奥地利专利AT16319U1 Optical system and arrangement for emitting light

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专利摘要:
The invention relates to an optical system for influencing a light emitted by a light source (9), which has a first optical element (1), which is plate-shaped in a first approximation, so that a plane (E) through the first optical element (1). wherein the first optical element (1) has a lateral edge region (11) formed to enter the light, and a second optical element (2) which is plate-shaped in a first approximation, the second optical element (2) being parallel is arranged to the first optical element (1) and has a light exit area (21) for the exit of the light, wherein the lateral edge area (11) of the first optical element (1) is designed to deblast the light in the plane (E) , and the second optical element (2) comprises at least one elongate lens element (3) extending along a longitudinal axis (L) and adapted to light in one further leveling or bundling further plane (E '), which is oriented at least substantially perpendicular to the first-mentioned plane (E).
公开号:AT16319U1
申请号:TGM266/2015U
申请日:2015-09-08
公开日:2019-07-15
发明作者:Machate Andreas
申请人:Zumtobel Lighting Gmbh；
IPC主号:

专利说明:

description
OPTICAL SYSTEM AND ARRANGEMENT FOR LIGHT EMISSION The invention relates to an optical system for influencing a light emitted by a light source, as well as an arrangement for light emission with such an optical system.
[0002] DE 10 2012215 640 A1 discloses an illumination system with an essentially plate-shaped light guide and an essentially plate-shaped glare control unit. The anti-glare unit is arranged parallel to and below the light guide. Furthermore, the lighting system comprises an LED light source (LED: light-emitting diode) for generating a light that shines into the light guide from one side. On the underside of the light guide protruding, for example cuboid structures are formed, via which the light leaves the light guide. Collimating elements, which are each assigned to one of the structures, are formed on the top of the anti-glare unit, so that the light subsequently enters the anti-glare unit via these collimating elements. Finally, the light leaves the lighting system via the underside of the glare control unit.
The collimating elements serve to glare the light. For this purpose, they are approximately conical in shape, with a circular or rectangular base. On their upper side they have a recess in which the associated structure is arranged to engage. However, this design means that only a certain proportion of the light leaves the light guide plate via the structures. By contrast, a not inconsiderable proportion of the light is directed past the structures by the light guide, so that it subsequently experiences other interactions and does not subsequently emerge via the underside of the glare control unit. As a result, the efficiency of the lighting system is clearly limited. In addition, the formation of the collimating elements in particular requires a comparatively high production outlay.
The invention has for its object to provide a corresponding improved optical system or a corresponding improved arrangement for light emission; in particular, it should be possible to achieve a particularly good lighting efficiency with a simple production possibility.
This object is achieved according to the invention with the objects mentioned in the independent claims. Particular embodiments of the invention are specified in the dependent claims.
According to the invention an optical system for influencing a light emitted by a light source is provided which has a first optical element which is plate-shaped in a first approximation, so that a plane is defined by the first optical element; the first optical element has a lateral edge region designed for the entry of the light. Furthermore, the system has a second optical element which is plate-shaped in a first approximation, the second optical element being arranged parallel to the first optical element and having a light exit region for the exit of the light. The lateral edge area of the first optical element is designed to glare or focus the light in the plane; the second optical element has at least one elongated lens element which extends along a longitudinal axis and which is designed to glare or focus the light in a further plane which is at least substantially oriented perpendicular to the first-mentioned plane.
Because the glare in the first-mentioned plane is already brought about by the lateral edge region of the first optical element, the elongated lens element only has to be designed for glare-free operation in the further plane, that is to say in only one plane. This results in framework conditions which, in particular, enable the system to be manufactured much more easily. For example, the lens element profil1 / 19
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Patent office shaped.
In addition, can be achieved by the elongated design of the lens element that the first optical element can be designed with a comparatively large light exit area, through which the light emerges from the first optical element and further via the at least one elongated lens element in the second optical element occurs. In this way, an improved efficiency can be achieved.
Preferably, the at least one elongate lens element has a groove extending parallel to the longitudinal axis, which is designed for the entry of light and which is formed on one side of the second optical element, which faces the first optical element. A particularly effective passage of the light from the first optical element into the second optical element can be achieved through the groove.
Preferably, the groove extends on both sides to the edge of the second optical element. This allows a comparatively large light transition area to be achieved, so that a particularly high degree of efficiency can be achieved. In addition, easier manufacture of the lens element is possible if the groove extends all the way to the two end regions of the lens element.
Preferably, the at least one elongated lens element - viewed in a cross section normal to the longitudinal axis - has diverging outer boundaries. This shape enables particularly effective bundling of the light in the further level.
Preferably, the first optical element has at least one elongated structure aligned parallel to the longitudinal axis for the exit of the light. This shape makes it easier to manufacture the first optical element. For this purpose, for example, the elongated structure can be formed on both sides as far as the edge of the first optical element. In addition, a comparatively large light transition area between the two optical elements is made possible in this way.
Preferably, the design is such that - viewed in a normal projection on the plane - the at least one elongated structure and the at least one elongated lens element at least partially overlap, preferably the elongated structure lies within the projection of the at least one elongated lens element. In this way, a particularly low-loss light transition from the first to the second optical element can be achieved with an advantageous use of space.
Preferably, the design is further such that the elongated structure is arranged engaging in the groove. Furthermore, in a cross section normal to the longitudinal axis, the shape of the elongated structure is preferably congruent with the shape of the groove. This is also advantageous with regard to a particularly effective light transition. For example, viewed in a cross section normal to the longitudinal axis, the elongated structure can have a rectangular shape.
Preferably, the second optical element has a plurality of elongated lens elements which are arranged parallel to one another, preferably directly adjacent to one another. This allows a particularly large light-emitting surface of the second optical element to be produced.
Preferably, the first optical element has a plurality of elongated structures for the exit of the light, which are arranged parallel to one another, with each of the lens elements being assigned exactly one of the elongated structures. This is also advantageous in terms of efficiency.
According to a further aspect of the invention, an arrangement for light emission is provided which has a light source for generating light, and an optical system according to the invention. The arrangement is designed such that the light generated by the light source is influenced by the optical system.
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Patent Office [0018] The light source is preferably an LED light source. The optical system is particularly suitable for this.
Preferably, the arrangement also has at least one further light source, the design being such that the light from several sides enters the first optical element through the first-mentioned light source and the at least one further light source. In this way, a particularly homogeneous light can be emitted via the second optical element.
Preferably, the arrangement further comprises a reflector element which is arranged opposite the second optical element with respect to the first optical element.
The invention is explained below using an exemplary embodiment and with reference to the drawings. Show it:
Fig. 1 [0023] Fig. 2 [3] [0025] Fig. 4 [0026] Fig. 5 [0027] Fig. 6 [0028] Fig. 7 [0029] Fig. 8 [0030 9 shows a cross-sectional sketch of an arrangement according to the invention for emitting light, a sketch of a top view of a part of the arrangement, a perspective sketch of a corner region of the arrangement, a sketch corresponding to FIG. 3 in the manner of an exploded view , a perspective sketch of a larger area of the arrangement, a detail from the sketch of FIG. 5, a sketch of a plan view of part of the lateral edge area of the first optical element, a cross-sectional sketch around a light transition area between the two optical elements, a perspective Sketch of the arrangement and a perspective sketch of a variant of the arrangement in the manner of an exploded view.
1 shows a cross-sectional sketch of an arrangement for emitting light according to the invention, FIG. 2 shows a sketch of a top view of a part of the arrangement. The arrangement comprises an optical system according to the invention for influencing a light emitted by a light source 9. The light source 9 is part of the arrangement according to the invention.
The optical system comprises a first optical element 1, which is plate-shaped in a first approximation, so that a plane E is defined by its plate shape. In this description it is assumed that the first optical element 1 is oriented horizontally and accordingly the plane E is also oriented horizontally. In general, however, a different orientation of the first optical element 1 with respect to the vertical can also be provided for operating the arrangement. In this case, the present directions etc. have to be reinterpreted accordingly.
7 shows a detail from the sketch in FIG. 2. In the example shown, the light source 9 comprises a plurality of LEDs 91 arranged along a straight line, which are preferably arranged on a circuit board 92. The light source 9 is designed and positioned in such a way that the LEDs 91 lie in the plane E or are arranged to penetrate the plane E.
The first optical element 1 consists at least partially of a translucent material, for example, advantageously from a manufacturing point of view of a plastic. The first optical element 1 has a lateral edge region 11, which is designed for the entry of the light emitted by the light source 9.
9 is a perspective sketch of the arrangement in the manner of an exploded view 3/19
AT16319U1 2019-07-15 Austrian
Patent office shown. As can be seen, the first optical element 1, viewed in a top view, can have a rectangular shape in a first approximation, so that it has four edge sides, the side edge region 11 being formed on one of these edge sides. In the example shown, the first optical element 1 accordingly has a length 1 and a width b, the edge region 11 being formed on one of the two long sides.
Preferably, the circuit board 92 with the LEDs 91 extends along the edge region 11.
FIG. 5 shows a perspective sketch of a larger area of the arrangement and FIG. 6 shows a detail from the sketch of FIG. 5. In FIG. 6 the first optical element 1 is sketched transparently.
Furthermore, the optical system comprises a second optical element 2, which is also plate-shaped in a first approximation. The second optical element 2 consists at least partially of a translucent material, for example advantageously from a manufacturing point of view of a plastic.
The second optical element 2 is arranged parallel to the first optical element 1, in the example shown below the first optical element 1. The second optical element 2 has a light exit region 21 for the exit of the light.
The light exit region 21 is preferably formed on that of the two large surfaces, the second optical element 2, which is opposite the first optical element 1, here on the downward-facing surface of the second optical element 2. The design is preferably such that that the light exit region 21 extends over most of this area or is formed by this area.
The light exit area 21 or the downward-facing surface of the second optical element 2 is preferably designed to be flat. This enables particularly simple cleaning.
The light emitted by the light source 9 thus first reaches the first optical element 1 and then from there to the second optical element 2 and finally leaves the optical system via the light exit region 21. The optical elements 1, 2 can also be used in this respect be regarded as light guides.
The lateral edge region 11 of the first optical element 1 is designed to glare or focus the light in the plane E. In other words, the edge region 11 is designed in such a way that it reduces the opening angle of the light emitted by the light source 9 which lies in the plane E. For this purpose, the edge region 11 can have a plurality of lens-like light entry regions 6, the lateral boundaries of which are designed to diverge in a direction pointing away from the light source 9, in particular diverging in a convex shape. The LEDs 91 are preferably positioned very close to the light entry areas 6, so that a particularly large proportion of the light emitted by the LEDs 91 enters the first optical element 1 via the light entry areas 6.
In the example shown, the light entry regions 6 are advantageously shaped in terms of production technology in such a way that their contour is unchanged in a direction perpendicular to the plane E.
The configuration is preferably such that one LED 91 or a certain number of LEDs 91 each radiate their light into one of the lens entry regions 6. In the example shown, the design is such that two adjacent LEDs 91 each emit light into one of the light entry areas 6.
Preferably, the light entry areas 6 are designed such that they form a straight line, preferably in such a way that they adjoin each other directly. In particular, it can be provided that the light entry areas 6 extend over the entire length of the relevant edge side of the first optical element 1. A particularly suitable entry of light into the first optical element 1 can thus be brought about.
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Patent Office [0048] FIG. 3 shows a perspective sketch of a corner area of the arrangement, FIG. 4 shows a corresponding sketch in the manner of an exploded view. The second optical element 2 has an elongated lens element 3 which extends along a longitudinal axis L and which is designed to de-glare or bundle the light in a further plane E '- indicated in FIG. 2 - which at least in the Is oriented substantially perpendicular to the first-mentioned plane E. The further plane E 'is thus oriented parallel to the drawing plane of FIG. 1.
This configuration makes it possible for the light, when it leaves the arrangement through the light exit region 21, to be bundled or glare-free in the two planes E, E '. The expression at least substantially perpendicular is intended to mean in particular that the two planes E, E 'mentioned form an angle which is between 80 ° and 90 °. This is particularly advantageous, for example, if the arrangement is used as a light source for a lamp, for example in the form of a ceiling lamp or pendant lamp.
In the example shown, the lens element 3 or the longitudinal axis L extends parallel to the lateral edge region 11 or parallel to the row of LEDs 91.
Preferably, the lens element 3 has a groove 4 which extends parallel to the longitudinal axis L and is designed for the entry of the light and which is formed on a side of the second optical element 2 which faces the first optical element 1, here that is, on the top of the lens element 3.
The first optical element 1 preferably has an elongated structure 5 aligned parallel to the longitudinal axis L for the exit of the light. Advantageously in terms of production technology, the elongated structure 5 can be designed in profile form. In particular, the elongated structure 5 can be formed in one piece with the remaining first optical element 1.
Preferably, the elongated structure 5 is arranged to engage in the at least one groove 4. In this way, a particularly low-loss transition of the light from the first optical element 1 into the second optical element 2 can be achieved.
A particularly simple manufacture of the second optical element 2 is made possible if the lens element 3 is shaped in profile, so that its profile axis extends parallel to the longitudinal axis L. Furthermore, the groove 4 advantageously extends over the entire length of the lens element 3. Accordingly, the elongated structure 5 is preferably at least as long, in particular as long, as the groove 4.
8 shows a detail from the sketch of FIG. 1 on an enlarged scale. Accordingly, the lens element 3 is shown here in a cross section normal to the longitudinal axis L. The lens element 3 has — viewed in this cross section — diverging outer boundaries 31 in the direction of the light exit region 21, wherein the outer boundaries 31 can in particular have a concave shape. This allows a particularly suitable bundling of the light in the further plane E '.
Preferably, viewed in cross section normal to the longitudinal axis L, the shape of the elongated structure 5 is at least approximately congruent with the shape of the groove 4. For example, the structure 5, as indicated in FIG. 8, can have a rectangular cross section. Accordingly, the groove 4 can likewise have a rectangular cross section or, as outlined, a trapezoidal one, which is advantageous with regard to the positioning of the structure 5 in the groove 4. In principle, however, other cross sectional shapes are also possible here, such as semicircles or the like.
The extension of the second optical element 2 parallel to the longitudinal axis L preferably corresponds to the longitudinal extension of the lens element 4. In this case, the groove 4 advantageously extends on both sides to the edge of the second optical element 2.
As indicated in Fig. 2 with broken lines, the design is preferably such that - viewed in a normal projection on the plane E - the
5.19
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Patented elongated structure 5 and the elongated lens element 3 at least partially overlap, in particular such that the elongated structure 5 lies within the projection of the at least one elongated lens element 3. In this way, with particularly good use of the area, a particularly suitable passage of light from the first optical element 1 into the second optical element 2 can be brought about.
The second optical element 2 preferably has a plurality of parallel and analog, in particular identical lens elements 3, 3 'and the first optical element 1 preferably has a plurality of parallel and analog, in particular identical elongated structures 5, 5', wherein in each case one of the lens elements 3, 3 'is designed to interact with exactly one of the elongated structures 5, 5' as described above. Accordingly, the design is preferably such that the number of lens elements 3, 3 'is the same size as the number of elongated structures 5, 5'.
The described intervening arrangement of the elongated structures 5, 5 'in the grooves 4 of the lens elements 3, 3' makes it possible to achieve very efficient light transfer. Ideally, therefore, virtually all of the light that leaves the first optical element 1 via the structures 5, 5 ′ can enter the second optical element 2 via the grooves 4.
Preferably, the second optical element 2 can consist of the lens elements 3, 3 '.
As is the case in the example shown, the lens elements 3, 3 'are designed such that the light exit region 21 is formed by their surfaces, which lie opposite the grooves 4. In this way, the light exit region 21 can be designed to be particularly large and coherent.
According to the sketch from FIG. 1, the second optical element 2 has ten lens elements 3, 3 '. In the embodiment shown in FIG. 9, there are significantly more. In principle, the number of lens elements 3 can be chosen freely. The same applies analogously with regard to the number of light entry areas 2 of the lateral edge area 11 of the first optical element 1. In this regard, the sketches of FIGS. 1 and 2 are intended to illustrate the principle of the optical system.
As indicated in FIG. 1, the design is further preferably such that, viewed in cross section normal to the longitudinal axis L, the first optical element 1 extends closer to the light source 9 than the second optical element 2. For example, it can be provided that between the second optical element 2 and the light source 9 is formed a distance a measured parallel to the plane E, which is for example at least as large as the corresponding width β of the edge area 11 or the light entry areas 6. For example, that the following relation applies: ß <a <5 ß.
This configuration makes it possible for the light from the LEDs 91 to mix to a certain extent before it enters one of the elongated structures 5, 5 '. In this way, a correspondingly advantageous, uniform mixing of the LED light can be achieved. This is particularly relevant, for example, if the light differs from that of the LEDs 91 which radiate their light into one of the light entry areas 6, for example with regard to the color or the color temperature of the light. For example, it can be provided that two adjacent LEDs 91 each radiate their light into one of the light entry areas 6, one of the two LEDs 91 emitting a cold white light and the other LED 91 a warm white light. Appropriate control of the LEDs 91 advantageously allows the color temperature of the light emitted by the arrangement to be adjusted.
The elongated structures 5, 5 'are preferably designed in such a way that - viewed normal to the longitudinal axis L - they extend comparatively close on both sides to the edge of the first optical element 1. This is advantageous with regard to the formation of a particularly large light exit region 21. For example, it can be provided that the two edge-side structures 5, 5 'viewed from the corresponding edge of the first one
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Patentamt optical element 1 each have a distance that is less than three times the width β of the edge region 11, preferably less than twice the width β of the edge region 11.
As sketched for example in Figures 1 or 9, the arrangement preferably further has a further light source 9 ', which is arranged with respect to the first optical element 1 of the first-mentioned light source 9, the design with reference to the Irradiation of the light in the first optical element 1 is analog. Accordingly, in this case the first optical element 1 preferably has a corresponding further edge region 11 ', formed analogously to the first-mentioned edge region 11, which lies opposite the first-mentioned edge region 11 and for bundling or glare-free radiation emitted by the further light source 9' Light in level E is used.
Accordingly, as indicated in FIG. 1, the second optical element 2 preferably has a width b 'which is slightly smaller than the width b of the first optical element 1.
Alternatively, it can be provided, for example, that the arrangement on a side of the first optical element 1 opposite the light source 9 has a reflector element which serves to reflect back the light impinging there; this can increase the efficiency.
As partially indicated in FIG. 10, it can generally also be provided that the arrangement has four corresponding light sources, which are each arranged on one of the four edge sides of the first optical element 1. In the variant outlined, the first optical element 1 furthermore has line structures 15 for generating diffuse light; For this purpose, the line structures 15 are preferably parallel to one another and perpendicular to the longitudinal axis L. For example, as can be seen in FIG. 10, the line structures 15 can be designed such that they each extend to one of the boundaries between two adjacent light entry regions 6.
As can be seen, for example, from FIG. 4, the light source 9 can be designed such that the LEDs 91 are arranged in a repeating pattern. In principle, however, an uneven arrangement of the LEDs 91 can also be provided, for example in such a way that distances between the LEDs 91 to the two boundaries of the circuit board 92 increase. This can be advantageous with respect to the most uniform possible light distribution in the first optical element 1, for example in the case of the four-sided light irradiation into the first optical element 1 mentioned above.
In the corresponding figures, the elongated structures 5, 5 'of the first optical element 1 are outlined as elements which protrude from the underside of the first optical element 1. This is advantageous with regard to the described high efficiency of light transfer. However, it can alternatively be provided that instead of corresponding protruding elements, only the corresponding areas of the underside of the first optical element 1 are designed to be roughened, so that the light can emerge from the first optical element 1 and subsequently enter the second optical element 2 can. It should be noted here, however, that a correspondingly rough surface generally counteracts the bundling of light in plane E. From this point of view, too, the protruding structures 5, 5 ′ shown are generally more advantageous.
As can be seen, for example, from FIG. 1, it can be provided that the lens elements 3 are all constructed identically and are arranged at equal mutual distances, for example, directly adjacent to one another.
In general, however, it can also be provided that the lens elements 3 are not arranged uniformly, but, for example, in such a way that they are arranged in a direction toward the light source 9 with decreasing density — viewed in cross section normal to the longitudinal axis L. This can be advantageous with regard to a uniform light emission of the arrangement.
7.19
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Patent Office A similar effect can also be achieved in that the lens elements 3 are of different sizes than, for example - viewed in cross-section normal to the longitudinal axis L - in a direction towards the light source 9 with decreasing size.
In this sense, the same also applies analogously to the elongated structures 5, 5 'of the first optical element 1. In other words, their size or density can be designed to decrease in the direction of the light source 9.
As indicated in the right-hand area of the sketch in FIG. 1, the arrangement can furthermore have a reflector element 8, for example in the form of a highly reflective film, which is arranged opposite the second optical element 2 with respect to the first optical element 1, here on the top of the first optical element 1. This is generally advantageous in terms of efficiency.
However, the reflector element 9 is only optional. For example, it can be provided that the arrangement is constructed such that there is no further component of the arrangement above and below the two optical elements 1, 2, at least above and below a central region of the two optical elements 1, 2. If the arrangement is used according to this embodiment with a pendant lamp, it can be achieved that a view through the two optical elements 1, 2 is made possible from below to the ceiling above.
With the design described, in particular a light exit area 21 can be achieved which has a particularly large area for a given width of the system. The system or the arrangement is also suitable in the case of an overall comparatively small width. However, an overall comparatively large light exit area 21 can also be suitably implemented.
Another advantage of the embodiment according to the invention is that the two optical elements 1, 2 can be produced relatively easily. For example, the first optical element 1 and / or the second optical element 2 can be made of plastic.
The two optical elements 1, 2 only have to be placed one on top of the other for the intended mode of operation. No additional mechanical connection is required, for example no gluing or the like.
In addition, due to the plate shape of the two optical elements 1, 2, an overall very low overall height of the optical system and thus also the overall arrangement can be achieved.
Because the elongated structures 5, 5 'and the lens elements 3, 3' are designed parallel to one another, there is no moiré effect on the light exit region 21.
The arrangement is particularly suitable for use in a lamp, for example in a pendant lamp, a surface-mounted lamp or a recessed lamp.
It is not necessary to provide a cover or a film or the like for the arrangement.
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权利要求:
Claims (11)
[1]
1.9
11/19
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CM d>
IhJL · "
12/19
P5
Λ6
, _t w &
© ff / ·
CA ₂ 0Λθ, -ϋί
t T>
CP
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A9
A3
Λ6
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1. An optical system for influencing a light emitted by a light source (9), comprising:
- A first optical element (1) which is plate-shaped in a first approximation, so that a plane (E) is defined by the first optical element (1), the first optical element (1) being a lateral one designed for the entry of the light Edge area (11),
- A second optical element (2) which is plate-shaped in a first approximation, the second optical element (2) being arranged parallel to the first optical element (1) and having a light exit region (21) for the exit of the light, characterized in that the lateral edge region (11) of the first optical element (1) is designed to glare or focus the light in the plane (E) and that the second optical element (2) has at least one elongated lens element (3) which extends along a longitudinal axis (L) and is designed to glare or focus the light in a further plane (E ') which is oriented at least substantially perpendicular to the first-mentioned plane (E).
[2]
2. Optical system according to claim 1, characterized in that in which the at least one elongate lens element (3) has a groove (4) which extends parallel to the longitudinal axis (L) and is designed for the entry of light and which is on one side the second optical element (2) is formed, which faces the first optical element (1); and / or in which the at least one elongate lens element (3) - viewed in a cross section normal to the longitudinal axis (L) - has diverging outer limits (31).
[3]
3 ^ 9
.σΜ ⁵
3 ^ 9
2tf 9, 0-7
Λ5
Αδ
AT16319U1 2019-07-15 Austrian
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3. Optical system according to claim 2, characterized in that in which the groove (4) extends on both sides to the edge of the second optical element (2).
[4]
4. Optical system according to one of the preceding claims, characterized in that in which the first optical element (1) has at least one elongated structure (5) aligned parallel to the longitudinal axis (L) for the exit of the light; and / or that the second optical element (2) has a plurality of elongated lens elements (3, 3 ') which are arranged parallel to one another and preferably directly adjoining one another.
[5]
5. Optical system according to claim 4, characterized in that the optical system is designed such that - viewed in a normal projection onto the plane (E) - the at least one elongated structure (5) and the at least one elongated lens element (3 ) overlap at least partially, preferably the elongated structure (5) lies within the projection of the at least one elongated lens element (3).
[6]
6.9
16/19 Austrian AT 16 319 U1
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2019-07-15
6. Optical system according to claim 4 or 5, depending on claim 2, characterized in that the optical system is designed such that the elongated structure (5) is arranged engaging in the groove (4).
[7]
7.9
17/19 Austrian
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AT16319U1 2019-07-15
7. Optical system according to claim 6, characterized in that - viewed in a cross section normal to the longitudinal axis (L) - the shape of the elongated structure (5) is congruent with the shape of the groove (4); and / or that - viewed in a cross section normal to the longitudinal axis (L) - the elongated structure has a rectangular shape.
[8]
8.9
18/19
κθ ⁶
8. Optical system according to claim 4, characterized in that the first optical element has a plurality of elongated structures (5, 5 ') for the exit of the light, which are arranged parallel to one another, each of the lens elements (3,3') exactly one of the elongated structures (5, 5 ') is assigned.
[9]
9. Arrangement for light emission, having
- A light source (9) for generating light and
- An optical system according to one of the preceding claims, characterized in that the arrangement is such that the light generated by the light source (9) is influenced by the optical system.
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[10]
10/19
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10. Arrangement for emitting light according to claim 9, characterized in that the light source (9) is an LED light source; and / or that the arrangement further comprises at least one further light source (9 '), the design being such that the light enters the first optical element (1) from several sides through the light sources (9, 9'); and / or that the arrangement has at least one further light source (9 '), the design being such that the light enters the first optical element (1) from several sides through the light sources (9, 9').
9 sheets of drawings
[11]
11¾¾. Austrian patent office

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DE202019106804U1|2021-03-09|Optical system for influencing the light output of an elongated light source

AT16042U1|2018-12-15|Optical element and arrangement for emitting light with an optical element

WO2021058167A1|2021-04-01|Luminaire having a region for emitting light over a surface

DE102017202123A1|2018-08-16|Light guide plate and luminaire with this light guide plate

EP2787271A1|2014-10-08|Lighting device with asymmetric radiation

同族专利:

公开号 | 公开日

EP3283820A1|2018-02-21|

CN107533186A|2018-01-02|

WO2016166203A1|2016-10-20|

US10162097B2|2018-12-25|

EP3283820B1|2021-06-23|

US20180081106A1|2018-03-22|

DE202015101870U1|2016-07-19|

CN107533186B|2020-02-14|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

DE202015101870.3U|DE202015101870U1|2015-04-16|2015-04-16|Optical system and arrangement for emitting light|

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