DE102004026585B4 - Light distributor with a light-distributing structure consisting of micro and macrostructures - Google Patents

Abstract

diffuser from one for the light to be distributed transparent plastic, with a Lichteintritts- and a light exit side, each having an extension in x- and y-direction and in which the light entrance side and / or the light exit side has a light-distributing structure, those from macrostructures and these superimposed microstructures consists, characterized in that the macrostructures by an array of wells in the x and y directions and the microstructures are formed by pores, which are increasingly closer to the well bottoms lie.

Description

Under a light distributor is understood to mean an optical component which a light source upstream of transmission or reflection the radiation characteristic of the impinging radiation beam (hereinafter Lighting beam called) changed, by the radiation intensity within the illumination beam and its shape is changed. Light distributors, which act by transmission, consist of a for the Illuminating beam transparent material and have a Lichteintritts- and a light exit surface depending on the destination of the light distributor a two- or three-dimensional surface shape has, which is superimposed by light-distributing structures. These light-distributing structures are macrostructures (in the mm and 1/10 mm range) and / or microstructures (in the μm range). Light distributor can including planed plates, wedges and lighting shells. For the purpose of The invention also optical fibers with a lichtverteilenden Structure over a light exit surface on Fiber end or fiber circumference are understood as a light distributor.

Known Light distributors differ essentially by the geometry and size of the light-distributing Structures as well as their production process.

In the DE 197 31 142 a light distributor is disclosed in which the surface is formed of adjacent linear prisms, which constitute a first linear structure. This is superimposed by at least one second linear structure, which is formed by an arrangement of prismatic recesses in the linear prisms.

The surface structure is a pure macrostructure.

The first linear structure widens the illumination beam of a point light source essentially linearly orthogonal to the course of the linear prism edges and homogenizes the intensity of the illumination beam accordingly in that direction while they the radiation characteristic of the illumination beam in the direction the linear prism edges are almost unaffected.

The Influencing the radiation characteristic in the direction of the linear prism edges is crossed by the second linear structure, the prismatic Recesses, causes.

By the distance and the size of this cruising Recesses can be the degree of linear light distribution in one area Light distribution can be adjusted.

The Linear prisms are made by embossing, the recesses generated by a mechanical ablation process. As material for The light distributor is indicated as plastic, glass and quartz. The light distributor may be formed as a plate or as a foil.

In WO 02/057816 a light distributor is disclosed, the surface of which is formed by adjacent linear elements (called breaking structure) to equal to the linear prisms in the DE 197 31 142 to cause the light distribution in one direction. The cross section of the linear elements may be triangular, semicircular or wavy. These linear elements, here referred to as "refractive structure" are superimposed by a "scattering structure", which is formed in particular by elliptical elevations, whose large diameter is aligned according to the desired light distribution in the direction or orthogonal to the linear elements and in their dimensions clearly should be smaller than the linear elements. The surface structure is thus formed from a macrostructure and a microstructure. No statement is made with which method such light distributors can be produced.

It is stated that the light distributor is made of a transparent material like glass or e.g. a synthetic plastic film or may consist of a reflective material such as metal.

In the US 6,130,777 Another special light distributor, namely a lenticular glass pane and a method for its production are described. The prior art is stated in this document that conventional diffuser (better called light distributor), for example, with a surface shape of half side by side arranged cylindrical lens elements (linear elements) in the order of 0.1 to 0.2 mm, so a macrostructure, by um- or forming processes, and that these methods are not suitable for accurately producing elements of more complex shape or smaller size. These conventional light distributors, in which the lenticular surface acts as a light entry surface, distribute the radiation substantially only in one direction, as already explained with reference to the described prior art. In order to increase the distribution area, two such light distributors are to be joined together offset from one another in such a way that the lens elements lie perpendicular to one another in two planes.

With the subject of US 6,130,777 is now proposed for better homogenization the light distribution, the described conventional surface shape (macrostructure) with tiny structures (microstructure), on the order of 1-200 microns overlay and a process for the production of lenticular glass panes (light distributor) is given with these structures.

In a first embodiment of the manufacturing process is a transparent plastic film with a multitude of tiny scattering elements (microstructure) on one surface made by passing a plastic film over a first roll and is irradiated, their surface complementary to the desired Microstructure is formed and the previously with a by radiation curable Resin has been coated. The resin hardens irradiation and forms on the adjacent surface of the transparent plastic film the microstructure. This plastic film is in a second step on a thermoplastic Laminated synthetic resin board by placing the plastic film and the resin plate between led a pair of roles be pressed together, wherein at least one of the rollers one for Macrostructure complementary surface shape has, so that the fitting surface of the resin plate accordingly the macrostructure is shaped.

Further described embodiments the manufacturing process are just as expensive. For curing proposed, depending on the resin used, UV radiation or To use electron radiation.

The compelling use of radiation-curable resins a material restriction above In addition, the process is time consuming and sets a special technical equipment ahead as well as for different structures custom-made tools (different Roll).

Either the microstructure as well as the macrostructure are described in all versions of the manufacturing process produced by forming or prototyping. Accordingly, the structures are each determined by the design the model form in its size, shape and arrangement determined to each other.

A first execution the microstructure shows cylindrical lens elements of the same shape and Alignment of the cylindrical lens axes as the cylindrical lens elements the macrostructure and causes a more homogeneous scattering of the radiation perpendicular to the cylindrical lens axes.

In a second embodiment the microstructures are also cylindrical lens elements whose cylindrical lens axes aligned perpendicular to those of the macrostructure, thereby an additional scatter in the direction of the cylindrical lens axes of the macrostructure is effected and the scattering spatially extended becomes.

The US 6,352,359 shows a lamp in which are irradiated by a light source components in the context of the invention as a light distributor. These may be the cover shell, an inner lens and / or a reflector. If the light distributor is a transparent component, the light entry surface and the light exit surface can be structured. The light-distributing structures are said to be microstructures that homogenize the light distribution, direct the light to where it is needed, and shape the radiation to illuminate a desired area.

To Size, shape and alignment of the microstructures are made to be selected dependent of the functional properties that the luminaire should have.

In one embodiment, the microstructures are integrated into a so-called cushion structure on the inner surface of a curved cover shell. The cushion structure, which presumably is a matrix-like arrangement of relatively large ball sections to the microstructures on a concave base surface, scatters according to the author US 6,352,359 The radiation is very inefficient and serves more the aesthetic appearance of the lamp. It is based on a variety of older patents of the owner US 6,352,359 referring to forms of microstructures and methods of making the same.

These Procedures have in common that the light distributors each as a copy or negative of a master mold. This is the Structures, which for the light distribution are determinative, each specified concretely. For different desired light distributions Different master forms are needed.

In all described solutions are the light-distributing structures, as far as the manufacturing process are known or derivable, fixed by the tool. Optionally, a light distribution determined by macrostructures is transmitted defined, evenly over the surface of the Macrostructures homogenized distributed microstructures.

It is the object of the invention to provide a light distributor with macrostructures and microstructures, the microstructures being dependent on the light-distributing effect of the macrostructure be distributed over the surface of the macrostructures.

These Task is for a light distributor according to claim 1 solved.

advantageous versions are in the subclaims executed.

By the generation of the light-distributing structure by means of laser can with one and the same tool not just different macro structures in size and shape be created, but at the same time arise in the new generated surface by the thermal effect of the laser radiation on the material Microstructures that are essentially pores.

About the Choice of material and laser and its process parameters, such as laser power, pulse rate, pulse duration, feed rate and scan (motion) may be the shape, size and arrangement the macrostructures are determined and varied. In addition, the Density distribution of the microstructures are affected.

When Material come for the light distributor all laser-processable plastics in question, the for the provided illumination radiation are transparent. Especially amorphous plastics, e.g. PMMA (polymethyl methacrylate) or PS (polystyrene) or plastics based on polybutadienes are special suitable.

to Processing of these materials are particularly suitable lasers, which emit in the near infrared or in the infrared range.

The Invention will be described below with reference to exemplary embodiments Drawings closer explained become. Show:

1a a stylized graphic representation of a section of a light distributor with grooved structure

1b a section of an enlarged scanning electron micrograph of a light distributor according to 1a

1c a section of a greatly enlarged scanning electron micrograph of a light distributor according to 1a

2a a stylized graphic representation of a section of a light distributor with a structure of shallow hollows

2 B a section of an enlarged scanning electron micrograph of a light distributor according to 2a

2c a section of a greatly enlarged scanning electron micrograph of a light distributor according to 2a

3a a stylized graphic representation of a section of a light distributor with a structure of deep hollows

3b a section of an enlarged scanning electron micrograph of a light distributor according to 3a

3c a section of a greatly enlarged scanning electron micrograph of a light distributor according to 3a

In a first embodiment of the method according to the invention, a light distributor made of PMMA is to be produced with a CO ₂ laser, the basic shape of which is a plane plate and whose macrostructure is formed by grooves.

to execution the process, the laser is perpendicular to the surface of the directed to be machined plane plate and the focus distance over the surface guided. The guided Movement is a scanning movement of the laser beam in the x-direction with changing sense of direction, with each change of direction the laser beam is displaced in y-direction by a predetermined amount (Scan line offset).

at a feed rate of 800 mm / s, a scan line offset of 0.075 mm, a laser power of 8 W, a pulse rate of 2 kHz and a pulse duration of 45 ns are in the x direction with a Distance from one another juxtaposed recesses in the form of Dumped caves, between which a narrow rounded bridge preserved. In the y-direction, there is an overlap of each trough-shaped material removal and thus forming grooves that run in the y-direction.

A Generation of the overlap the material removal in the y direction instead of the x direction differs thereby that in the y-direction of each groove forming material removal not immediately after one another and therefore the groove structures become more even.

The grooves formed with these process parameters are about 0.1-0.2 mm deep and have a distance (from groove center to groove center) of about 0.4 mm. The macrostructures are essentially made by material evaporation, materi aldepolymerisation and material degradation produced, however, the microstructures arise in particular, however, by an explosive dissolution of material particles, whereby pores are formed. In the 1a . 1b and 1c a light-distributing structure of a light distributor according to the first embodiment is shown in plan view.

The remaining surface looks under an electron microscope, see 1b and 1c discarded, unsystematically structured and porous. In particular, the pores represent an optically participating microstructure.

In 1a is a stylized section through the surface structure in the x-direction shown. In its macrostructure, the surface is formed by side-by-side grooves having a wave-shaped cross section. In an enlarged section, the microstructures are shown stylized. The magnitude of the microstructures goes back to molecular dimensions, in particular 1c shows, the microstructure distribution across the macrostructure is different. In the region of the groove bottom, in which the macrostructure contributes less to the light distribution, since the light emerges almost unbroken, the structure is highly porous, while it is rather smooth-waved in the groove transitions.

One Light distributor, as in carrying out the method according to the first embodiment arises, affects the transmissive illumination beam e.g. a point light source by moving it substantially in the x direction expands and the intensity evenly distributed (no Gaussian distribution). The illumination beam is transformed into a linear radiation and can thus form a light curtain or illuminate a linear surface.

About the Variation of laser power and pulse duration can increase the depth of the grooves be varied. By defocusing the laser can the groove width be enlarged. This allows the illuminable surface shortened or extended and the intensity distribution over the Length to be changed.

In a second embodiment should in contrast to the first embodiment, the method so changed be that as macrostructures a grid-shaped arrangement of flat Troughs are created.

2a shows a stylized graphic representation of the macrostructures. The microstructures are from the photographic images 2 B and 2c , each showing an enlarged photograph by scanning electron microscope, recognizable. To create shallow wells, the scan line offset is increased and the laser power and pulse duration are reduced. The larger the unprocessed surface areas between the troughs, the greater the intensity of the illumination beam in the center remains, ie a resulting circularly illuminated surface shows a much brighter center with respect to the edge areas. With increasing approach of the wells to each other up to a beginning overlap, which is achieved by a higher pulse rate or lower feed rate for the x-direction and for the y-direction by a smaller scan line spacing, the intensity distribution is homogenized, ie the illuminated area acts increasingly uniformly bright. Especially if you have the 2c with the 1c compares, differences in the density of the microstructures according to the first and the second embodiment can be seen. The pore density in the light-distributing structure with shallow wells is not that high, which can be explained by the lower laser power and longer pulse duration. The choice of parameters also influences the microstructure. For both embodiments, it turns out that the microstructures arise more intensively in the trough bottom or groove bottom. Light that exits the light distributor almost unbroken for a given macrostructure is diffusely scattered by the microstructure, ie the microstructure acts in particular in the surface regions in which the macrostructure hardly causes any light distribution.

Experiments have shown that when the laser power is increased by about four times and otherwise while maintaining the process parameters chosen for the production of shallow wells, macrostructures are produced which can not be produced by any known method and lead to an unexpected shaping of the illumination beam For this 3a . 3b and 3c ,

The resulting deeper troughs are over their depth in cross section not continuously lower, like the shallow hollows, but it comes after initial Cross-section reduction to a cross-sectional widening to the trough bottom so that they represent an undercut cavity.

If the troughs are produced close to each other, the creation of further troughs influences the shape of adjacent troughs. The depressions, which are essentially round in each sectional plane perpendicular to the direction of action of the laser beam, are "pressed in" and thus flattened to the subsequently generated depression .This deformation and the form of the lower depressions forming an undercut affect the shape of the transmitted illumination beam and thus to the shape of the illuminated area the shape of the hollows, the shape of the illumination beam can be purposefully changed. For example, a trapezoidal illuminated surface can be created with concave side lines. An illumination radiation shaped with such structures could be particularly suitable for illuminating areas in the passenger compartment of a car.

Next Macrostructures formed by grooves and hollows of the same shape and shape Size, can with that inventive method also macrostructures are generated in which e.g. the depth of Depressions from the center of the light distributor towards its edges or increasingly, or is the bridge width between the grooves or hollows over the length of the light distributor is reduced or increased. The latter can be an advantage to be e.g. a more even jet application to cause from a light guide, created on the circumference of a beam exit surface shall be.

advantageously, For this purpose, the laser can work according to another scanning regime. Instead of the surface to be machined in x-direction in mutual Sense direction, the processing can spiral from Outside to the inside or vice versa. Or the scan regime is chosen so that the laser becomes smaller or larger Circles or rectangles describing e.g. annular grooves can be generated.

It can also to the axis of the laser beam unbalanced macrostructures be generated by the laser beam is not perpendicular to the working surface is directed, as in the direction of the surface normal, but under an angle to the surface normal.

The mentioned parameter combinations and sampling regimes are only examples called.

By the choice of process parameters and the scanning regime can be a illuminated area in same distance to the light distributor both in size and shape as well as in the intensity distribution targeted be formed by a targeted influence on the resulting Macrostructure and microstructure is achieved.

the A person skilled in the art will understand that that the invention is not illustrative of the details of the above mentioned embodiments limited is, but that the present invention in other special Forms forms may be without departing from the scope of the invention, which the appended claims is fixed.

Claims (5)

Light distributor of a transparent plastic for the light to be distributed, with a light entrance and a light exit side, each having an extension in the x and y direction and in which the light entrance side and / or the light exit side has a light-distributing structure consisting of macrostructures and this superimposed microstructures, characterized in that the macrostructures are formed by an array of wells in the x and y direction and the microstructures are formed by pores, which are increasingly dense to each other to the well bottoms. Light distributor according to Claim 1, characterized the troughs are so close to each other in the y-direction that they form grooves. Light distributor according to Claim 1, characterized that the hollows over their depth have a cross-sectional widening towards the trough bottom, so that they represent an undercut cavity. Light distributor according to claim, characterized that the troughs from the center of the light distributor to the edge regions have a decreasing or increasing depth. Light distributor according to Claim 1, characterized that the webs between the hollows of the center of the light distributor have a decreasing or increasing width to the edge regions.