi (si×ni)=constant, wherein si the respective path of the optical path I and ni, respectively, represents the refractive indices of the different media traversed (n1=n2=n4=1 for air; n3≠1 corresponding to the material of the lens 4″″″).
With the invention-based light module 1, it is intended to implement in the lighting equipment dynamic curve lighting, partial upper beam, marker lights and the like as resulting total light distribution 5 through well-directed activation and deactivation of individual light sources 16 or groups of light sources 16 without mechanically movable parts. However, alternatively or in addition to the well-directed activation or deactivation of light sources 16 for generating dynamic curve lighting, partial upper beam, marker lights as resulting total light distribution 5, or optionally for adjusting the light-dark boundary, it is also possible to swivel the light module 1, including of the light source array 15, the primary optics array 17, and the secondary optics system 4, in motor-controlled manner about a vertical and/or horizontal axis. As a result, it is possible, for example, to swivel dynamic curve lighting into the curve. Partial upper beam includes high beam distribution which selectively cuts out specific areas in which other road users are present. To be able to follow a motion of the other road users in relation to the motor vehicle equipped with the light module 1, it is possible to swivel in horizontal manner the light module 1 about the vertical axis so that the area omitted by the high beam distribution follows the actual position of the other road users. A marker light includes dimmed light distribution with a horizontal light-dark boundary, wherein selectively at least a very limited area above the light-dark boundary is illuminated in order to illuminate other road users or objects in this area and to draw the attention of the driver with the motor vehicle equipped with the light module 1 to these other road users or objects. To be able also in this case to follow a motion of the other road users or objects in relation to the motor vehicle so that the illuminated very limited area above the light-dark boundary is directed to the other road user or object, the light module 1 can be designed in such a way that it can be swiveled in horizontal manner about the vertical axis. For the purpose of adjusting a vertical light-dark boundary, the light module 1 can also be swiveled in horizontal manner about the vertical axis and be fixed in the adjusted position.
Also for adjusting a horizontal light-dark boundary, the light module can be swiveled in vertical manner about a horizontal axis and fixed in the adjusted position. The adjusted position of the light-dark boundary then forms the zero point for an adaptive headlight function and/or headlight range adjustment function to be performed during the process of operating the light module 1.
The invention has been described in an illustrative manner. It is to be understood that the terminology which has been used is intended to be in the nature of words of description rather than of limitation. Many modifications and variations of the invention are possible in light of the above teachings. Therefore, within the scope of the appended claims, the invention may be practiced other than as specifically described.
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