奥地利专利AT519453A4 Laser module and laser source arrangement for a vehicle headlight

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专利摘要:
A laser module (11) comprises a module body (21) with a head part (24, 44) in which a laser source (20) with a laser diode and associated collimator optics are fixedly mounted in a receiving space (22). The head part (24) forms a joint part of a ball joint with at least one joint surface (25); a second joint part (30) with a corresponding joint surface (35) belongs to a bearing component (31) for the laser module (11). The adjustment of the alignment of the laser source (20) is effected by adjusting the laser module (11) as a whole in the ball joint bearing formed by the two joint parts, and the adjustment thus achieved can be fixed by a permanent attachment, preferably by means of spot welding.
公开号:AT519453A4
申请号:T50254/2017
申请日:2017-03-30
公开日:2018-07-15
发明作者:Mayer Matthias
申请人:Zkw Group Gmbh；
IPC主号:

专利说明:

Summary
A laser module (11) contains a module body (21) with a head part (24, 44), in which a laser source (20) with a laser diode and associated collimator optics are fixedly mounted in a receiving space (22). The head part (24) forms a joint part of a ball joint with at least one joint surface (25); a second joint part (30) with a corresponding joint surface (35) belongs to a bearing component (31) for the laser module (11). The alignment of the laser source (20) is adjusted by adjusting the laser module (11) as a whole in the ball joint bearing formed by the two joint parts, and the adjustment thus achieved can be fixed by permanent attachment, preferably by means of spot welding.
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Laser module for a vehicle headlight
The invention relates to a laser module for a vehicle headlight, with a laser light source, preferably a laser diode, and an optical system assigned to the laser light source, comprising at least one collimator. The invention further relates to a laser source arrangement for a vehicle headlight with a laser module and a bearing component for mounting the laser module. The invention also relates to a light module that contains a number of this laser source arrangement and a vehicle headlight with a light module and / or laser source arrangements of this type.
The use of laser light sources in motor vehicles, in particular for headlights of motor vehicles, has currently gained in importance, since laser diodes enable more flexible and efficient solutions, as a result of which the luminance of the light bundle and the light yield can also be increased considerably. Accordingly, the laser light sources considered here are primarily laser diodes.
In currently known solutions, however, the laser beam is not emitted directly from the lighting device or the headlight, in order to avoid endangering the eyes of people and other living beings from the extremely concentrated, high-power light beam. Rather, the laser beam is directed onto an intermediate conversion element, which contains a material for luminescence conversion, or "phosphor" for short, and converts the laser light, for example a wavelength in the blue range, into visible light, preferably white light; this visible light is then directed outside. In the context of the present invention, "phosphorus is generally understood to mean a substance or mixture of substances which converts light of one wavelength into light of another wavelength or a wavelength mixture, in particular into" white light, which can also be subsumed under the term "wavelength conversion". In most cases, the conversion element is preceded by a programmably pivotable mirror (with regard to the beam path of the laser light), by means of which the laser beam can be directed to different locations on the flat conversion element. In order to ensure that well-defined light spots or (with a moving mirror) light patterns are generated on the conversion element, the light originating from the laser light source is collimated by means of an optical arrangement, which here is called collimator optics
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P15696 is called. The collimator optics are generally arranged immediately after the laser light source (with regard to the beam path) and can comprise several optical components and / or the light-limiting components, but are often formed by a single optical lens.
Due to manufacturing-related deviations in the relative position and orientation of the optical components that belong to the laser light source, it is necessary to adjust the laser light source with respect to the beam path of the laser beam generated by it so that a light spot with the desired sharpness can be generated on the conversion element.
Conventional solutions provide a device that provides an adjustment option for the collimator lens, in particular by tilting the lens with respect to the optical axis or adjusting the distance from the laser light source. However, these devices are naturally complex and therefore costly and time-consuming to manufacture and adjust. In addition, they generally lead to an increased space requirement due to the number of components required.
It is therefore an object of the invention to provide a laser source arrangement with laser modules which overcomes the disadvantages mentioned and in particular allows simple and efficient adjustment of the laser beam path. In particular, individual adjustment of the individual laser beams should be made possible in the case of light modules with several laser light sources.
This object is achieved by a laser module of the type mentioned at the outset, which according to the invention has a module body with a head part, which contains a joint part of a ball joint with at least one joint surface with a spherical shell-like shape, the laser light source together with the optics in a receiving space provided in the head part ( ie an at least partially enclosed area in the head part) are mounted in a fixed positional relationship to each other.
The object is also achieved by a laser source arrangement (laser assembly) for a vehicle headlight with a laser module according to the invention and with a bearing component for mounting this laser module, the bearing component being a
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Joint part which is formed with at least one joint surface with a spherical shell-like shape as a counterpart to the joint part of the head part of the laser module, the joint parts of the head part and the bearing component being designed to correspond to one another to form a ball joint.
The invention is based on the knowledge that it is not necessary to correct the beam path by adjusting the collimator relative to the light source; rather, it is sufficient to adjust the unit that contains the light source and the collimator as a whole. According to the solution according to the invention, the laser module includes a module body with a head part, which has an inner region as a receiving space in which the laser source, i.e. the laser diode and the associated collimator optics can be installed in a fixed position. The laser diode and the collimator are thus in a fixed positional relationship to one another; these, together with the module body receiving them, form a unit within which the components therein are generally no longer changed after assembly. The head part forms a joint part of a ball joint with at least one spherical shell-like joint surface; a second joint part of the ball joint belongs to a bearing component that serves for the adjustable mounting of the laser module.
The laser module according to the invention and the bearing component together form a laser assembly, namely the laser source arrangement of the invention, which can be pre-assembled in a form-fitting manner and in which the two parts no longer fall apart due to the articulated connection. The ball joint formed by the two joint parts enables simple and efficient adjustment of the alignment of the laser source or of the laser beam generated by it and the associated beam path. The adjustment of the laser module achieved in this way can then be achieved by permanent attachment, e.g. by means of gluing or spot welding.
By adjusting the laser assembly right at the beginning of the beam path, any deviations that may occur and the tolerances of the subsequent optical surfaces of optical components can be compensated for; the components following in the beam path therefore no longer have to be adjusted, or at least only to a significantly reduced extent. In particular, the invention enables an efficient counteraction against propagating errors (e.g. angular errors) in the beam path.
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In the context of this disclosure, “optical component means a component that serves to generate light and / or to deflect or shape light, which includes in particular light sources and light-converting components as well as optical lenses, mirrors and diaphragms. The “longitudinal direction” is understood to mean the direction of the imaginary axis along which the light propagation of the laser light from the laser light source takes place, including the extension backwards, i. H. against the direction of light propagation.
As a rule, the module body will have at least one cooling part, which is used in particular to dissipate heat from the light source. This cooling part can advantageously be arranged facing away from the head part of the module body. Furthermore, the cooling part can extend parallel to the longitudinal direction, i.e. that direction which is a rearward extension of the nominal direction along which laser light generated by the light source emerges from the receiving space.
In order to facilitate the mounting of the laser light source and the associated electrical supply, it is advantageous if the cooling part, or two or more of the cooling parts mentioned, are arranged around an access path through which access to an installation location in which the laser light source is mountable, is formed. The access path can in particular coincide with the longitudinal direction, but can also deviate from this. In addition, the laser light source can be inserted through the access into the module body, for example into a seat which is accessible from the rear and is provided for the laser light source.
The ball joint can preferably be provided such that the joint surface of the head part has at least one convexly shaped part of a ball shell (ball head); the counterpart is then e.g. a joint socket is provided, which has at least one concavely shaped part of a spherical shell. Alternatively, the roles can be reversed, i.e. the counterpart contains a spherical head part and the head part of the laser module contains an articulated surface which has at least one concavely shaped part of a spherical shell.
In order to be able to secure the (adjusted) position of the laser module in the laser source arrangement after insertion and, if necessary, adjustment, after the
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Ball joint and adjusting the orientation of the laser module are an inseparable fixation of the position of the head part on a counterpart connected via the joint surface. This fixation can be achieved in particular by gluing or preferably a welding spot.
The receiving space can expediently be formed as a depression in the head part, in which the laser light source can be permanently installed together with the optics. Here, the depression can also open into an opening provided in the articular surface, which is provided for the passage of laser light generated in the laser light source.
In another embodiment of the invention, the head part can have two or more
Have projections that are arranged surrounding the receiving space.
A convenient position of the laser light source together with the optics within the receiving space is e.g. such that the virtual light source (i.e. the location of the emission from which the laser beam appears to emanate with regard to the beam path immediately after the laser light source and the optics integrated therein) is arranged in the center of the articular surface of the head part. This measure prevents the virtual light source from shifting during adjustment.
According to a favorable shape, the spherically curved joint surface corresponds to a spherical shell part which lies within an angular width with respect to a longitudinal axis, which is smaller than an installation angle of the rotation about the longitudinal axis, this condition only applies to that part / at least that part of the joint surface which faces away from the longitudinal axis of the laser light source. This mounting angle is preferably 90 °. The edges of the articular surface can advantageously merge continuously, preferably smoothly, into the remaining part of the head part and / or the cooling part.
The invention can be understood in more detail and further advantages on the basis of the exemplary embodiments illustrated below. The exemplary embodiments relate, by way of example and not limitation, to various configurations of light modules and laser modules in a motor vehicle headlight, which are shown in schematic form in the accompanying drawings, in which:
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1 shows a light module according to a first embodiment;
FIG. 2 illustrates the optical beam path and the optical components in the light module of FIG. 1;
3 shows a laser module of the light module of FIG. 1 and an associated mounting in a perspective view obliquely from the front;
FIG. 4 shows the laser module of FIG. 3 in another perspective view obliquely from behind;
5 shows a perspective sectional view of the laser module of FIGS. 3 and 4;
6 shows an example of a tasted beam path of a laser module;
FIG. 7 illustrates the correction of the beam path of the laser module of FIG. 6 according to the invention;
8a and 8b illustrate the correction according to the invention on the basis of the light images generated by the light module, FIG. 8a showing a desired light image and FIG. 8b a light image with a tasted light strip;
9 shows a perspective view of a laser module and an associated mounting according to another exemplary embodiment;
FIG. 10 shows the laser module of FIG. 9 in a further perspective view; and
FIG. 11 illustrates the assembly process of the laser module of FIG. 7.
In the figures and in the discussion of the exemplary embodiments below, parts which are important for the invention are shown in a vehicle headlight, it being clear that a vehicle headlight also contains many other parts, not shown, which enable sensible use in a vehicle itself. For the sake of clarity, the headlight housing, the control electronics, further mechanical elements or holders of optical components in the vehicle headlight are not shown, for example; these components, not shown here, can be easily supplemented by the person skilled in the art from the prior art.
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1 to 7 illustrate a first exemplary embodiment of the invention, namely a light module 10 of a motor vehicle headlight. In Fig. 1, the light module 10 is shown with the housing 19 opened, whereby an overview of the essential optical components of the light module 10 can be seen. 2 shows the optical components of the light module 10 and the beam path of a plurality of laser beams, which is defined by these components.
The light module 10 contains a number of laser modules 11 (e.g. two to five, more generally one to ten or more, depending on the embodiment variant selected), as can be seen in particular in FIG. 2. Each laser module 11 contains a laser light source Q (FIG. 5), which in the example shown is designed as a laser diode; however, other known laser sources can be used in a corresponding manner. The laser modules 11 are, for example, lined up next to or above one another in a linear arrangement along the direction Z in the light module 10, for example attached to a mounting field 38 provided for this purpose on the outside of the housing 19 by means of bearing elements 31 of the light module 10, as explained in more detail below becomes. Each laser module 11 is assigned one of a corresponding number of first deflection mirrors 13, which can be staggered along a direction Z, which direction Z is oriented transversely to the longitudinal direction X of the emission of the laser light from the laser modules 11. The light, which is emitted by one of the laser modules 11 in each case, is deflected by the respectively assigned first deflecting mirror 13, whereby a beam of rays V is formed which is directed onto a dynamic beam deflection device 16, e.g. in the form of a MEMS scanner mirror, for example with the aid of a second deflecting mirror 14 and a lens 15 interposed in the beam path, and / or a concave mirror (not shown), e.g. Parabolic mirror. The beam deflection device 16 periodically directs the light of the beam onto a phosphor 17, as will be explained below. The light image thus generated on the phosphor 17 is projected with the aid of projection optics, which in the exemplary embodiment shown are e.g. is realized by a projection lens 18, image E projecting outwards - projected through the front window (not shown) of the headlamp, where it generates a desired light image (cf. FIGS. 8a, 8b) on a roadway, for example.
In the exemplary embodiment considered here, the beam deflection device 16 is designed as a micromirror which can be pivoted about at least one axis and which, for example, is produced using the known MEMS technology (Micro-Electro-Mechanical Systems) and is therefore also known as a MEMS scanner. A micromirror of this type (or any of
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P15696 multiple micromirrors) is used, for example, as a one-dimensional line scanner, with the laser beams being periodically guided line by line over the phosphor (ID scanner). If several laser beams are used, several laser spots can be generated on the phosphor, which are arranged one above the other, and with the use of the periodically oscillating micromirror, light stripes are generated which adjoin or overlap, so that no gap is left between them (see Fig. 8a). In a variant it can be provided that a micromirror is pivoted about 2 axes, whereby several laser beams create a point on the phosphor, which is scanned line by line over the phosphor (2D scanner).
3 shows a perspective view of a laser module 11 and an associated bearing element 31 of the light module 10. FIG. 4 shows the laser module 11 in another perspective view, in which the viewing direction is rotated by approximately 90 ° with respect to FIG. 3. FIG. 5 shows the laser module 11 in a sectional view along a plane which runs through the longitudinal direction X and is parallel to the direction Z.
The laser module 11 is formed by a module body 21, in which the already mentioned laser light source Q is mounted and a collimator (collimator optics) R assigned to the laser light source Q is provided; for example, the collimator R can be realized by a single converging lens (collimator lens) which is arranged in the beam path immediately after the light source Q and is permanently mounted or adjustable there. The module body 21 can be formed in one piece or, if necessary, be assembled from several parts. In the exemplary embodiment shown in FIGS. 3 to 5, the laser light source Q and a collimator lens R connected downstream thereof are accommodated in a preassembled laser diode unit 20. The light source Q and the collimator R are installed in a defined position in relation to one another. For example, a laser diode can be used as the laser diode unit 20, in the component housing of which a laser diode and a window, which allows the laser beam to emerge and can serve as a collimator lens, are accommodated and from which an elliptical laser beam is emitted.
The laser diode unit 20 is in a recess 22 provided for this purpose in the
Laser module 11 used and fixed there. Here, e.g. the bottom of the recess 22 or a protrusion (e.g. an annular step) in the side wall of the recess form a seat for the unit 20. In this way, light source Q and collimator R are rigid in that
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Module body 21 arranged. The light emitted by the laser diode unit 20 exits through the opening 23 corresponding to the depression 22 on the surface of the module body 21. The opening 23 or the associated depression 22 is preferably located in a head part 24 formed on the front of the laser module, which has a shape with an articulated surface 25 which, in the example shown, has a convex spherical shell-like design and through which the head part is made possible, a ball joint in connection with a suitable counterpart (in particular the bearing element 31). The depression 22 is preferably located at an apex of the head part 24, parallel to the longitudinal direction X of the laser module 11, for example in the middle of the articular surface 25. The opening 23 is preferably circular, but can be designed differently if necessary. The length of the module body 21 (along the longitudinal direction X) is typically 5 cm. The laser diode unit 20 is preferably arranged in the depression 22 such that the virtual light source (i.e. the emission point of the laser beam) is located in the center of the spherical shell-like curved joint surface 25. The depression 22 is also shaped such that good heat transfer from the component housing of the laser diode unit 20 into the module body 21 can take place. In the exemplary embodiment of FIGS. 3-5, the laser diode unit 20 is inserted into the recess 22 of the module body 21 from the front, for example through the opening 23, during its assembly in the laser module, the electrical connections (not shown) being provided for this purpose by one or more provided bushings 28 (Fig. 4) in the bottom of the recess to the rear of the module body 21 can be performed.
The laser module 11 is inserted into a bearing component 31 with the aid of the head part 24 and can be fixed there, thereby forming a laser source arrangement in the sense of the invention. The bearing component of the embodiments shown here is a one-piece bearing element; in other design variants, the bearing component can also be composed of several parts.
3 and 4, the bearing element (bearing component) 31 has a joint socket 30 which, as a second joint part, forms the counterpart for the head part 24 for producing a joint connection in the manner of a ball joint. The joint socket 30 has an articulated surface 35 which, in the example shown, is designed as a concavely curved spherical shell, more precisely as a partial surface of this concave spherical shell (inner surface of the sphere). Correspondingly, the joint surface 25 of the head part 24 has the shape of a convex
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Spherical shell, more precisely part of a spherical shell (outer surface of a sphere). The two joint surfaces 25, 35 are shaped corresponding to one another, so that the inner surface of the ball can be rotatably positioned in the outer surface of the ball and forms a bearing with a ball joint.
The bearing element 31 also has fastening devices such as e.g. Tabs 32, which serve to permanently secure the bearing element 31 to mounting surfaces 38 of the light module 10 provided for this purpose, for example by means of screws or rivets (not shown), which pass through holes 34 provided in the tabs 32 and on the mounting surfaces 38 side through corresponding holes 39 (Fig. 1) are fixed. In addition, an opening 33 is expediently provided in the joint socket 30, which corresponds to the opening of the head part 24 and through which the laser light emitted by the light source Q can pass.
In the exemplary embodiment shown, the articulated surface 25 corresponds to that part of a spherical cap which has been trimmed at the top and bottom (with respect to the height direction Z), so that the parts above and below are omitted and from which the opening 23 has also been removed. The sectional planes correspond to the two XY planes perpendicular to the height direction Z at the height of the upper or lower edge of the head part 24. The articular surface 35 has an analogous shape, but the height in the Z direction and / or the size or shape of the Articular surface 35 may differ slightly, provided that this is compatible with the arrangement on the mounting surfaces of the light module.
As is known, heat is generated in the light source Q or the laser diode unit 20 during its operation, and this must be dissipated in order to avoid destruction of the light source. The heat is dissipated via the module body 21 of the light module. Referring again to FIGS. 3 and 4, the heat reaches cooling fins 27 via the head part and adjoining side parts 26, by means of which the heat is released to the environment. The cooling fins 27 are e.g. realized as external designs of the module body, which are preferably arranged on a rear side of the laser module, i.e. on a side facing away from the head part 24. In the embodiment shown in FIGS. 3 and 4, the module body 21 of the laser module 11 has two wing-like side parts 26, which are formed on both sides of the longitudinal direction X and each other
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P15696 are spaced, thereby forming an access to the rear of the head part along the longitudinal direction X. The cooling fins 27 are provided in the extension of the side parts 26 backwards. This results in a flattened design of the laser module 11, which facilitates an arrangement of a number of laser modules in a (or possibly more) row, which is aligned, for example — preferably linearly — along the direction Z, which is transverse to the direction of propagation X of the laser light, for example in the vertical direction.
Ideally, the laser beam which emerges from the light source mounted in the laser module 11 (ie in this case the laser diode unit 20) runs along a longitudinal direction X defined in the laser module 11. The assembly and basic alignment of the laser module 11 in the light module 10 is based on this Longitudinal direction X carried out, whereby the laser beam emerging from the light source spreads - at least approximately - in a defined direction and along the predetermined beam path (see FIG. 2). In fact, however, as will be explained below, a deviation of the exit direction from the longitudinal direction X occurs and thus a certain error in the beam path.
Due to tolerances and / or assembly errors in the light source Q or the laser diode unit 20 and the mounting thereof in the laser module, for example due to deviations in the shape in the recess 22, the direction of the emerging laser beam can differ slightly from that of the longitudinal direction X.
The laser module 11 is aligned as a function of the exit direction of the laser beam within the light module 10, so that the light is directed to the assigned first deflecting mirror 13 in the direction specified in the light module 10 (direction X in FIG. 2). In order to set the exit direction of the light, the joint connection already mentioned is used, which is formed by the joint socket 30 of the bearing element 31 and the head part 24 inserted therein.
6 and 7 illustrate the process of setting a laser module 11 using the example of a beam path of a laser module in a light module of the type shown in FIGS. 1 and 2. Fig. 6 shows a laser module 11 in the initial state immediately after its installation in the bearing element 31. Tolerances (or other deviations) on the
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Components, in particular optical components, of the light module 10 can lead in the optical path to a deviation from the desired beam path V0 (dashed line), as symbolically represented in FIG. 6 by a dotted line VI; this deviation (misalignment) can often be so great that the laser beam falls on an incorrect location of the micromirror (beam deflection device) 16 or completely misses it. According to the invention, the ball joint of the laser module 11 allows the laser module to be tilted by a small angle from the nominal axis X, which is indicated by the arrow W in FIG. 7. The direction in which the tilting takes place can lie in the Z direction (within the plane of the drawing in FIG. 7; including the opposite direction) and / or perpendicularly thereto - in the direction Y perpendicular to the plane of the drawing. This enables the direction of the laser beam emerging from the laser module to be corrected and a corrected beam path V2 to be achieved with which the laser beam is directed onto the micromirror arrangement 16 and the phosphor 17 as required.
The adjustment of the laser modules can also be carried out automatically. For this purpose, the pre-assembled laser module 11 is held at the rear end of the heat sink, e.g. from a robot. The luminous point, which is generated by the laser module 11, is measured on the phosphor 17 by means of a camera; Any deviation is determined on the basis of this measurement, and accordingly the alignment of the laser module 11 is readjusted until the position of the illuminated dot corresponds to the desired position. In this way, all deviations / tolerances in the beam path are compensated.
In contrast to conventional solutions in which only the lens (collimator) following the laser light source is adjusted, the present invention provides that the laser light source including the collimator optics - which is also integrated in the laser diode unit in the exemplary embodiments shown - is adjusted. It can also be provided that the light source can not only be swiveled but also rotated (namely by rotating the laser module). This enables an elliptical laser output beam to be rotated, which is not possible with conventional solutions in which only the lens is adjusted.
In order to secure the laser module 11 in the adjusted position, it is fixed in this position with the aid of a fixing device. For this purpose, advantageously directly after the adjustment process described above, a weld spot is passed through the joint socket 30
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P15696 set up to joint surface 25. Here, the wall of the spherical shell is temporarily heated by the welding process (preferably laser welding) in the area of the welding point and thereby melted; in this way the hinge part connects to the counterpart underneath. As a result, the ball joint formed by the two joint parts 24, 35 is permanently fixed in this position; at the same time the articulation itself is secured against unwanted loosening. During the fixing process, the position is expediently held by suitable holding means (such as a robot arm, with the aid of which the laser module 11 is also adjusted). Alternatively, permanent fixation can also be achieved by other means, for example by an adhesive which e.g. is introduced into the joint gap or is previously applied to the spherical surface (s) on one or both sides. In this case, the assembly is assembled, adjusted and held in the adjusted position until the adhesive has cured, be it by self-curing or by the adhesive e.g. is cured by means of UV radiation.
The effect of the invention is explained again in FIGS. 8a and 8b, using the area illuminated on the phosphor 17; this illuminated area is projected onto the road as a light image T in front of the headlamp with the brightness curve modulated on it. 8a shows a desired light image T, which consists of a plurality of strips S, which are generated by the scanning movement of the micromirrors of the micromirror arrangement 16, in that a light spot P, which is generated by a laser beam, illuminates one of the strips S. , The double arrows symbolize the scan direction of the light points P in the light image T; the brightness curve, which corresponds to a concrete light distribution, is not shown in FIGS. 8a and 8b for the sake of clarity, rather a (hypothetical) uniformly bright light image is assumed. The individual strips S run parallel to one another, bordering on one another or overlapping slightly. If one of the laser modules is misaligned, the strip SI generated by the associated misaligned light point PI is shifted from its target position as shown in FIG. 8b, this shift generally a component along the scanning direction and a component transverse to this (transverse offset) can have. In particular, as a result of the transverse offset, a more or less narrow strip-shaped area U is not illuminated, which leads to an interruption in the photograph. Due to the possibility of adjustment of the light module according to the invention, this displacement and an interruption of the resultant which may result therefrom
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Light image can be compensated in a simple manner, so that the uniformly illuminated light image T of Fig. 8a can be obtained again.
9 and 10 show a laser module 12 and an associated bearing element 51 according to a further exemplary embodiment, which allows a particularly stable form-fitting articulated connection. The laser module 12 is in turn formed by a module body 41, which is divided into a head part 44 and a cooling part 46. A laser diode unit 40 with the laser light source Q and integrated collimator R is accommodated in the head part 44. In the embodiment shown, the head part 44 includes a seat 42, which is preferably arranged centrally on a base plate 43 of the module body 41 and in which the laser diode unit 40 is received and held, for example in the form of a recess in a frustoconical holder. The seat 42, and thus the light source Q or the laser diode unit 40, lies in the middle of an inner region 47 of the head part 44, which is defined by the base plate 43 and two projections 49 arranged laterally thereon and which corresponds to the receiving space of the invention. Each projection 49 has on its inside, i.e. the side assigned to the light source Q or the seat 42 has a concave curved inner surface 45, which serves as the joint surface of a joint part for forming a ball joint. As already mentioned, the inner sphere surface is understood to mean a concavely curved partial surface of the spherical shell. When assembled, the laser diode unit 40 in the seat 42 is preferably in a position such that the virtual light source (i.e. the emission point of the laser beam) is located in the center of the (spherical shell-like) joint surface 45.
The cooling part 46 adjoins the base plate 43 of the head part, wherein it extends rearward from the head part 44, as seen in the longitudinal direction X. A plurality of cooling fins are formed on the outside of the cooling part, e.g. also run in the longitudinal direction. An access opening 48 is advantageously left free in the middle of the cooling part 46, along the longitudinal axis X. The laser diode unit 40 is installed in the module body 41 by inserting the unit 40 through this rear access opening 48. This access opening 48 also serves to supply the electrical supply to the laser diode unit 40.
The bearing element 51 corresponding to the laser module 12 has a joint part 50 which, as a second joint part, is the counterpart for the head part 44 for producing one
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Forms joint connection in the manner of a ball joint. The joint part 50 is designed as a spherical head, more precisely in the form of parts of a spherical head, and in the example shown contains two projections, the outer sides of which each have a joint surface 55. The joint surfaces 55 are outer spherical surfaces, i.e. Partial surfaces of convex spherical shell surfaces. The two joint surfaces 45, 55 are shaped corresponding to each other so that they can form a bearing according to a ball joint, in which the inner surface of the ball can be rotated in the outer surface of the ball.
The bearing element 51 also has fastening devices such as e.g. Tabs 52, which serve to permanently secure the bearing element 51 to mounting surfaces provided for this purpose of the light module 10, for example by means of screws or rivets (not shown), which are passed through holes 54 provided in the tabs 52 and are fixed on the mounting surface side of the light module 10. In addition, an opening 53 is expediently provided, which corresponds to the front of the inner region 47 and through which the laser light emitted by the light source Q can pass.
In the exemplary embodiment shown, the two surfaces 45 correspond to those parts of a spherical zone ring which runs around the longitudinal direction X and which has been trimmed above and below (with respect to the height direction Z), so that the parts lying above and below are omitted. The sectional planes correspond to the two XY planes perpendicular to the height direction Z at the height of the upper and lower edge of the base plate 43.
The articulated surfaces 55 can also be viewed geometrically as a (small) part of a spherical shell sector of an imaginary sphere that has an angular width with respect to the longitudinal axis X that is smaller than a predetermined mounting angle of the rotation D about the longitudinal axis X. This mounting angle is preferably 90 °, but can optionally also be selected differently, in particular smaller. In this way, when the laser module is rotated through this mounting angle about the longitudinal axis X, the articulation surfaces 55 come to lie in regions of the imaginary sphere which do not overlap at any point with the regions which the articular surfaces had occupied before the rotation. This allows the articulation surfaces 55 to engage the counterpart in the original position, while in the rotated position they are free and allow the laser module to be inserted or removed. In addition, it is noted that this restriction with regard to the angular width is strictly only for the counterpart 50
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The part facing away from P15696 applies (or, in other words, the part facing away from the light source Q), while there is no such restriction for the parts of the articular surfaces facing the counterpart 50, as can be seen from the example of the first embodiment.
With this design, the joint surfaces of the two joint parts are shaped in such a way that the laser module can be placed on the bearing element and positively connected by a rotary movement in a manner that prevents the ball joint from falling apart. As a result, the secure connection of the laser module in the light module can be achieved, which nevertheless permits simple and permanent adjustment.
11 illustrates the process of inserting the laser module 12 onto the bearing element 51 in order to obtain the corresponding laser source arrangement with a ball joint connection. It is assumed that the bearing element 51 is already mounted on the mounting surfaces of the light module provided for this purpose - this is not shown in FIG. 11 for the sake of clarity. The laser module 12 is aligned head first, along the longitudinal axis X, but around this by an angle of e.g. Rotated 90 ° (mounting bracket), moved to the bearing element 51. In this way, the projections 49 of the head part 44 on the one hand and those of the corresponding joint part 50 on the other hand do not stand in the way of one another, so that the laser module 12 can be brought along the longitudinal direction X to the position shown in FIG. 11, in which the spherical shell parts are concentric , A rotation D of the laser module 41 about the axis X by 90 ° (mounting angle) engages the articulation surfaces 45, 55, and an articulated connection is established which allows the laser module to be tilted by (not too large) angles without the Articulation itself is broken by this.
The adjustment of the laser module 41 with respect to the beam path corresponds to the process which was explained above with reference to FIGS. 6 and 7 in connection with the first exemplary embodiment. To fix the laser module in the adjusted position, welding spots or other suitable means can also be used here.
Of course, the invention is not limited to the exemplary embodiments described above; rather, numerous modifications are conceivable within the scope of the invention as defined by the claims. In particular, the orientation of the light module and the laser modules arranged therein can be different than shown here; for example, the
17/24
P15696
Height direction Z can also be aligned horizontally instead of vertically. The longitudinal direction X of the laser modules is mostly horizontal, but can also be oriented differently; however, the alignment of the micromirror arrangement, projection lens and phosphor according to the installation position in the headlight is naturally predetermined in the light module in order to ensure the projection of a light image to the front by the headlight. Also, the inside and outside surfaces of the two joint parts involved in the ball joint in the laser source arrangement according to the invention can be optionally arranged so that the inside surfaces of the balls are arranged in the head part of the module body and the outside surfaces of the balls on the bearing element, or vice versa, the outside surfaces of the balls on the head part and Spherical inner surfaces in the bearing element.
18/24
P15696

权利要求:
Claims (13)
[1]
claims
1. Laser module (11, 12) for a vehicle headlight, with a laser light source (Q), preferably a laser diode, and an optical system assigned to the laser light source, comprising at least one collimator (R), characterized by a module body (21, 41) with a head part (24 , 44), which contains a joint part of a ball joint with at least one joint surface (25, 45) with a spherical shell-like shape, the laser light source (Q) together with the optics (R) in a receiving space (22, 47) provided in the head part (24) ) are mounted in a fixed positional relationship to each other.
[2]
2. Laser module according to one of the preceding claims, characterized in that the module body (21, 41) has at least one cooling part (26, 46) which is arranged facing away from the head part (24, 44) of the module body.
[3]
3. Laser module according to claim 2, characterized in that the at least one cooling part (26,46) extends parallel to an axial direction (X), which is a rearward extension of the nominal direction, along the laser light generated by the light source (Q) the recording room (22, 47) emerges.
[4]
4. Laser module according to claim 2 or 3, characterized in that two or more of said cooling parts (26) are arranged around an access path (X) through which an access (28,48) to a mounting location in which the laser light source ( Q) is mountable, is formed.
[5]
5. Laser module according to claim 4, characterized in that the laser light source (Q) through the access (48) in the module body (41) can be used.
[6]
6. Laser module according to one of the preceding claims, characterized in that the articulated surface (25) of the head part has at least one convexly shaped part of a spherical shell.
[7]
7. Laser module according to one of claims 1 to 6, characterized in that the receiving space (22) is formed as a recess (22) in the head part (24) in which the laser light source (Q) together with the optics (R) can be permanently installed are, the
19/24
P15696
Depression opens into an opening (23) provided in the articular surface, which is provided for the passage of laser light generated in the laser light source (Q).
[8]
8. Laser module according to one of claims 1 to 6, characterized in that the head part (44) has two or more projections (49) which are arranged surrounding the receiving space (47), the laser light source (Q) together with the optics ( R) is arranged within the receiving space in or near a center point of the articular surface (25, 45) of the head part.
[9]
9. Laser module according to one of the preceding claims, characterized in that the at least one articulated surface (55) corresponds to a spherical shell part which is in relation to a longitudinal axis (X) within an angular width which is smaller than an installation angle of the rotation about the longitudinal axis ( X), the mounting angle preferably being 90 °, this being the case for at least that part of the articular surface (55) which faces away from the laser light source (Q) with respect to the longitudinal axis (X).
[10]
10. Laser source arrangement for a vehicle headlight with a laser module (11,
12) according to one of the preceding claims, and with a bearing component (31, 51) for mounting the laser module, the bearing component having a joint part (30, 50) which has at least one joint surface (35, 55) with a spherical shell-like shape as a counterpart to Joint part of the head part (24, 44) of the laser module is formed, the joint parts of the head part and the bearing component being designed to correspond to one another to form a ball joint.
[11]
11. Laser source arrangement according to claim 10, characterized by a non-detachable fixation of the position of the head part (24, 44) produced after the ball joint has been formed on a counterpart (30, 50) connected via the joint surface (25, 45).
[12]
12. Light module (10) comprising a number of laser source arrangements according to claim 10 or 11.
[13]
13. Vehicle headlight with a light module according to claim 12 and / or at least one laser source arrangement according to claim 10 or 11.
20/24
1.4
21/24
X
22/24
23/24
4.4

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同族专利:

公开号 | 公开日

AT519453B1|2018-07-15|

WO2018176073A1|2018-10-04|

KR102298248B1|2021-09-08|

EP3601875A1|2020-02-05|

CN110446886A|2019-11-12|

EP3601875B1|2020-12-16|

KR20190125387A|2019-11-06|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

ATA50254/2017A|AT519453B1|2017-03-30|2017-03-30|Laser module and laser source arrangement for a vehicle headlight|ATA50254/2017A| AT519453B1|2017-03-30|2017-03-30|Laser module and laser source arrangement for a vehicle headlight|

EP18714422.5A| EP3601875B1|2017-03-30|2018-03-09|Laser module for a vehicle headlamp|

PCT/AT2018/060062| WO2018176073A1|2017-03-30|2018-03-09|Laser module for a vehicle headlamp|

KR1020197028684A| KR102298248B1|2017-03-30|2018-03-09|Laser module for vehicle headlamps|

CN201880022178.2A| CN110446886A|2017-03-30|2018-03-09|Laser module for automobile front lamp|

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