Additional optics for beam splitters for optical fibers

专利摘要:
The invention relates to a lighting arrangement (1) for vehicles, comprising at least one optical waveguide (2) which, starting from a common end region (E) opening at a fork (G), at the fork (G) into at least two optical waveguide sections (4 ', 4 ''), wherein the common end region (E) has a light main propagation direction (X), the light guide sections (4 ', 4' ') having one or more outcoupling sites (5) for coupling out light, and an intermediate element (3) for homogenizing stray light emerging at the fork (G) from the at least one optical waveguide (2), wherein the intermediate element (3) extends between the at least two optical waveguide sections (4 ', 4' ') and a light entry surface (3a) and one of the Has light entrance surface (3a) opposite light exit surface (3b) for emitting light in a lying between the light guide sections (4 ', 4' ') area, wherein the light 3) is spaced from a beam splitting point located at a crest of the crotch (G), the light entrance surface (3a) being oriented substantially normal to the main propagating light direction (X) of the common end region (E).
公开号:AT518191A1
申请号:T50070/2016
申请日:2016-02-04
公开日:2017-08-15
发明作者:Moser Martin；Ecker-Endl Markus
申请人:Zkw Group Gmbh；
IPC主号:

专利说明:

Additional optics for beam splitters for optical fibers
The invention relates to a lighting arrangement for vehicles, comprising at least one light guide, which branches from a forked into a common end region at the fork in at least two optical fiber sections, wherein the common end region has a Lichthauptausbreitungsrichtung, wherein the optical fiber sections one or more extraction points for coupling of light, as well as an intermediate element for homogenizing scattered light emerging from the at least one light guide, the intermediate element extending between the at least two light guide sections and a light entry surface and a light entry surface opposite the light exit surface for emitting light into a lying between the light guide sections Has area.
Lighting arrangements are increasingly used in vehicle construction, wherein light originating from light sources is fed to a front surface in a light stick. The light is inside the boundary walls of the most circular, but possibly also another, e.g. elliptical, cross-section having optical fiber totally reflected, but share at the Störs and radiated essentially at the opposite side of the sturgeon. The geometry of the glow sticks is often determined by design specifications in automotive construction, whereby the desired contours can often no longer be realized by a single light stick and in many cases it is necessary aufzuschabel a light stick in two branches.
In the lighting arrangements according to the prior art, problems arise with respect to a uniform luminance along the light guide, especially in the region of the fork, wherein depending on the viewing angle uncontrollable light spots, but especially dark spots occur.
It is therefore an object of the invention to provide a lighting arrangement that allows the emission of a homogeneous light image and is easy to produce.
This object is achieved with a lighting arrangement of the aforementioned type, wherein according to the invention, the light entry surface of the intermediate element of a on a
Spacing of the crest point is spaced apart, wherein the light entry surface is oriented substantially normal to the light main propagation direction of the common end portion.
Thanks to the features of the invention, a lighting arrangement is provided which allows both the emission of a homogeneous light image and can be easily manufactured. By providing an intermediate element whose light entrance surface is oriented normal to the light main propagation direction and which is spaced from the apex of the bifurcation, the stray light exiting the bifurcation can propagate toward the intermediate element, the light passing through the light entry surface the intermediate element enters, spreads within the intermediate element, at least partially merged and through the
Light exit surface of the intermediate element emerges. As a result, stray light emerging from the fork can be homogenized in a simple manner. This arrangement does not require a shape-filling adaptation of the geometric shape of the intermediate element to the fork, so that an air space can remain between the beam-splitting point and the intermediate element. The intermediate element is therefore subject to lower manufacturing tolerances and can therefore be inexpensively introduced between conductor sections. The lighting arrangement according to the invention does not necessarily have to have only a single intermediate element. The intermediate element may also be formed in several pieces.
By the term "beam splitting point located at a vertex of the crotch" is meant the point which, seen in the light main propagation direction, is the last point at which the optical fiber sections are in cross-sectional orientation oriented normal to the main light propagating direction, so that stray light therefrom Point can escape.
In particular, it can be provided that the light exit surface of the intermediate element is oriented substantially parallel to the light entry surface. This makes it possible to realize a particularly simple construction of the intermediate element and thus of the lighting arrangement.
In addition, it can be provided that the light entry surface of the intermediate element has a contour which is designed to form light emerging from the intermediate element through the light exit surface such that in the region of the fork the angle-dependent intensity of the light emitted from the light exit surface substantially coincides with the angle-dependent intensity of the emitted light from the light guide sections substantially matches. By the region of the bifurcation is meant a region which extends from the vertex of the bifurcation towards the intermediate element and around the distance between vertex and intermediate element beyond the intermediate element. By a constant angle-dependent intensity of the light emission is achieved that the transition of emitted light in the region between the light guide sections and the intermediate element from various viewing angles appears continuous.
For additional homogenization of the light emitted by the intermediate element, provision can be made for the light entry surface to have a wavy contour along its extension between the optical waveguide sections. Depending on the respective irradiation direction of the light beam of parallel rays, a divergent refraction occurs in the region of the depressions when entering, in the region of the elevations a convergent refraction. The point at which the transition between divergent and convergent occurs may "move" depending on the orientation of the beam of parallel rays.
In particular, it can be provided that the wave-shaped contour is formed according to a contour of a wave function, which propagates in the direction of the extension of the intermediate element of a light guide section toward the next light guide section. The term contour of the wave function is understood to mean the spatial distribution of the actual values of the wave function at a specific point in time. Such an orientation of the waves has proved to be particularly advantageous.
In particular, it can be provided that the amplitude of the wave function is 0.02 mm to 0.1 mm and the wavelength of the wave function is in a range of 0.25 mm to 1.5 mm. As a result, inhomogeneities of the light entering via the light entry surface into the intermediate element can be compensated particularly efficiently. The wave function may preferably be in the form of a sinusoidal function.
In addition, it can be provided that the wavelength of the wave function coincides with the length of individual extraction points along the longitudinal extent of a light-emitting section. As a result, by means of the intermediate element as closely as possible a light impression as caused by the light guide sections.
It can be particularly favorable if the coupling-out points of the light guide sections are formed by light extraction elements formed within the light guides, in particular light-outcoupling prisms.
It may be particularly advantageous if the optical fiber sections each have at least one continuous strip of juxtaposed light outcoupling elements, wherein the strip extends along the longitudinal extent of the respective light guide section to the fork, so that light from the light guide section can be directed into the light entry surface of the intermediate element. As a result, the light emitted by the intermediate element can additionally be homogenized.
It can be particularly favorable if the light exit surface runs continuously, in particular smoothly. In particular, it can be provided that the light exit surface of the intermediate element in a cross section transverse to the longitudinal extent of the intermediate element has substantially the same shape as the light exit surface of the optical fiber sections in a cross section transverse to the longitudinal extent of the optical fiber sections, for example, the shape is convex contrary to the light propagation direction. By the term "substantially the same shape" is meant a form which gives the viewer the same impression upon light emission as the form to which reference is made In the present case, this means that the naked eye observer is at least for the duration of the time Light emission through the light guide assembly can detect no difference between the intermediate element and the transition to a light guide section.
In particular, it can be provided that the optical waveguide has a light coupling surface for the coupling of light, which is associated with a light source. Particularly preferably, it can be provided that the light source comprises an LED.
For easy attachment of the intermediate element to the light guide or a light guide section may be provided that the intermediate element is connected to a clamping means for clamping to the light guide or to a light guide section.
In particular, it can be provided that the intermediate element is connected to a cover, which extends to the fork and opens into a clamping means which engages the fork for clamping at the crotch.
In a particularly simple variant of the invention it can be provided that the light guide has exactly two light guide sections branched to one another.
In order to achieve a particularly uniform homogenization, it has proved to be advantageous if the light guide sections are formed in the region of the fork so that they form substantially to the intermediate element together with the intermediate element, the Lorm an isosceles triangle, in particular an equilateral triangle. The sides of this triangle do not necessarily have to be straight, but can also be curved.
It may be particularly favorable if the intermediate element extends as far as the light guide sections, so that the light which can be emitted by the light exit surface of the intermediate element can connect seamlessly to light which can be emitted by the light guide. In particular, it may be provided for this purpose that the intermediate element contacts the optical waveguide sections in a form-fitting manner.
In addition, it can be provided that the intermediate element is at least 10 mm away from the beam splitting point. As the distance increases, it can be more and more easily achieved that due to its divergence the scattered light emerging from the fork passes over the entrance surface of the intermediate piece so that the light emitted by the light extraction points of the optical fiber sections is seamlessly connected without leaving any dark spots. The distance to the beam splitting point can alternatively or additionally be determined as a function of the diameter or the thickness of the light guide or its radius of curvature in the region of the fork.
In particular, it can be provided that the intermediate element consists of transparent material. A transparent material is understood in particular to mean a colorless material.
A further aspect of the invention relates to a vehicle headlight, in particular a motor vehicle headlight, with at least one lighting arrangement according to the invention and a vehicle, in particular a motor vehicle, with at least one lighting arrangement according to the invention and / or with at least one vehicle headlight according to the invention.
The invention is explained in more detail below with reference to an exemplary and non-limiting embodiment, which is illustrated in the figures. It shows
1 shows a schematic, perspective side view of a lighting arrangement according to the invention,
FIG. 2 shows an illustration of the lighting arrangement according to FIG. 1 obliquely from above,
3a shows a detailed view of a fork of the lighting arrangement according to FIGS. 1 and 2, and FIG. 3b shows an associated sectional view,
FIGS. 4a to 4d show different representations of an intermediate element according to FIGS. 1 to 3,
Figure 5a overview of the light assembly according to the invention, wherein the intermediate element is connected to a clamping means, and
FIG. 5b shows a detailed illustration of clamping means of the intermediate element.
In the following figures, unless otherwise stated, like reference numerals designate like features.
Figure 1 shows a schematic, perspective side view of a light assembly according to the invention 1 for vehicles, comprising a light guide 2, which is formed in the present example of two interconnected light rods 2 'and 2 "(see Figure 3a and 3b) and an intermediate element 3. The number the light guide 2 can in principle be chosen as desired. The light guide 2 branches off from a common one into one
At the fork G in at least two light guide sections 4 'and 4 ", which in the embodiment shown are connected together to form a ring or a rectangle with rounded corners, the common end region E has a light main propagation direction X which in a state installed in a vehicle, for example, with the direction of the vehicle's longitudinal axis, and the light guide sections 4 'and 4 "have outcoupling points 5 shown in FIG. The intermediate element 3 is set up to homogenize stray light emerging from the at least one light guide 2 at the fork G and extends between the at least two light guide sections 4 'and 4 ". The intermediate element 3 has a light entry surface 3a shown in more detail in FIGS the light exit surface 3a opposite light exit surface 3b for emitting light in a lying between the light guide sections 4 'and 4 "area.
The light entry surface 3a of the intermediate element 3 is spaced from a beam splitting point P located at an apex of the fork G (see FIG. 3a and FIG. 3b), the light entry surface 3a being oriented substantially normal to the light main propagation direction X of the common end region E. The light exit surface 3b and the light entry surface 3a may be oriented substantially parallel to one another.
FIG. 2 shows an illustration of the lighting arrangement 1 according to FIG. 1 at an angle from above. FIG. 3a shows a detailed view of the fork G of the lighting arrangement 1 according to FIGS. 1 and 2. Therein, the coupling-out locations 5 can be seen, which are designed in the form of light-outcoupling prisms. In the present exemplary embodiment, the two light guide sections 4 'and 4 "shown in each case have at least one strip 6 which is formed by a continuous juxtaposition of light extraction elements 5, the strips 6 extending along the longitudinal extent of the respective light guide section 4' and 4" to extend to the fork G, so that light from the light guide sections 4 'and 4 "can be directed into the light entry surface of the intermediate element associated with a light source, not shown in the figures, which may preferably be an LED.
As can be seen in Figure 3a, without the provision of the intermediate element 3, dark areas may result (e.g., in the angle range a) caused by the inhomogeneous radiation behavior in the region of the bifurcation G. This is mainly due to the fact that despite the provision of additional coupling elements 5 '(in Fig. 3a indicated by dashed lines), which may extend deep into the bifurcation G, due to total reflection at the respective light guide section (in the present example 4 ") The region of the optical waveguide section appears dark without an intermediate element, for example, the light beam LI is deflected due to total internal reflection within the optical waveguide and prevented from exiting, while the exemplary light beam L2 is characterized by additional coupling elements 5 ' the optical fiber section 4 "would be coupled out would impinge on the light guide section 4 'or enter this. Therefore, the problem of inhomogeneous radiation from the optical fiber in the area α can not be solved in a simple manner by the front of the additional coupling-out elements 5 '. A homogenization of the radiated light is achieved by the intermediate element 3, which extends between the at least two optical waveguide sections 4 'and 4 "In Figure 3a, in the region downstream of the intermediate element 3, light beams oriented in parallel to one another are shown by way of example, which are intended to illustrate homogeneous light emission This is a simplified representation - in fact the light rays emerging from the intermediate element 3 or the light exit surface 3b are not bound to any specific orientation but become dependent on the irradiation into the intermediate element 3, the configuration of the intermediate element 3, in particular the light entrance The essential feature is that the light distribution is continuous, which is understood to mean a light distribution which, from different angles of view, does not detect any darkened louvers visible to the naked eye Has in the photograph, so that the transition between the light guide sections 4 'and 4 "runs inconspicuous and largely unnoticed in the light distribution.
The light guides may, for example, have a diameter of 6 to 12 mm. The minimum radius of curvature in the direction of light propagation can be limited by violating the total reflection condition and allowing leakage to occur in the region of curvature. If the light guide made of polycarbonate (PC) is formed, prevails up to an angle of 51 ° between the light propagation direction and tangent to the interface of
Fiber optic section total reflection. In particular, the optical fiber may be designed according to a rule of thumb, according to which the radius of curvature (for example 40-80 mm) should not be less than 7 times the diameter of the optical fiber in order to prevent the leakage of light in the region of curvature. Directly in the beam splitting point P, there may be a leakage of false light, which forms a hotspot, if it is not homogenized.
FIGS. 4a to 4c show different representations of the intermediate element 3 according to FIGS. 1 to 3. FIG. 4a shows a front view of an intermediate element 3 on the light entry surface 3a of an intermediate element 3. It can be seen that the light entry surface 3a extends along its extension between the light guide sections 4 The contour is designed in accordance with a wave function which propagates in the direction of the extension of the intermediate element 3 from one light guide section 4 'to the next light guide section 4 ", the amplitude A of the wave function being between 0, May be 02 mm to 0.1 mm and the wavelength of the wave function may be, for example, in a range of 0.25 mm to 1.5 mm. The wave function is preferably sinusoidal. The course of the wave function is clearly visible in FIG. 4 b, which shows an oblique view of the intermediate element 3. FIG. 4 c shows a front view of the light exit surface of the intermediate element 3.
By providing the intermediate element 3, however, there is a homogenization of the light image, whereby it is possible to hide transitions between the light guide sections 4 'and 4 "and to allow a consistently homogeneous radiation - and even in the transition region to the light guide sections.
As shown in FIGS. 4 a and 4 b, the light entry surface 3 a of the intermediate element 3 has a wave-shaped contour. As a result, light incident on the light entry surface 3a can be changed and deflected by alternating collimating and widening regions in such a way that the same luminous impression is produced, which is caused by the coupling out points 5 in those regions of the optical waveguide sections 4 'and 4 ", which have no intermediate element 3 This makes it possible to achieve a particularly uniform light impression.
The decoupling points 5 are preferably formed as prisms and are opposite the radiating surface of the respective light guide section. In the direction of light pipe they often have a distance of about 1.5 mm.
In particular, provision may be made for the optical waveguide sections 4 ', 4 "to be designed in the region of the fork G in such a way that, together with the intermediate element 3, they form substantially the shape of an isosceles triangle, in particular an equilateral triangle a particularly homogeneous and simple arrangement of the optical waveguide sections 4 ', 4 "or of the light radiated through the optical waveguide sections 4', 4" can be achieved, in particular for the purpose of providing the intermediate element 3 as far as the optical waveguide sections 4 ', 4 ", so that the light which can be emitted through the light exit surface 3b of the intermediate element 3 can connect seamlessly to light which can be emitted by the light guides 2.
In the exemplary embodiment shown, the light rods have a diameter of 6 mm and the intermediate element 3 is spaced 32 mm from the beam splitting point P. In the present example, these dimensions are particularly suitable for providing a lighting arrangement in which the scattered light emerging from the fork G passes, due to its divergence, over the entrance surface 3a of the intermediate element 3 so far as to be separated from the light extraction points 5 of the light guide sections 4 'and 4 The light guide sections 4 'and 4 "themselves have at their light exit surfaces, ie those surfaces through which the light exits the light guide sections, no coupling points, whereby the efficiency of the light assembly is improved , The extraction points 5 are instead arranged opposite these light exit surfaces. It can thereby construct long light guides. Lower efficiency could be compensated by a higher coupled luminous flux, which, however, increase the heat losses in the lighting arrangement, in particular the light source and therefore increased cooling capacity is required.
FIG. 4d shows a sectional view of the intermediate element 3 along the section line BB of FIG. 4b. It can be clearly seen that the light exit surface 3b of the intermediate element 3 in the present cross section, which is oriented transversely to the longitudinal extent of the intermediate element 3, has a convex shape, which in the present example is substantially the same
Shape of the light exit surface of the light guide sections 4 ', 4 "in a cross section transverse to the longitudinal extent of the light guide section 4', 4" corresponds.
5a shows an overview representation of the lighting arrangement 1 according to the invention, the intermediate element 3 being connected to a clamping means 3c for clamping to the light guide 2 or to an optical waveguide section 4 ', 4 ", as can be seen in the detail illustration according to FIG Intermediate element 3 to be connected to a cover 3d, which extends to the fork G and opens in a clamping means 3c, which engages the fork G for clamping at the crotch G.
In view of this teaching, one skilled in the art will be able to arrive at other, not shown embodiments of the invention without inventive step. The invention is therefore not limited to the embodiment shown. Also, individual aspects of the invention or the embodiment can be taken up and combined with each other. Essential are the ideas underlying the invention, which can be performed by a person skilled in the knowledge of this description in a variety of ways and still remain maintained as such.

权利要求:
Claims (22)
[1]
claims
1. lighting arrangement (1) for vehicles, comprising - at least one light guide (2), starting from one in a fork (G) opening common end region (E) at the fork (G) in at least two light guide sections (4 ', 4th "), wherein the common end region (E) has a light main propagation direction (X), the light guide sections (4 ', 4") having one or more outcoupling points (5) for coupling out light, and - an intermediate element (3) for homogenization from at the fork (G) from the at least one light guide (2) exiting stray light, wherein the intermediate element (3) extends between the at least two light guide sections (4 ', 4 ") and a light entry surface (3a) and one of the light entry surface (3a 3) for emitting light into a region lying between the optical waveguide sections (4 ', 4 "), characterized in that the light entry surface (3a) of the Intermediate element (3) is spaced from a at a vertex of the fork (G) lying beam splitting point, wherein the light entry surface (3a) is oriented substantially normal to the light main propagation direction (X) of the common end region (E).
[2]
2. lighting arrangement (1) according to claim 1, characterized in that the light exit surface (3b) is oriented substantially parallel to the light entry surface (3a).
[3]
3. lighting arrangement (1) according to any one of the preceding claims, characterized in that the light inlet surface (3a) of the intermediate element (3) has a contour which formed in such a shape for forming from the intermediate element (3) through the light exit surface (3b) light exiting is that in the region of the fork (G) the angle-dependent intensity of the light emitted from the light exit surface (3b) substantially coincides substantially with the angle-dependent intensity of the light emitted from the light guide sections (4 ', 4 ").
[4]
4. lighting arrangement (1) according to one of the preceding claims, characterized in that the light entry surface (3a) along its extension between the light guide sections (4 ', 4 ") has a wavy contour.
[5]
5. lighting arrangement (1) according to claim 4, characterized in that the wave-shaped contour is formed according to a contour of a wave function extending in the direction of the extension of the intermediate element (3) from one light guide section (4 ', 4 ") to the next Fiber portion (4 ', 4 ") propagates.
[6]
6. lighting arrangement (1) according to claim 5, characterized in that the amplitude of the wave function is 0.02 mm to 0.1 mm and the wavelength of the wave function is in a range of 0.25 mm to 1.5 mm.
[7]
7. lighting arrangement (1) according to one of claims 4 to 6, characterized in that the wavelength of the wave function with the length of individual extraction points (5) along the longitudinal extent of a Lichtleierabschnitts (4 ', 4 ") coincides.
[8]
8. lighting arrangement (1) according to any one of the preceding claims, characterized in that the coupling points (5) of the light guide sections (4 ', 4 ") formed by within the light guide (2) light extraction elements, in particular Lichtauskopplungsprismen.
[9]
9. lighting arrangement (1) according to claim 8, characterized in that the light guide sections (4 ', 4 ") each have at least one continuous strip of juxtaposed light outcoupling elements, wherein the strip along the longitudinal extension of the respective optical fiber section to the fork (G) extends, so that light from the light guide section (4 ', 4 ") in the light entry surface (3a) of the intermediate element (3) can be directed.
[10]
10. lighting arrangement (1) according to any one of the preceding claims, characterized in that the light exit surface (3b) continuously, in particular smooth, extends.
[11]
11. Lighting arrangement (1) according to one of the preceding claims, characterized in that the light exit surface (3b) of the intermediate element (3) in a cross-section transverse to the longitudinal extent of the intermediate element (3) has substantially the same shape as the light exit surface of the optical fiber sections (4 '. , 4 ") in a cross-section transverse to the longitudinal extent of the optical waveguide section (4 ', 4"), wherein, for example, the shape seen in the direction opposite to the light propagation direction is convex.
[12]
12. lighting arrangement (1) according to any one of the preceding claims, characterized in that the light guide (2) has a light coupling surface for coupling light, which is associated with a light source.
[13]
13. lighting arrangement (1) according to claim 12, characterized in that the light source comprises an LED.
[14]
14 light assembly (1) according to any one of the preceding claims, characterized in that the intermediate element (3) with a clamping means (3c) for clamping to the light guide (2) or to a light guide section (4 ', 4 ") is connected.
[15]
15. lighting arrangement (1) according to one of the preceding claims, characterized in that the intermediate element (3) with a cover (3d) is connected, which extends to the fork (G) and in a clamping means (3c) opens, the the fork (G) for clamping at the fork (G) attacks.
[16]
16. lighting arrangement (1) according to any one of the preceding claims, characterized in that the light guide (2) has exactly two mutually branched optical fiber sections (4 ', 4 ").
[17]
17 light assembly (1) according to claim 16, characterized in that the light guide sections (4 ', 4 ") are formed in the region of the fork (G) in such a way that this towards the intermediate element (3) together with the intermediate element (3). form substantially the shape of an isosceles triangle, in particular an equilateral triangle.
[18]
18. Lighting arrangement (1) according to one of the preceding claims, characterized in that the intermediate element (3) extends up to the light guide sections (4 ', 4 "), so that through the light exit surface (3b) of the intermediate element (3) radiant Light can connect seamlessly through the light guide (2) radiatable light.
[19]
19, light assembly (1) according to any one of the preceding claims, characterized in that the intermediate element (3) is spaced at least 10 mm from the beam splitting point.
[20]
20. lighting arrangement (1) according to any one of the preceding claims, characterized in that the intermediate element (3) consists of transparent material.
[21]
21. A vehicle headlight, in particular a motor vehicle headlight, with at least one lighting arrangement (1) according to one of the preceding claims.
[22]
22. Vehicle, in particular motor vehicle, with at least one lighting arrangement (1) according to one of claims 1 to 20 and / or with at least one vehicle headlight according to claim 21.

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FR3051885B1|2016-05-31|2020-08-28|Valeo Iluminacion Sa|LIGHTING DEVICE, ESPECIALLY FOR MOTOR VEHICLES, AND LIGHTING AND / OR SIGNALING UNIT INCLUDING SUCH LIGHTING DEVICE|EP3683497A1|2019-01-18|2020-07-22|ZKW Group GmbH|Lighting arrangement for vehicles|

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CN209944212U|2019-04-01|2020-01-14|法雷奥照明湖北技术中心有限公司|Optical assembly, vehicle lamp and motor vehicle|

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US10648637B1|2019-06-20|2020-05-12|Valeo North America, Inc.|Optical device for a lighting and/or signalling device of an automobile vehicle|

法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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ATA50070/2016A|AT518191B1|2016-02-04|2016-02-04|Additional optics for beam splitters for optical fibers|ATA50070/2016A| AT518191B1|2016-02-04|2016-02-04|Additional optics for beam splitters for optical fibers|

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ES17152735T| ES2878312T3|2016-02-04|2017-01-24|Additional optics for beam splitters in light conductors|

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EP17152735.1A| EP3205926B1|2016-02-04|2017-01-24|Additive lens for the beam splitter of light guides|

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CN201710223459.1A| CN107036026B|2016-02-04|2017-02-03|Additional optical system for a beam splitter in an optical waveguide|