DE202008015402U1 - Optical light scattering unit - Google Patents

Abstract

optical Light scattering unit, with a transparent diffuser (1), and with at least one light source (2) whose emitted Light (4) coupled into the scattering body (1) and at his Passage of inhomogeneities in the interior (3) is scattered, characterized in that the inhomogeneities (3) as by electromagnetic radiation in the scattering body (1) formed sub-surface markers formed are.

Description

The The invention relates to an optical light scattering unit, with a transparent Scattering body, and with at least one light source whose emitted light is coupled into the scattering body and at its passage to inhomogeneities existing in the interior is scattered.

in the Scope of the invention is predominantly a scattering in Forward direction, in which the light source emitted light rays at the individual in the scattering body existing scattering centers are deflected at an angle of not more than 90 ° become. Of course it can also lead to a scatter come in reverse direction. Mostly, however the intensity of the scattered light in the forward direction greater than that in intensity of the scattered Light in reverse direction.

Optical light scattering units of the construction described above are widely known in practice and are used, for example, in the context of DE 101 53 380 A1 described. This is about a lamp with a translucent writing, which is equipped with a microstructure.

A similar structure describes the DE 10 2004 049 260 A1 to illuminate containers or general containers and take their picture using one or more cameras. By the DE 10 2006 061 164 A1 a light-emitting device has become known, in which a radiation source cooperates with a curved light guide body. The radiation emitted by the radiation source is coupled into the light guide body and coupled out at an angle to its longitudinal axis.

In the end, that is what the DE 101 23 263 B4 with a light guide system for the interior of a motor vehicle. It is all about a large-scale, homogeneous and glare-free brightening of a vehicle roof in the overhead area of vehicle occupants. For this purpose, an optical fiber for guiding light is provided in addition to the actual light source. The light guide is formed flat, wherein the coupling of the light takes place at one or more side surfaces. The extraction of the light is achieved by roughening, embossing or drilling with a certain structure.

Of the The state of the art can not convince in all respects. Because the arrangement and introduction of the scattering centers in the interior of the Stray body often requires an increased mechanical effort and can only be with great Effortless and with particular arrangement and alignment realize. This is where the invention starts.

Of the Invention is the technical problem underlying such optical light scattering unit to develop so that the scattering centers in the transparent diffuser simple and defined can be introduced.

to Solution of this technical problem is a generic optical light scattering unit characterized in that the inhomogeneities or scattering centers in the transparent scattering body than by electromagnetic radiation introduced sub-surface markers are formed.

In the context of the invention, therefore, the inhomogeneities in the scattering body are not defined by mechanical or chemical treatment of the scattering body in the interior thereof, but rather by introducing markings, so-called sub-surface markings or generally structures or sub-surface structures, with the aid of electromagnetic radiation under the surface. In this case, the invention is based on the finding that energy densities of several J / cm ² can be achieved with the aid of the electromagnetic radiation coupled into the scatterer so that molecular bonds are permanently destroyed at the location of the focal point and a plasma is generally generated.

As a result thereof, microscopic internal structures in the form of, for example, crack stars, which can be changed in terms of shape, size and position in the depth of the volume essentially by the parameters power of the electromagnetic radiation and focal length of an associated optics for focusing. This is basically known in connection with the writing and reading of information in transparent material body, like the DD 237 972 A3 , the US 3,715,734 or even the DE 691 25 378 T2 occupy. In addition to that DE 199 25 801 B4 Reference is made, which describes a method for controllable change of the spot size in the laser interior engraving and also the US 5 637 244 which depicts various three-dimensional structures attachable within a transparent body of material.

The previous documents on laser engraving are either concerned with capturing information in the transparent material body or generally defining three-dimensional structures. However, these known approaches are not used specifically to introduce inhomogeneities or scattering centers in a scattering body in connection with an optical light scattering unit. In this connection In the past, it has proven useful if the inhomogeneities or scattering centers are designed as laser markings, that is to say they are introduced into the transparent scattering body with the aid of a laser. As a rule, electromagnetic radiation is used in the near infrared, in the visible or even in the UV range. For example, a Nd: YAG laser with a wavelength of 1.064 μm or even of 532 nm may be used.

Such lasers emit laser pulses with a pulse duration of not more than 10 ^-6 sec duration, in particular even pulse durations of 10 ^-8 sec or less are generated. As a result, it is possible to achieve power densities of more than 10 ⁷ W / cm ² and to realize the previously mentioned energy densities of several J / cm ² .

in the Unlike the electromagnetic radiation source, which the Inhomogeneities or scattering centers or structures in general defined in the interior of the scatterer and in the infrared, emitted in the visible or in the UV range, the light source works continuous in the visible spectral range, d. H. sends the light spectrum to be perceived by the human eye. Of the Wavelength range of the light source is therefore about from 380 nm to 750 nm. Of course, both with a continuous light spectrum as well as with a discontinuous one and of course also working with a pulsed light spectrum which is emitted by the light source. The inhomogeneities or scattering centers usually have one Size in the micrometer range.

As already explained, the inhomogeneities are advantageous designed as laser markings or laser structuring. These are introduced into the transparent scattering body by With the help of the laser, the damage threshold in the scatterer is selectively exceeded becomes. As a result, the transparent scattering body remains course still permeable to the light spectrum emitted by the light source only becomes the light rays emitted by the light source in whole or in part the inhomogeneities or scattering centers scattered. It can the interpretation of course be taken so that the inhomogeneities or scattering centers inside the transparent Scatter body the incident light anisotropic in given spatial directions sprinkle. That is, with the help of inhomogeneities can be Specifically determined on the output side of the transparent scattering body Prefer directions for the scattered light. In addition to one On the output side of the scattering body realized homogeneous Brightness distribution is therefore also possible such in which the light is controlled and anisotropic in certain spatial directions is distracted. It can be depending on in the scattering bodies introduced structure also realize geometric patterns.

Conceivable is it, for example, with the help of inhomogeneities or Scattering centers the light irradiated by the light source so to scatter that on the output side of the transparent scattering body a projection screen circles, slats, lines, squares or other shapes and structures with or without design Realize effect. At each pursued technical Effect and the physical context changes this is nothing.

All in all it has proven useful when the transparent scattering body flat and designed as a scattering plate. In any case the diffuser has a closed and smooth surface, in particular no microstructuring as taught by the prior art. By doing so leaves the surface is easy to clean and at the same time insensitive to dirt, especially for outdoor use is of particular importance.

In usually have the light source or emitted by her and the scattered light over a substantially coincident Direction, where between the light source and the scattered light the scatterer is interposed. These are essentially consistent Direction is due to the fact that that of the light source emitted and injected into the scatterer light predominantly in the forward direction at the inhomogeneities elastic is scattered. It is also possible in principle that the light source and the scattered light are at an angle to each other are arranged. For example, a right-angle or near right-angled arrangement of the light source and the scattered light conceivable and is encompassed by the invention. In this case can the light source over an edge in the (plane) Scattering be coupled.

Of particular and independent significance for the invention is furthermore the fact that the inhomogeneities in the interior of the scattering body can have a varying density. In this way, for example, the light propagation can be limited. Thus, it is conceivable that the incident light of the light source is scattered, for example, only between previously introduced clusters of inhomogeneities. Also, this can limit the direction of light propagation. As a result, for example, reflections can be avoided if the optical light scattering unit is used as a display or general display unit. In addition, the varying density of the inhomogeneities in the scattering body permits a possible absorption of the coupled-in light beams counteract.

Indeed the rays of light become with increasing length of their way within the scattering body and the inhomogeneities more and more distracted. Basically, there is also an increasing absorption conceivable. Mostly, however, the scattering body is transparent throughout designed so that the decrease in light intensity up the with increasing path of the light beam through the scatterer increased dispersion due to the inhomogeneities. This sinking light intensity can be increased by a Scattering with increasing distance from the light source bill be worn. This increased scattering leaves by an increasing density of scattering centers and thus inhomogeneities in produce the transparent scattering body.

in the Result, it is therefore advantageous in this context, if the Density of inhomogeneities or scattering centers in the transparent Scattering body increases with increasing distance from the light source. In this way, for example, a sinking light intensity and consequently decreasing brightness inside the scatterer be met, in which this decreasing brightness by increasing Number of scattering centers is compensated in whole or in part. The The result is a scattering body or a scattering plate with Homogeneous light emission, even if the light source over an edge is coupled.

When We recommend materials for the diffuser used the invention glasses, for example, mineral glasses or plastics, such. As acrylic glass, polycarbonate, PVC, PET etc. In addition, solid-state crystals can such as sapphire, quartz, etc. are used. critical is solely the property of the materials used, transparent to the light spectrum emitted by the light source to be and, moreover, to open the possibility by laser engraving o. The like. Permanent markings to be able to define. In the process, the interpretation will be made in such a way that the markings or structures as bubbles or tear stars available. These structures lead macroscopically to one Material turbidity, although the material of the scattering body between of course, transparent to the individual structures stays and no turbidity experiences.

Finally proposes the invention before, that the scattering body designed to be reflective at least on one side or on both sides is. That can be done, for example, by clicking on a surface of the scattering body vapor-deposited on a reflective layer is, such a layer is glued or even a reflective Layer spaced from the respective surface a Arrangement experiences. In this way, the scattered light becomes even further directed and experiences a spatial guidance. Here, the inhomogeneities in the scattering body can be order so that overall a geometric body described becomes. This geometric body may be circles, Spirals, slats, lines, squares, etc. act. With the help of Form and size of these structures can not be can only achieve creative effects, but can also do that over the light source coupled light can be performed.

object Finally, the invention is also a surface radiator. which is characterized by an optical light scattering unit, which has the specifications described above. This surface radiator may be an example Display or a display unit, a lamp, wall elements, room elements like room dividers, projection surfaces in the shape of a glass Canvas, room or ceiling lighting, illuminated heat surfaces etc. act. Most of the time you will realize surface spotlights, which provide a homogeneous light emission or by means of which a targeted light control is generated.

in the The result will be an optical light scattering unit and a surface radiator described, which is particularly cost-effective, fast and efficiently adapted to the specific requirements to let. This is due, in particular, to the fact that the inhomogeneities ultimately responsible for the light control or scattering centers in the interior of the transparent scattering body practically arbitrary in size, shape and arrangement can be specified. Because the questionable Scattering centers or inhomogeneities are becoming more advantageous Embodiment with the aid of a laser beam in the scattering body in question introduced, which selectively exceeds the source of destruction in the scattering body.

By doing either the laser beam is moved three-dimensionally and / or the Scattering body undergoes a three-dimensional movement, can be any spatial structures in the interior of the Set scattering bodies. As a result, this will be in the Diffuser coupled and emitted by the light source light deflected in the desired directions at the scattering centers. Here are the main benefits.

in the The invention will be described below with reference to a purely exemplary embodiment descriptive drawing explained in more detail; show it:

1 and 2 two different embodiments of an optical light scattering unit or a surface radiator, which operates in accordance with the invention.

In the figures, an optical light scattering unit is shown, which in its basic structure via a transparent scattering body 1 and at least one light source 2 features. The optical light scattering unit with the scatterer 1 and the light source 2 may be part of a surface radiator that can be realized in this way. This is in particular on the basis of 2 clear. Because for a viewer B, the optical light scattering unit appears as if the entire transparent scattering body 1 is illuminated flat, for example, emits a uniform homogeneous light intensity.

To achieve this in detail, this is done by the light source 2 emitted light in the scattering body 1 coupled. This can after the variant 2 take place such that the of the light source 2 emitted light in a back surface 1a in the scattering body 1 in and out of the opposite front surface 1b again after the dispersion of inhomogeneities 3 inside the scattering body 1 exit. Additionally or alternatively, however, it is also possible that the light entry is not over the previously discussed broadsides 1a . 1b in the diffuser designed as a diffuser 1 takes place, but rather on its narrow sides 1c , Then, after scattering of the coupled-in light at the inhomogeneities or scattering centers 3 inside the scattering body 1 a light emission over the two broadsides 1a . 1b or the back surface 1a and the front surface 1b ,

In the context of the alternative 2 comes as a light source 2 a conventional thermal radiator or a suitable white light source used. At the light source 2 according to the 1 In contrast, it is one or more point-shaped radiator, such as an LED, which may also emit colored. Either way, that covers from the light source 2 emitted spectrum completely or partially from the light spectrum, ie the visible range.

The inhomogeneities or scattering centers 3 inside the scattering body 1 are introduced in the course of an internal machining, which takes place with the aid of a laser, for example a Nd: YAG laser. In this process, the inhomogeneities or laser markings 3 produced such that with the help of the laser beam, the damage threshold in the scattering body 1 is selectively exceeded. For this purpose, the laser beam undergoes a corresponding focusing, so that it comes to so-called dielectric breakdown and ionization in the interior. As a result, the scattering body becomes 1 locally melted and it forms substantially macroscopically visible bubbles or structures that are often additionally characterized by protruding from their surface cracks, so-called crack stars. These structures have a size in the micrometer range and act altogether as scattering centers 3 ,

The scattering centers or inhomogeneities 3 make sure that from the light source 2 emitted or emitted light 4 this in the context of the presentation 2 mainly scattered in the forward direction. The 1 on the other hand shows an angular scattering with scattering angles in the range around 90 °. This can be the inhomogeneities 3 The incident light also anisotropically scatter in pre given spatial directions, if the inhomogeneities 3 about a certain structure inside the scattering body 1 as described in the introduction.

The scattering body 3 has an overall closed and smooth surface, because the laser engraving described does not damage the surface and can therefore be easily cleaned and does not tend to soiling. As a result, the illustrated optical light scattering unit or a surface radiator realized thereby is predestined for outdoor use. For example, it is not difficult to realize a display unit or a display with the aid of the light scattering unit. Also, lamps, wall elements, etc. can be displayed.

The scattering body 1 can be made from the previously described materials such as glass, plastic or crystalline materials and mixtures. For example, it is conceivable, the scattering body 1 as a scattering plate or diffuser from, for example, acrylic glass, glass, PVC, PET to produce.

As part of the variant 2 assign the light source 2 and the light emitted by her 4 as well as the scattered light 5 a substantially coincident direction, wherein the scattering body or the scattering plate or lens 1 is interposed. On the other hand, the 1 a variant in which the light source 2 or the emitted light 4 and the scattered light 5 angled, z. B. predominantly rectangular, are arranged to each other. In this way it is achieved that on the narrow side 1c in the scatterer or the lens 1 entering light 4 after scattering at the inhomogeneities or scattering centers 3 on the two broadsides 1a respectively. 1b exit and can also escape. An additional and from the diffuser 1 spaced reflective layer 6 May make sure that the scattered light 5 primarily from the front surface 1b exit and a directed leadership to the right in the representation in 1 experiences.

The 1 finally indicates that the inhomogeneities or scattering centers 3 a varying density in the interior of the scattering body 2 may have NEN. In fact, the design is such that the density of the inhomogeneities or scattering centers 3 with increasing distance from the light source 2 increases. In this way, one can see a growing dispersion of the light source 2 emitted or emitted light to the inhomogeneities or scattering centers account. For by this circumstance decreases the brightness of the emitted light rays 4 inside the scattering body 1 with increasing distance from the light source 2 from.

To compensate or mitigate this effect, the distance from the light source increases 2 with a growing number of scattering centers 3 worked. As a result, even in the embodiment according to 1 with a side-mounted light source 2 achieved that the light intensity of the scattered light 5 over the exit surface 1a . 1b is essentially the same. That is, even with the variant 1 Finally, a homogeneous surface radiator is provided.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 10153380 A1 [0003]
• DE 102004049260 A1 [0004]
• DE 102006061164 A1 [0004]
• - DE 10123263 B4 [0005]
• - DD 237972 A3 [0010]
• US 3715734 [0010]
• - DE 69125378 T2 [0010]
• - DE 19925801 B4 [0010]
• US 5637244 [0010]

Claims (14)

Optical light scattering unit, with a transparent diffuser ( 1 ), and with at least one light source ( 2 ), whose emitted light ( 4 ) in the scattering body ( 1 ) and in its passage to inhomogeneities ( 3 ), characterized in that the inhomogeneities ( 3 ) as by electromagnetic radiation in the scattering body ( 1 ) Substrate surface markings are formed. Optical light scattering unit according to claim 1, characterized in that the inhomogeneities ( 3 ) are designed as laser markings, which by means of a damage threshold in the scattering body ( 1 ) are introduced at intervals overlying laser beam. Optical light scattering unit according to claim 1 or 2, characterized in that the inhomogeneities ( 3 ) the incident light ( 4 ) sprinkle anisotropically in given spatial directions. Optical light scattering unit according to one of claims 1 to 3, characterized in that the transparent scattering body ( 1 ) as a scattering plate ( 1 ) is trained. Optical light scattering unit according to one of claims 1 to 4, characterized in that the transparent scattering body ( 1 ) has a closed and smooth surface. Optical light scattering unit according to one of claims 1 to 5, characterized in that the light source ( 2 ) emitted light ( 4 ) and the scattered light ( 5 ) have a substantially coincident direction. Optical light scattering unit according to one of claims 1 to 6, characterized in that the emitted light ( 4 ) and the scattered light ( 5 ) are arranged at an angle, predominantly rectangular, to each other. Optical light scattering unit according to one of claims 1 to 7, characterized in that the emitted light ( 4 ) over an edge ( 1c ) in the scattering body ( 1 ) is coupled. Optical light scattering unit according to one of claims 1 to 8, characterized in that the inhomogeneities ( 3 ) a varying density in the interior of the scattering body ( 1 ) exhibit. Optical light scattering unit according to claim 9, characterized in that the density of the inhomogeneities ( 3 ) with increasing distance from the light source ( 2 ) increases to an increasing scattering of the emitted light ( 4 ) in whole or in part. Optical light scattering unit according to one of claims 1 to 10, characterized in that the scattering body ( 1 ) is made of a glass, plastic or a crystalline transparent material. Optical light scattering unit according to one of claims 1 to 11, characterized in that the scattering body ( 1 ) is formed at least on one side reflective and / or the scattering body ( 1 ) at least one reflective surface ( 6 ) assigned. Optical light scattering unit according to one of claims 1 to 12, characterized in that the inhomogeneities ( 3 ) describe a geometric body to which the scattered light ( 5 ) follows. Area radiator, characterized by an optical Light scattering unit according to one of claims 1 to 13.