Abstract
Optics (20) for an illumination device (1), as well as an illumination device (1) comprising such optics. The optics comprise at least one lens (30) with a light entry surface (31) and a light exit surface (32). A stepped lens structure (321), such as a Fresnel structure, is formed on the light exit surface. A recurring surface structure, such as periodically arranged prominences (311) and deepenings (321), are formed on the light entry surface (31).
Claims
1-22. (canceled)
23. An optics (20) for an illumination device (1) comprising: at least one lens (30) with a light entry surface (31), and a light exit surface (32), wherein a stepped lens structure (321) is formed on the light exit surface, and a recurring surface structure of prominences (311) and deepenings (321) is formed on the light entry surface (31).
24. The optics (20) according to claim 23, wherein the prominences (311) and the deepenings (312) are arranged parallel to one another.
25. The optics (20) according to claim 23, wherein the prominences (311) and deepenings (312) are arranged uniformly distanced at a distance (A) of less than 1 mm.
26. The optics (20) according to one of the claim 23, wherein the prominences (311) and deepenings (312) from a highest point to a deepest point have a distance (T) of less than 1 mm.
27. The optics (20) according to claim 23, wherein the prominences (311) and the deepening (312) are designed in a sinusoidal manner.
28. The optics (20) according to one of the claim 23, wherein the light entry surface (31) and the light exit surface (32) are connected by two connecting walls (41, 42) which are uniformly distanced from one another.
29. The optics (2) according to claim 28, wherein the two connecting walls (41, 42) have a reflection degree of larger than 90%.
30. The optics (20) according to claim 28, wherein the two connecting walls (41, 42), at least over a part-region of their extension from the light entry surface (31) to the light exit surface (32), are connected to one another via two diverging additional walls (51, 52) which are arranged in a diverging manner from the light entry surface (31) to the light exit surface (32).
31. The optics (20) according to claim 30, wherein the two diverging walls (51, 52) have a reflection degree of larger than 90%.
32. The optics (20) according to claim 23, wherein the light entry surface (32) comprises a bulging or a deepening which dominates the surface structure.
33. The optics (20) according to claim 23, comprising at least two lenses are successively arranged along the uniformly distanced connecting walls (41, 42)
34. The optics (20) according to claim 33, wherein the at least two lenses (30) are arranged at a distance from one another, and the distance is at least half a distance from the light entry surface (31) to the light exit surface (32).
35. The optics according to claim 34, wherein a first lens (30′) and a second lens (30″) are designed as end lenses.
36. The optics (20) according to claim 33, wherein the at least two lenses (30) are designed as one piece.
37. The optics (20) according to claim 23, wherein the optics comprise a plurality of fastening elements and at least one fastening element is assigned to each lens (30).
38. The optics (20) according to claim 23, wherein a diffuser (6) is arranged subsequently to the light exit surface (32).
39. The optics (20) according to claim 38, wherein the diffuser (60) has Lambert-shaped scatter characteristics.
40. The optics according to claims 38, wherein the diffuser is arranged in a diffuser housing (61) and at least one lens (30) is fastened to the diffuser housing (61).
41. An illumination device (1) comprising a light source and one or more optics (20) according to claim 23.
42. The illumination device (1) according claim 41, wherein the light source comprises a light module (70) with one or more LEDs which are arranged thereon.
43. The illumination device (1) according to claim 42, wherein an LED is assigned to each lens (30).
44. The illumination device (1) according to claim 42, wherein each LED is designed as an RGB LED.
45. The optics (20) according to claim 23, wherein the stepped lens structure (321) comprises a Fresnel structure.
46. The optics (20) according to claim 23, wherein the prominences (311) and deepenings (321), formed on the light entry surface (31), are periodically arranged.
Description
[0090] One embodiment is explained hereinafter by way of schematic figures. There are shown in:
[0091] FIG. 1: a perspective representation of a lens;
[0092] FIG. 2: a sectioned view of the lens of FIG. 1;
[0093] FIG. 3: a view upon the lens exit surface of FIG. 1;
[0094] FIG. 4: a view upon the lens entry surface of FIG. 1;
[0095] FIG. 5: a sectioned view through the light entry surface of FIG. 4;
[0096] FIG. 6: a perspective view of an array of lenses;
[0097] FIG. 7: a lateral view of the array of FIG. 6;
[0098] FIG. 8: a detailed view of FIG. 4;
[0099] FIG. 9: a perspective view of a section of an illumination device;
[0100] FIG. 10: a lateral view of the illumination device of FIG. 9;
[0101] FIG. 11: a lateral view of an array of lenses.
[0102] FIG. 1 shows a perspective view of a lens 30 of optics 20. It is to be understood that the lens 30 itself can already represent the optics 20, but preferably yet further optical elements such as diffusers can yet also be taken into account as part of the optics 20 (for this see FIG. 9 and following). The lens 30 comprises a light entry surface 31 and a light exit surface 32. These are connected to one another via a lens body which is not described in more detail. Herein, it is conceivable for the lens body to be constructed in a multi-part manner, but a single-part construction is preferred. The lens body here comprises two uniformly distanced walls 41 and 42 which connect the light entry surface 31 to the light exit surface 32. These two walls 41, 42 are connected to one another by way of two diverging walls 51 and 52. The lens 30 has a length L and a width B which are defined by the longitudinal extension L1 and width B1 (see FIG. 3) of the light exit surface 32. The beam path S extends from the light entry surface 31 to the light exit surface 32. The light entry surface 31 and the light exit surface 32 are arranged essentially at right angles with regard to this beam path S.
[0103] The essentially uniformly distanced walls 41 and 42 have a reflection degree of 96%. The diverging walls 51 and 52 also have a degree of reflection of 96%. The reflection degrees are however preferably higher.
[0104] A surface structure which is not shown in more detail here and which here is formed from sinusoidal prominences and deepenings (see FIGS. 4 and 5) are formed on the light entry surface 31.
[0105] A stepped lens structure which is not shown in more detail in this figure is formed on the light exit surface 32 (see FIGS. 2 and 3).
[0106] FIG. 2 shows a sectioned view in the direction of the length L through the beam path S of the lens of FIG. 1. In FIG. 2 it is evident that the lens 30 is designed essentially centrally symmetrically to the beam path S. The diverging walls 51 and 52 are arranged at an angle α and α′ to one another at both sides of the beam path S. Here, the angle a corresponds to the angle α′. The angles α and α′ together are 77°.
[0107] The surface structure of the light exit surface 32 is clearly recognisable. This surface structure is designed essentially accordingly the principle of a Fresnel structure but in a manner such that the individual scatter lenses do not meet at a single focal point but in a manner such that the focal points are distributed at least partly along the length L2 (see FIG. 4).
[0108] The surface structure of the light entry surface 31 is practically not visible in FIG. 2 on account of its smaller size.
[0109] Likewise drawn in FIG. 2 is the height H of the lens 30 which is defined by the distance of the respective geometrical middles of the light entry surface 31 and the light exit surface 32.
[0110] FIG. 3 sows a plan view upon the light exit surface 32. What is clearly recognisable in FIG. 3 is the essentially circular arrangement of the individual stepped lenses around the beam path S (for this see FIG. 1). The light exit surface 32 and hence the structure which is arranged thereon has a length L1 and a width B1. The length L1 here corresponds approx. to tenfold the width B1.
[0111] FIG. 4 shows a view upon the light entry surface 31. The light entry surface 31 has a width B2 and a length L3 which are defined according to the length L and the width B of the lens 30 (for this see FIG. 1). Prominences 311 and deepenings 312 which extends essentially from the first wall 41 to the second wall 42 are formed on the light entry surface 31 in a region with a surface structure. The prominences 311 and deepenings 312 form a uniform surface structure. The lens body extends over this region in the plane of the light entry surface 31 on both sides of this region of the light entry surface 31. Here, the lens body has a length L3 which is larger than the length L2 of the region. This widening subsequently merges into the diverging wall 51 or into the diverging wall 52.
[0112] FIG. 5 shows a sectioned view through the surface structure of FIG. 4 along the beam path S in the direction of the length L (see FIG. 1). The surface structure is formed from sinusoidal deepenings 312 and sinusoidal prominences 311. These deepenings 312 and prominences 311 are arranged in a periodic manner at a distance A of 135 μm. The highest point of the prominence 311 to the deepest point of the deepening 312 has a distance T which is 50 μm.
[0113] FIG. 6 shows a perspective and schematic view of a detail of an array of several lenses 30 which together form simple optics 20. The transition between the individual lenses 30 is only represented in a simplified manner. The lenses 30 are connected to one another as one piece at their broad sides (see FIG. 1). The connection extends over a height H1 which corresponds to a quarter of the height H. This connection can however be designed for example as a web, on which likewise fastening elements for fastening the lens or the array are arranged (see for example FIG. 11).
[0114] FIG. 7 show a lateral view of a detail of the array of FIG. 6. A light beam is drawn in at the light entry surface 31 for a first lens 30 (shown at the left in FIG. 7). This is congruent with the central beam path S. This individual light beam is refracted at the light entry surface 31 by the surface structure and is fanned out in a wide manner and is distributed within the lens body. Such a distribution is also to be found in the second represented lens 30 (show at the right in FIG. 7). The light beam of the second lens 30 is now arranged offset with respect to the central beam path S. Here, it can be clearly recognised that on the one hand the positioning of a light source to the central beam path is of less relevance, and on the other hand light which is fed in edge regions is also widely fanned out. The individual light beams or light bundles after the passage of the light entry surfaces 31 have an essentially fan-like distribution. This is represented as a whole by hatchings, in other words the lens body is flooded with light in large regions.
[0115] Concerning these two lenses 30, the associated light exit surface 32 is likewise drawn in. In the region of the connection of these two lenses 30, it is likewise evident that the respective light bundles overlap, represented by the overlapping of the hatchings. In other words a light bundle of a light source, represented by an arrow at the light entry surface 31, of a first lens 30 beams to into the light exit surface of a second lens 30 and vice versa. Thus the light density is increased in these overlapping regions and a weakening of the light intensity which typically occurs at a radial distance to the beam path is compensated. The uniform light intensity or light density by way of example is represented by two shorter light beams which are drawn in the region of the overlapping, which however have a higher density.
[0116] FIG. 8 shows a detailed view of the surface structure of FIG. 4. Represented schematically are individual light beams of the light source which are refracted at the surface structure 31. A fanning-out takes place by way of the continuous change of the angle of incidence of a light beam on the surface of the surface structure, relative to the light source.
[0117] FIG. 9 shows a perspective view of a section of an illumination device 1. The illumination device 1 comprises an array of several lenses 30 and a diffuser 60. The array of the lenses 30 together with the diffuser 60 forms optics 20. The diffuser 60 is fastened in a diffuser housing 61. The array of the lenses 30 here is fastened to the diffuser housing 61 by way of fastening elements which are not shown here in more detail. A light module 70, on which several LEDs 71 are arranged is assigned to these optics 20. The light module 70 comprises one LED 71 per lens 30. The light module 70 in turn is connected to the diffuser housing 61 by way of fastening means which are not represented in detail. The illumination device 1 can be arranged for example in a steering wheel of a vehicle. By way of such an illumination device 1, certain information can be conveyed to the user and in the present case to the driver of the vehicle. For example, the turning of the vehicle can be optically represented. By way of a suitable activation of the light module 70, circumstances, for example that the vehicle is presently being overtaken by a further vehicle can be also possibly conveyed. In particular, given the provision of the individual LEDs as RGB LEDS, additionally with a representation for example via the colours red or green one can indicate to the driver whether an overtaking of another vehicle is presently possible or not, or whether for example an obstacle is located to the left or right next to the vehicle.
[0118] FIG. 10 shows a lateral view of the illumination device 1 of FIG. 9. An individual LED 71 is represented on the light module 70. The LED radiates into the lens 30, wherein a diffuser 60 is arranged subsequently to this. As is evident from FIG. 10, the LED 71 can be displaced in the arrow direction relative to the lens 30 without a noticeable change of the emitted light being effected at the exit of the diffuser 60. On account of a linear design of the surface structure of the light entry surface 31 (for this see FIG. 4) the LED 71 likewise in the representation according to FIG. 10 can be moved in the direction of the plane of the sheet, thus into the sheet or out of the sheet without having a significant influence on the light which is emitted from the diffuser 60.
[0119] FIG. 11 shows a lateral view of the array of FIG. 6, wherein more details are evident in this representation compared to the representation in FIG. 6. The optics 20 comprise several lenses 30, wherein for the purpose of a better overview not all elements are provided with reference numerals.
[0120] The optics comprise several fastening elements 33, wherein these fastening elements 33 are each arranged at the transition between two lenses 30.
[0121] The transition between the individual lenses 30 is shown here in a detailed manner. The lenses 30 at their broad sides (see FIG. 1) are connected to one another as one piece. The connection is designed as a web, on which the fastening elements 33 are arranged for fastening the array of lenses 30.
[0122] Each of the lenses 30 comprises a light entry surface 31 and a light exit surface 32. These are designed according to the light entry surfaces 31 and light exit surfaces 32 as are described with regard to the remaining figures. These light entry surfaces 31 and light exit surfaces 32 are essentially each arranged in a common plane and are connected to one another via the walls 41 and 42 which are essentially uniformly distanced to one another. Furthermore, each lens comprises two diverging walls 51 and 52 which each extend up to one of the webs which connect the lenses 30. The lenses 30, seen from a plan view, are arranged on a circular arc, so that they can be arranged for example in a steering wheel.
