The present invention relates to a lighting module comprising strips of light sources. A field of the invention is more particularly, but not limitedly, that of lighting modules comprising strips of LED.
Such a module can enable a background light to be created for example in a room or as an overhead light of a motorcar. An application area of the invention can for example be in particular that of lighting of shelf in furniture contents, or lighting of a room in replacement of a set of neon tubes.
Such a module can also enable various objects to be backlit, for example a small tag in a supermarket department or a large advertising poster in a street. An application area of the invention can for example be more particularly that of backlighting commercial signs, advertising posters or roadsigns, or even that of backlighting LCD screens in particular large size screens.
Lighting modules comprising LED (Light Emitting Diode) rows are known, such as for example described in document WO 2009/125104.
Such a module comprises a light guide and, inside the light guide, at least one row of LED emitting light along a main direction which is contained in the light guide.
In such a module, an issue of homogeneity of the light emitted by this module is often met. Indeed, most often:
The object of the invention is to solve at least partly this issue of homogeneity of the light exiting from such a lighting module.
This purpose is achieved with a lighting module comprising:
The emitting sources are preferably located inside the light guide.
Each strip of sources preferably comprises at least one row of aligned sources. In particular, each strip of sources can comprise at least one row of light sources emitting light substantially in a same direction of emission. Each strip of sources can further comprise a second row of light sources, the sources of the first row preferably emitting light in a direction of emission substantially opposite to a direction of light emission of the sources of the second row. Both rows of sources can be arranged so that the sources of the first row are, with respect to the sources of the second row:
According to a first aspect of the invention, the module according to the invention preferably comprises for each light source, a transmitting reflector associated with this source and having a reflecting face directed towards the transmitting face so that the transmitting reflector associated with this source is located between the transmitting face and an emitting surface of this source arranged for the output out of the source of the light emitted by this source.
Each transmitting reflector is preferably a reflector comprising a reflecting white layer, or can possibly comprise a metal reflector.
Each transmitting reflector can be integrated in the module so that there is no intermediate space, in particular no vacuum, air or gas space, between the light guide and each transmitting reflector.
Each transmitting reflector can have a convex shape towards the transmitting face.
According to a second aspect of the invention, the module according to the invention preferably comprises for each light source a return reflector, associated with this source, and having a reflecting face directed towards the return face so that the emitting surface of this source is located between the return reflector associated with this source and the return face.
Each return reflector can be a reflector having a reflecting white layer, or can be a metal reflector.
For each source, the reflecting face of the return reflector associated with this source can be tilted so that the distance between the return face and this reflecting face is increasing as the distance from the strip carrying this source increases.
For each strip of sources, the return reflectors of the different sources can form:
Each reflecting strip is preferably provided, along its edge farthest from the light sources of this strip of sources, with a non-reflecting dark strip arranged to absorb light emitted by the sources.
For each light source, the transmitting reflector and return reflector associated with a same source are preferably located on two opposite faces of a same object such as a film or profile.
Each strip of sources can comprise a power supply circuit carrying the sources of this strip of sources, and:
According to another aspect of the invention, a method is provided for making a module according to the invention, characterised in that it comprises the following steps:
If transmitting reflectors and return reflectors are both present, then, for each assembly, the transmitting reflectors and return reflectors associated with all the sources of an assembly are preferably located on two opposite faces of a same object such as a film or a profile.
The surface bounding the return face is preferably in contact with each assembly.
The surface bounding the transmitting face is preferably not in contact with any assembly.
Each strip of sources can comprise at least one first row of light sources emitting light substantially in a same direction of emission, and further a second row of light sources (preferably parallel to the first row), the sources of the first row emitting light in a direction of emission substantially opposite to a direction of light emission of the sources of the second row.
Each assembly can further include a power supply carrying the sources of the strip of sources of this assembly.
In this case:
Both surfaces can be connected by a seal closing the space.
Further advantages and features of the invention will appear upon reading the detailed description of implementations and embodiments in no way limiting, and in the following appended drawings wherein:
These embodiments being in no way limiting, alternatives of the invention could in particular be considered which only comprise a selection of characteristics described in the following isolated from the other described characteristics (even if this selection is isolated within a sentence comprising these other characteristics), if this selection of characteristics is sufficient to provide a technical advantage or differentiate the invention with respect to the state of prior art. This selection comprises at least one preferably functional characteristic without structural details, or with only part of the structural details if only this part is sufficient to provide a technical advantage or to differentiate the invention with respect to the state of prior art.
It will be first described, in reference to
The module 1 can be used for:
The lighting module 1 comprises several parallel strips 7 of light emitting sources 2. Besides its own sources 2, each strip 7 comprises a power supply printed circuit 10 carrying the sources 2 of this strip 7 and arranged to electrically power these sources 2. This circuit 10 is typically:
Each source 2 is a LED (Light Emitting Diode). Each of the emitting sources 2 is a “side view” type LED, that is an emitting source arranged to emit light in a direction of emission 9 or 29 substantially parallel to the portion of the circuit 10 carrying said emitting source. These sources have a typically thickness between 0.2 millimetre and 2 millimetres, and can for example comprise “side view” LED model no NSSW208T thickness 0.8 mm or NSSW105T thickness 0.5 mm from Nichia Corporation.
In the present embodiment, each strip 7 only comprises two rows 17, 18 of sources 2: a first row 18 of sources 2 which are arranged to emit light substantially in a same direction of emission 9, and a second row 17 of sources 2 which are arranged to emit light substantially in a same direction of emission 29, the sources 2 of the first row emitting light in a direction of emission 9 substantially opposite to the direction of emission 29 of the sources of the second row. Each direction of emission 9 or 29 of a source 2 is a direction to which is centred the solid angle of emission of the light emitted by this source 2. Each direction of emission 9 or 29 is parallel to the return face 5. Each direction of emission 9 or 29 is parallel to the transmitting face 4.
The module 1 further comprises a light guide 3 comprising:
Each face of the return 5 or transmitting 4 face can be structured, that is provided with relief structures such as for example structures of side by side spherical caps or pyramids about 1 mm high and about 3 mm wide.
The emitting sources 2 are located inside the light guide 3 between the transmitting face 4 and the return face 5. The emitting sources 2 are inserted inside the guide 3 from the return face 5.
Each source 2 is arranged to emit light along a direction of emission contained in the light guide 3.
The light guide 3 comprises two parts:
Upon making the module 1, each cavity is initially empty, and is then filled with a transparent filling material, said filling material being initially liquid or pasty and solidified after the emitting sources are inserted into the cavities 3b. Thus, the emitting sources 2 are located in the guide 3 without intermediate space between the guide 3 and the emitting sources 2, in particular without air space. The material of the guide 3 preferably comprises PMMA (polymethylmethacrylate), polycarbonate (PC) and/or polyester. The thickness of the guide 3 is for example 4 millimetres (typically between 0.3 mm and 10 mm). This filling is optional but is very advantageous, because it improves a lot the coupling, inside the rest 3a of the guide, of the light emitted by the sources 2. This filling material is preferably the same as the material of the main part 3a.
The printed circuits 10 further comprise electrical resistors (not represented in the figures) electrically connected to the emitting sources 2, typically one resistor per group of three LED type emitting sources. Typically, there is one resistor per group of four LED type emitting sources and for a direct current 14V power supply.
The light sources are advantageously driven by an electronic driver, for example of the NUMEN Technology brand, for example reference NU501 of the SOT 23-3, SOT 23-5 or SOT 89-3 types.
The guide 3, that is the main part 3a and the cavities 3b, is preferably made according to a method such as described in document WO 2009/125104 or preferably by extrusion such as described in French patent application no 1053733.
The module 1 further comprises means 6 for returning to the inside of the guide 3 the light emitted by the emitting sources 2, said returning means 6 being provided on the return face 5 side. This means typically comprises:
Thus, according to the invention, moister or dust can be prevented from infiltrating between the return face 5 and the reflecting means 6.
Moreover, the use according to the invention of the reflecting film or a painting or ink on the return face, with respect to the use according to the state of prior art of laser etched grooves:
The return means 6 are plated or glued against the return face 5, without intermediate space or at least mostly (that is for more than 50% of the area) without intermediate space, in particular no vacuum, air or gas space, between the return means 6 and the return face 5.
Each direction of emission 9 or 29 of the source 2 does not intersect, starting from this source 2, the transmitting 4 or return 5 face by being perpendicular to that face, but rather is either substantially parallel to the transmitting 4 or return 5 face, or slightly oblique to the transmitting 4 or return 5 face.
The guide 3 has substantially a plate shape comprising two opposite faces bordering the guide: the substantially planar transmitting face 4 and the substantially planar return face 5. This plate is flexible, and can be flattened or assume curved shapes. The transmitting face 4 is arranged to let the light emitted by the emitting sources 2 inside the guide 3 through and transmit out of the guide 3 to an object to be lit. The object to be lit is located out of the guide 3, on the transmitting face 4 side with respect to the guide 3. As a particular lighting type, this object can be backlit, that is it is located between the viewer and the guide 3. The return face 5 faces the transmitting face 4. The return face 5 is substantially parallel to the transmitting face 4. The guide 3 further comprises a boundary surface 8 (also called side edges) connecting the transmitting face 4 to the return face 5, so that the emitting sources 2 are located inside the guide 3 by being surrounded by the boundary surface 8.
The module 1 further comprises for each light source 2 a transmitting reflector 12 associated with this source and extending at least partly along a direction parallel to the transmitting face 4. This transmitting reflector has a reflecting face 13 directed towards the transmitting face 4 so that the transmitting reflector 12 associated with this source is located between the transmitting face 4 and an emitting surface 14 (illustrated in dotted lines) of this source, this emitting surface 14 being arranged for the output out of the source of the light emitted by this source 2. Each transmitting reflector 12 is preferably a white reflector comprising a light reflecting white surface, typically a reflecting thin white ink or paint layer. Each transmitting reflector 12 is a reflector reflecting the light emitted by the sources 2. By reflecting, it is preferably meant, in this description, reflecting more than 90% of the light visible to human eye (i.e. 400 nm to 700 nm wavelength). Each transmitting reflector is opaque. By opaque, it is preferably meant in this description which does not let the light visible to human eye through it, more concretely, which prevents at least 90% of the light visible to human eye from passing through it.
Each transmitting reflector 12 is arranged to form a screen between, on the one hand, the source 2 with which it is associated and, on the other hand, the transmitting face 4. Such a screen avoids creating a too luminous light strip at each strip 7 of sources with respect to the rest of the guide 3. However, such a simply opaque screen is likely to transform a too luminous light strip at each strip 7 with respect to the rest of the guide 3 into too dark a light strip with respect to the rest of the guide 3. The fact that the “screen” formed by each transmitting reflector 12 is further arranged to reflect light towards the transmitting face enables this risk of under-exposure to be overcome.
Each transmitting reflector 12 is integrated in the module 1 and inside the light guide 3 so that there is no intermediate space, in particular no vacuum, air or gas space, between the light guide 3 and each transmitting reflector. The fact that there is no air enables much more light to go out than in the presence of air thanks to direct reflection on the transmitting reflector 12.
The module 1 further comprises for each light source a return reflector (or mirror) 15 associated with this source having a reflecting face 16 directed towards the return face 5 so that the emitting surface 14 of this source is located between the return reflector 15 associated with this source and the return face 5. Each return reflector 15 extends at least partly along a direction parallel to the return face. Each return reflector 15 is preferably a metal reflector, typically comprising a thin metal deposit reflecting layer, but can in some alternatives, be a white reflector comprising a light reflecting white surface, typically a thin reflecting white ink or paint layer. Each return reflector 15 is preferably a reflector reflecting more than 90% of the light visible to human eye (i.e. 400 nm to 700 nm wavelength). Each return reflector 15 is opaque, that is it does not let the light visible to human eye through it. More concretely, it prevents at least 90% of the light visible to human eye from passing through it.
Each return reflector 15 enables “the release” of the light emitted by the source 2 associated to it to be improved, so that this light is not trapped under the opaque screen formed by the transmitting reflector 12 or the return reflector 15 associated with this source 2.
Each return reflector 15 is arranged to form a screen between, on the one hand, the source 2 with which it is associated and, on the other hand, the transmitting face 4. Each return reflector 15 is integrated in the module 1 and inside the light guide 3 so that there is no intermediate space, in particular no vacuum, air or gas space, between the light guide and the transmitting reflector.
For each light source 2, these associated transmitting reflector 12 and return reflector 15 are located on 2 opposite faces of an object 21 provided at the bottom of the cavity 3b wherein this source 2 is inserted. This object 21 is preferably transparent to the light of the sources 2. More exactly, the transmitting reflector 12 and the return reflector 15 which are associated with a same source 2 are located on 2 opposite faces of a same film such as illustrated in
As illustrated in
For each strip 7 of sources 2, the return reflectors 15 of the different sources form a continuous reflecting strip per row 17, 18 of sources of the strip of sources, this reflecting strip running along its row 17, 18 respectively (that is extending along the direction of alignment of its row), the reflecting strips of a same strip of sources being spaced by a non-reflecting intermediate space 19 letting the light through. Thus, the homogeneity of brightness is improved, by avoiding that the middle of each strip 7 of sources be too dark.
For each strip 7, between both rows 17, 18 of sources of this strip 7, the module 1 comprises means 23 reflecting the light from this strip 7 to the intermediate space 19 between reflecting strips of these rows 17, 18. These means typically comprise either:
Each reflecting strip is provided, along its edge farthest from the light sources of this strip of sources, with a non-reflecting dark strip 20 arranged to absorb the light emitted by the sources. Each dark strip 20 enables to soften the brightness jump between the end of the reflecting strip and the rest of the guide 3 caused by the interface between the outer edge of the cavity 3b and the rest of the guide 3.
Furthermore, for each strip 7 of sources, the transmitting reflectors 12 of different sources form a continuous reflecting strip per row 17, 18 of sources of the strip of sources, this reflecting strip running along its row 17 or 18 respectively, the reflecting strips of a same strip of sources being spaced by a non-reflecting intermediate space 19 letting the light through. Thus, the homogeneity of brightness is improved, by avoiding that the middle of each strip 7 of sources be too dark.
The light guide 3 is provided, for each row of light sources, with a non-reflecting dark strip 24 arranged to absorb the light emitted by the sources and provided on the return face side under the transmitting reflector 12 associated with this row of sources, more exactly at least under the length of the edge of this transmitting reflector 12 farthest from the light sources of this row of sources. Each dark strip 24 enables to soften a brightness jump between the end of a reflecting strip and the rest of the guide 3 caused by the interface between the outer edge of the cavity 3b and the rest of the guide 3a.
It is noted that in the module 1, in reference to
It will now be described, in reference to
In the module 11, for each light source, the associated transmitting reflector and return reflector are located not on two opposite faces of a same film, but on two opposite faces of a same profile 21. For each strip 7, there is a profile 21 common to all the rows of sources of the strip 7, this profile extending along the direction of alignment of at least one of the rows of sources of this strip 7.
This profile 21 is of a reflecting material, preferably a material reflecting more than 90% of the light visible to human eye. This material is typically white, and comprises for example a plastic material such as acrylonitrile butadiene styrene copolymer.
The face 16 of the profile is a metallized face, that is provided with a reflecting metal layer.
Furthermore, in the module 11, each transmitting reflector 12 has a convex shape towards the transmitting face 4, due to a convex shape of this profile towards the transmitting face.
Furthermore, in the module 11, for each strip 7 of sources, the transmitting reflectors 12 of different sources form a continuous reflecting strip running along the rows of sources of the strip of sources and common to all these rows.
In one alternative, on the contrary, the profile 21 is of transparent material, letting the light through, typically letting at least 50% or even at least 90% of the light through. Such a profile enables the light to be made uniform because the light is distributed inside the profile between the reflectors 12 and 15.
It will now be described, in reference to
In the module 101, for each strip of sources, the power supply circuit 10 carrying the sources of this strip of sources is included between the transmitting face 4 and the emitting sources 2 of this strip 7 of sources.
Furthermore, in the module 101, for each strip 7 of sources, the transmitting reflectors 12 of different sources form a continuous reflecting strip running along the rows of sources of the strip of sources and common to all these rows.
Moreover, in the module 101, for each strip 7 of sources, the return reflectors 15 of different sources form a continuous reflecting strip running along the rows of sources of the strip of sources and common to all these rows.
Furthermore, in the module 101, for each light source 2, the object 21 on the faces of which are located the transmitting reflector 12 and the return reflector 15 is the circuit 10 carrying this source 2. Each circuit 10 is thus provided with two reflecting surfaces:
Finally, for each source 2, the reflecting face 16 of the return reflector 15 associated with this source is at first not tilted, so that the distance between the return face 5 and this reflecting face 16 is constant when the direction of emission 9 or 29 of the light of this source is followed and as the distance from the strip carrying this source increases, and then is tilted after some distance so that the distance between the return face 5 and this reflecting face 16 is increasing when the direction of emission 9 or 29 of the light of this source is followed and as the distance from the strip carrying this source increases.
It will now be described, in reference to
In the module 102, for each strip of sources, the power supply circuit carrying the sources of this strip of sources is included between the transmitting face and the emitting sources of this strip of sources.
Moreover, in the module 102, for each strip 7 of sources, the transmitting reflectors of different sources form a continuous reflecting strip running along the rows of sources of the strip of sources and common to all these rows.
Furthermore, in the module 102, for each strip 7 of sources, the return reflectors of different sources form a continuous reflecting strip running along the rows of sources of the strip of sources and common to all these rows.
Finally, for each source 2, the reflecting face 16 of the return reflector 15 associated with this source is not tilted, so that the distance between the return face and this reflecting face 16 is constant when the direction of emission 9 or 29 of the light of this source is followed and as the distance from the strip carrying this source increases.
It will now be described, in reference to
In the module 103, each strip 7 only includes a single row of light sources 2.
In the module 103, the direction of emission 29 of at least some sources 2 is neither parallel to the transmitting face 4, nor parallel to the return face 5.
Finally, for each source 2, the reflecting face 16 of the return reflector 15 associated with this source is tilted so that the distance between the return face 5 and this reflecting face is increasing when the direction of emission 29 of the light of this source is followed and as the distance from the strip carrying this source increases.
It will now be described, in reference to
In the module 104, the direction of emission 9 or 29 of at least some sources 2 is neither parallel to the transmitting face 4, nor parallel to the return face 5.
Finally, for each source 2, the reflecting face 16 of the return reflector 15 associated with this source is tilted so that the distance between the return face 5 and this reflecting face 16 is increasing when the direction of emission 9 or 29 of the light of this source is followed and as the distance from the strip carrying this source increases.
In an alternative such as illustrated in
In another alternative, a case where each circuit 10 is laid onto a profile the boundaries of which are illustrated by the dotted lines 22 can be considered. In this case, each circuit 10 is thereby provided with a reflecting face: a face of the circuit 10, directed towards the return face 5, is provided with the reflecting face 16 of the return reflector 15 (preferably a white reflector). The profile, in turn, has a face directed towards the transmitting face 4, which is provided with the reflecting face 13b of the transmitting reflector 12b (preferably a white reflector).
It will now be described, in reference to
In this alternative, for each strip of sources, the return reflectors 15 of the different sources form reflecting areas being discontinuous between each other. In other words, each return reflector 15 associated with a source is distinct from the return reflectors associated with the other sources, and is separated from the return reflectors associated with other sources by an intermediate space letting the light through. Each return reflector 15 associated with a source 2 has a reflection coefficient which is maximum at a centre (which is typically the point of the reflector 15 that is closest to this source 2), and which decreases as the distance from this centre increases.
Furthermore, in this alternative, for each strip of sources, the transmitting reflectors 12 of the different sources form reflecting areas which are discontinuous between each other. In other words, each transmitting reflector 12 associated with a source is distinct from the transmitting reflectors 12 associated with the other sources, and is separated from the transmitting reflectors 12 associated with the other sources by an intermediate space letting the light through. Each transmitting reflector 12 associated with a source 2 has a reflection coefficient which is maximum at a centre (which is typically the point of the reflector 12 that is closest to this source 2), and which decreases as the distance from this centre increases.
In
This is applicable in particular in the case of
The ordinate axis represents a luminance in lumen/m2.
The width L of the rib or cavity 3b is 13 mm.
On the abscissa axis, the scale is expanded between 40 and 60 mm.
It will now be described, in reference to
In reference to
The guide 3 comprises at least one cavity 3b, each cavity being for receiving a strip 7 of sources to be inserted into the guide.
Each cavity 3b has a longitudinal trench shape. This trench comprises a groove 34 parallel to the trench (that is extending parallel to the longitudinal direction of the trench) and separating in two this trench and forming a support surface for the light emitting sources (more precisely for the support 10 of the sources 2). Each groove 34 is substantially centred inside its trench. Of course, the groove 34 is only optional, and embodiments free from the groove 34 can be contemplated.
Then, the reflectors 6, 23, 12, 15 are made. For this, several options can be considered:
Then, optionally, the black strips 20 can be inserted, for example by spraying black ink or paint or as a black glued or pressure sensitive adhesive strip.
Then, in reference to
For each inserted strip, the space 36 of the cavity 3b separating the strip inserted into this cavity 3b and the rest of the guide 3a is filled with a material which is initially fluid and then solidifies, for example an epoxy resin, or even polymethylmethacrylate (PMMA), or even an ACRYLATE or METHACRYLATE based material such as EPOXY ACRYLATE, EPOXY METHACRYLATE, URETHANE ACRYLATE, URETHANE METHACRYLATE, ACRYLATE, preferably the same material as the rest of the guide 3a. Thus, the intermediate air spaces are avoided, and thereby it is not necessary to treat the inner surfaces of trenches with an antireflection treatment to decrease the light energy losses by reflection. For each cavity to be filled, this space 36 is typically filled by a nozzle or needle (not illustrated) which injects fluid material:
Then, in reference to
It is noted that this method of making according to the invention by combination of the main part 3a and the part 35 is applicable to the module according to the invention illustrated in
As illustrated in
A source 2 is called “front view” when it is arranged to emit light in a direction of emission 9 or 29 substantially perpendicular to the portion of the circuit 10 which carries said emitting source.
Throughout this document, the use of the word “each” means each element considered, without excluding the existence of other different elements. For example, when it is said that the module according to the invention further comprises for each light source 2 a transmitting reflector, this means for each source 2 considered; it would indeed be possible to add to the module additional sources non-associated with reflectors and having their own roles, while keeping within the scope of the invention.
It will now be described, in reference to
In this making method according to the invention, at least one assembly 90 (preferably several parallel assemblies so as to comprise several parallel strips 7) is placed in a space 93 bounded between planar surfaces 97, 98 of both plates 91, 92. The plates 91, 92 are preferably glass plates.
The surfaces 97 and 98 are facing each other.
The surfaces 97 and 98 are parallel.
The surface 97 of a first 91 of these plates bounds the return face 5.
The surface 98 of a second of these plates bounds the transmitting face 4.
Both plates 91, 92 are connected by a seal (not illustrated) closing the space 93.
Each assembly 90 comprises a strip 7 of sources 2 (integral with each other) such as described above with its two parallel rows of sources arranged to emit along the opposite directions 9, 29. The sources of an assembly 90 are preferably carried by a circuit 10. Further, each assembly 90 comprises for each of its sources a transmitting 12 and/or return 15 reflector such as described above (according to the different possible alternatives: discontinuous areas, reflecting strip common to several rows of sources, one reflecting strip per row, . . . ). For each assembly 90, its rows of sources are integral with its reflectors 12, 15.
Once it is placed between both plates 91, 92, the transmitting reflector 12 associated with one source has a reflecting face 13 directed towards the transmitting face 4 so that the transmitting reflector associated with this source is located between the transmitting face 4 and an emitting surface 14 of this source arranged for the output out of the source of the light emitted by the source.
Once it is placed between both plates 91, 92, the return reflector 15 associated with one source has a reflecting face 16 directed towards the return face 5 so that the emitting surface 14 of this source is located between the return reflector 15 associated with this source and the return face 5.
The surface 97 of the plate 91 bounding the space 93 is in contact with each assembly 90.
The surface 98 of the plate 92 bounding the space 93 is not in contact with any assembly 90.
Once the assemblies 90 are placed between the plates 91, 92, the space 93 is filled with an initially liquid or pasty material to form the light guide 3.
Then, this material is solidified, typically by polymerization preferably by heating. The guide 3 becomes integral with each assembly 90.
This material of the guide 3 preferably comprises PMMA (polymethylmethacrylate), PolyCarbonate (PC) and/or polyester. The preferred solution comprises PPMA, which typically polymerizes from 50 to 65° C. overnight and then at 120° C. for one hour.
Then, the plates 91 and 92 which therefore have been used as a mould are removed (at room temperature typically at 20° C.). Thus, the guide 3 is demoulded by removing it from between both surfaces 97, 98.
Thus, the module according to the invention can be ingeniously made by a single moulding, without necessarily needing to make cavities to place the sources 2, which enables the manufacturing cost to be reduced. This moulding further enables the optical continuity of the guide 3 to be improved, because it avoids re-sealing a cavity with possible resealing imperfections. This moulding can be made in one go by directly integrating the reflectors 12, 15.
According to one embodiment of
According to one embodiment of
According to one embodiment of
According to one embodiment of
According to one embodiment of
According to one embodiment of
In an interesting alternative of the invention, each strip 7 of sources can be equipped at one of its ends with an electric connector (or “electric contact”). After solidification of the material forming the guide 3, each of these connectors is accessible by being released by a cutting along this connector. The cutting is preferably a laser cutting. Optionally, a pocket of air or of another material different from that of the guide 3 and extractible from the guide 3 can be provided at each connector to make it appear.
In one alternative, the faces 4 and 5 are not necessarily parallel. One of the faces 4, 5 can be not parallel to the other face, or have a saw tooth shape.
Of course, the invention is not restricted to the examples just described and numerous alterations can be provided to these examples without departing from the scope of the invention.
Of course, the different characteristics, forms, alternatives and embodiments of the invention can be associated with each other.
Number | Date | Country | Kind |
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11 52632 | Mar 2011 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR12/50639 | 3/27/2012 | WO | 00 | 9/30/2013 |