DE102024106632B3 - Optical element and lighting device and screen with such an optical element - Google Patents

Abstract

The invention relates to an optical element (10) with a light entry side and a light exit side, comprising first regions (E1) consisting of at least one transparent material with a first refractive index (N1) and second regions (E2) consisting of an opaque material and/or transparent and/or scattering or reflective material with a second refractive index (N2), wherein the first regions (E1) are embedded in the second regions (E2) in a one- or two-dimensional pattern, wherein the first refractive index (N1) is greater than the second refractive index (N2) over the entire wavelength range visible to the human eye, whereby the light exiting the optical element (10) at the light exit side is changed in its propagation directions compared to the light incident on the optical element (10) at the light entry side, and whereby furthermore at least a portion of the light incident on the first regions (E1) at the light entry side of the optical element (10) after passing through the optical element (10) is bundled.
The invention further comprises a method for producing such an optical element (10) as well as a lighting device and screens with such an optical element (10).

Description

Technical field of the invention

In recent years, great strides have been made in widening the viewing angle of LCDs. However, there are often situations where this very wide viewing angle of a screen can be a disadvantage. In particular, a wide viewing angle represents a waste of energy and resources when it's not really needed.

State of the art

In the US 5 993 940 A The use of a film with evenly spaced, small prism strips on its surface is described to achieve a privacy mode. Development and production are quite complex.

The US 2012/0235891 A1 describes a very complex backlight in a screen. 1 and 15 Not only are several light guides used, but also other complex optical elements such as microlens elements 40 and prism structures 50, which transform the light from the rear illumination on its way to the front illumination. This is expensive and complex to implement and also involves light loss. According to the variant according to 17 in the US 2012/0235891 A1 Both light sources 4R and 18 produce light with a narrow illumination angle, with the light from the rear light source 18 first undergoing a complex conversion into light with a wide illumination angle. This complex conversion, as already mentioned above, significantly reduces brightness.

According to the JP 2007-155783 A Special optical surfaces 19 are used, which are complex to calculate and manufacture, and which then deflect light into different narrow or wide areas depending on the angle of incidence. These structures resemble Fresnel lenses. Furthermore, there are interference edges that deflect light in undesirable directions. Thus, it remains unclear whether truly meaningful light distributions can be achieved.

In the US 2013/0308185 A1 describes a special light guide with steps that emits light over a large area in different directions depending on the direction from which it is illuminated from a narrow side. In conjunction with a transmissive image display device, e.g. an LC display, a screen can be created that can be switched between free and restricted view mode. A disadvantage of this is that the restricted view effect can only be created for left/right or up/down, but not for left/right/up/down simultaneously, as is necessary for certain payment transactions. In addition, even in restricted view mode, residual light is still visible from blocked viewing angles.

The DE 10 2022 134 518 B3 The applicant's patent describes an optical element, a method for its manufacture, and an illumination device. Differences in refractive indices are used to generate total internal reflection of light at specific angles. This document does not suggest designing the structures used with different contours on the light input and output sides.

The WO 2022/078942 A1 The applicant's patent describes an optical element and a method for its manufacture. Here, differences in refractive indices are used to generate total internal reflection of light at specific angles. This document also does not suggest designing the structures used with different contours on the light input and output sides.

The DE 10 2020 008 062 A1 The applicant's patent describes an optical element with variable transmission, a corresponding method, and a display screen with such an optical element. Here, differences in refractive index are again used to generate total internal reflection of light at specific angles. This document also does not suggest designing the structures used with different contours on the light input and output sides.

Finally, DE 10 2021 110 010 A1 The applicant's patent application describes an optical element for influencing light directions and arrangements using such elements. However, the use of flexible apertures, which are usually designed as LCD shutters, results in a relatively high loss of light.

The aforementioned methods and arrangements have the disadvantage that they do not allow the optional optimization of the luminance curve of a screen.

Description of the invention

It is therefore an object of the invention to develop a planar optical element that can influence incident light in a defined manner in its propagation directions, wherein at least a portion of the light incident on the light entry side of the optical element is bundled after passing through the optical element. The optical element should be inexpensive. be feasible and, in particular, universally usable with different screen types in order to achieve an increase in efficiency in luminance distribution.

Furthermore, the optical element should generally offer the possibility of achieving a top-hat light distribution. This means that the brightness decreases by no more than 15 percent within an angular range of at least +/-5 degrees around the mean emission angle.

• - mindestens aus einem transparenten Material mit einer ersten Brechzahl N1 bestehende erste Bereiche E1 und aus einem opaken Material und/oder transparenten und/oder reflektierendem oder streuenden Material mit einer zweiten Brechzahl N2 bestehende zweite Bereiche E2, wobei die ersten Bereiche E1 in einem ein- oder zweidimensionalen (bevorzugt, aber nicht notwendigerweise periodischen) Muster in die zweiten Bereiche E2 eingebettet sind, wobei die erste Brechzahl N1 im gesamten für ein menschliches Auge sichtbaren Wellenlängenbereich größer ist als die zweite Brechzahl N2,
• - wobei die ersten Bereiche E1 jeweils an der Lichtaustrittsseite einen größeren Querschnitt als an der Lichteintrittsseite aufweisen, und wobei ferner die ersten Bereiche E1 bei Betrachtung in Parallelprojektion senkrecht auf das optische Element jeweils an der Lichteinfallsseite und an der Lichtausfallsseite unterschiedliche Umrissformen aufweisen, die nicht durch Größenskalierung zur Kongruenz zu bringen sind,
• - so dass an der Lichteintrittsseite des optischen Elements auf dieses auftreffende Licht, welches in erste Bereiche E1 des optischen Elements einfällt, dort je nach geometrischer Einfallsrichtung, Polarisation und dem Verhältnis der ersten Brechzahl N1 zu der zweiten Brechzahl N2
  1. a) innerhalb eines ersten Bereiches E1 ungehindert propagiert oder totalreflektiert wird und hernach an der Lichtaustrittsseite des entsprechenden ersten Bereiches E1 wieder ausgekoppelt wird, oder
  2. b) von dem ersten Bereich E1 in einen angrenzenden zweiten Bereich E2 eindringt und, wenn es im zweiten Bereich E2 nicht absorbiert wird, in einem zweiten Bereich E2 propagiert, bis es auf der Lichtaustrittsseite aus einem zweiten Bereich E2 ausgekoppelt oder in einen oder mehrere nächste erste und/oder zweite Bereiche E1, E2 eingekoppelt wird (und so weiter),
• - und so dass in einer ersten Alternative, in welcher die zweiten Bereiche E2 aus einem transparenten Material bestehen, Licht, das an der Lichteintrittsseite des optischen Elements in zweite Bereiche E2 des optischen Elements einfällt, dieses durchdringt und auf der Lichtaustrittsseite aus dem optischen Element ausgekoppelt wird,
• - und so dass in einer zweiten Alternative, in welcher die zweiten Bereiche E2 mindestens teilweise ein opakes Material umfassen, Licht, das an der Lichteintrittsseite des optischen Elements in zweite Bereiche E2 des optischen Elements einfällt, mindestens teilweise absorbiert wird,
• - und so dass in einer dritten Alternative, in welcher die zweiten Bereiche E2 mindestens teilweise ein reflektierendes und/oder streuendes Material umfassen, Licht, das an der Lichteintrittsseite des optischen Elements in zweite Bereiche E2 des optischen Elements einfällt, mindestens teilweise reflektiert und/oder gestreut wird,
• - wodurch das an der Lichtaustrittsseite des optischen Elements aus diesem austretende Licht gegenüber dem an der Lichteintrittsseite auf das optische Element auftreffende Licht in seinen Ausbreitungsrichtungen verändert ist,
• - und wobei ferner mindestens ein Teil des an der Lichteintrittsseite des optischen Elements in erste Bereiche E1 einfallenden Lichtes nach Durchgang durch das optische Element gebündelt ist.

This object is achieved according to the invention by a planar optical element with a light entry side and a light exit side, comprising

• - first regions E1 consisting of at least one transparent material with a first refractive index N1 and second regions E2 consisting of an opaque material and/or transparent and/or reflective or scattering material with a second refractive index N2, wherein the first regions E1 are embedded in the second regions E2 in a one- or two-dimensional (preferably, but not necessarily periodic) pattern, wherein the first refractive index N1 is greater than the second refractive index N2 over the entire wavelength range visible to the human eye,
• - wherein the first regions E1 each have a larger cross-section on the light exit side than on the light entry side, and wherein, furthermore, the first regions E1, when viewed in parallel projection perpendicular to the optical element, each have different outline shapes on the light incidence side and on the light exit side, which cannot be brought into congruence by scaling,
• - so that on the light entry side of the optical element, light incident on the latter, which enters first regions E1 of the optical element, is reflected there depending on the geometric direction of incidence, polarization and the ratio of the first refractive index N1 to the second refractive index N2
  1. a) is propagated or totally reflected unhindered within a first area E1 and is then coupled out again at the light exit side of the corresponding first area E1, or
  2. b) penetrates from the first region E1 into an adjacent second region E2 and, if it is not absorbed in the second region E2, propagates in a second region E2 until it is coupled out of a second region E2 on the light exit side or coupled into one or more next first and/or second regions E1, E2 (and so on),
• - and so that in a first alternative, in which the second regions E2 consist of a transparent material, light which is incident on the light entry side of the optical element into second regions E2 of the optical element, penetrates the latter and is coupled out of the optical element on the light exit side,
• - and so that in a second alternative, in which the second regions E2 at least partially comprise an opaque material, light incident on the light entry side of the optical element into second regions E2 of the optical element is at least partially absorbed,
• - and so that in a third alternative, in which the second regions E2 at least partially comprise a reflective and/or scattering material, light incident on the light entry side of the optical element into second regions E2 of the optical element is at least partially reflected and/or scattered,
• - whereby the light emerging from the optical element at the light exit side is changed in its propagation directions compared to the light incident on the optical element at the light entry side,
• - and wherein furthermore at least a part of the light incident on the light entry side of the optical element into first regions E1 is bundled after passing through the optical element.

The “geometric direction of incidence” of a light beam into the first regions refers in particular to its direction vector, which describes the horizontal and vertical angle of incidence onto the light entry surface – also referred to as the “lower surface” – of a first region and, in addition to the polarization state, is essential for the further propagation of the light in the first region E1 or at the interfaces to second regions E2.

The "periodic sequence" of the first and second areas E1, E2 does not mean that they always have to be the same width and/or height, but rather that the first and second areas simply alternate. Their size can vary, however.

In general, the smaller the difference in refractive index between the first refractive index N1 and the second refractive index N2, the narrower the light distribution of the light leaving the optical element from the first areas E1. For a clear physical understanding, a It should be noted that "refractive index" refers to either the first or second refractive index N1, N2 for a selected wavelength, e.g., 580 nm, or the respective dispersion curve over the entire wavelength range visible to the human eye. In the case of the dispersion curve, the refractive index difference refers to the respective value that corresponds to the difference between the two refractive indices N1, N2 at a selected visible wavelength λ.

The interfaces of the first regions E1 and the second regions E2 of the optical element, when viewed in the cutting direction perpendicular to the light exit side of the optical element, can be trapezoidal (in particular, but not exclusively, trapezoidal with equally long sides of the trapezoid), funnel-shaped, at least partially or entirely parabolic, parallelogram-shaped, and/or step-shaped. Furthermore, it is possible for said interfaces to generally have the shape of an nth-degree polynomial in the cutting direction. Furthermore, mixed forms of the aforementioned possibilities are also possible in one and the same interface, for example if, within an interface, a partial step shape is followed by a parabolic portion.

The previously described configurations of the first and second regions E1, E2 allow for a targeted influence on the propagation directions of the light emerging from the optical element: Depending on the design, the light is focused more or less strongly across the surface. Furthermore, it is possible, for example, to achieve a peak shift by using parallelogram-shaped interfaces between the first and second regions E1, E2 through the associated tilting of the interfaces between the first and second regions E1, E2. The trapezoidal shape, in turn, has the additional advantage of ensuring a good focus of the angular distribution.

It is advantageous - but not exclusive - that the difference in refractive index between the first refractive index N1 and the second refractive index N2 is less than 0.25.

If, in the context of the second alternative, opaque material is present in second areas E2, this can optionally consist of an originally transparent material with the second refractive index N2, which, however, is mixed with absorbing particles, resulting in an overall opaque effect.

The opaque material can, for example, consist of a lacquer or polymer as the transparent portion, which is mixed with, for example, graphite particles with a size of less than 500 nm in the direction of their greatest dimension, or with black carbon nanoparticles with a size of less than 200 nm, for example with soot particles, for the opaque portion. Alternatively, or in combination, the opaque portion of the opaque material can also contain dyes or mixtures of dyes. A suitable dye, for example, is Sudan black, which absorbs all light in the visible range. Typically, the mass fraction of the absorbing particles is at most 50%, preferably less than 20%, particularly preferably less than 10%.

If, in the context of the third alternative, reflective or scattering material is present in second regions E2, this consists, for example, of a mixture of a paint and particles, whereby the particles are now reflective and/or scattering. The particles can be, for example, white-scattering particles such as titanium dioxide (TiO2) or reflective particles such as silver particles or chromium particles with a size of less than 500 nm.

The third alternative has the following general advantages: apart from general losses, light is not lost in the light balance due to permanent absorption. Compared to the first alternative, in which the second regions E2 are filled with a transparent material, this prevents a type of "crosstalk" of light rays and thus suppresses a type of blending effect, for example when the optical element is used together with an image display unit and its pixels are assigned to first regions E1 of the optical element. This is because in the third alternative, light from pixels that are not assigned to a specific first region E1 is not simply transmitted through a second region E2 (first alternative), but is reflected or scattered, which also means that it would no longer be unavailable due to absorption, as in the second alternative.

If such an optical element of the third alternative is used in an arrangement with a backlight, a (large) part of the light incident on the light entry surface of the optical element, which is reflected or scattered at second areas E2, can be recycled, e.g., in an underlying light source, i.e. the said backlight.

Furthermore, the first regions E1 and the second regions E2 can be arranged in strip-like fashion, distributed alternately over the surface of the optical element when viewed in parallel projection perpendicular to the optical element. In contrast, another embodiment provides that the first regions, when viewed in parallel projection perpendicular to the optical element, are arranged in a point-like, circular, oval, rectangular, hexagonal, or other two-dimensional shape distributed over the surface of the optical element, on the light incidence side or the light exit side, and that the second regions are each shaped complementarily thereto. This would restrict the light propagation directions in at least two planes that are perpendicular to the surface of the optical element. In practice, the effect of such an optical element is generally such that the light propagation directions for transmitted light are focused at angles close to the perpendicular bisector of the optical element or parallel to it. By "close" in this case, we mean that the deviations from the perpendicular bisector or the parallel to it are less than 20° or 30°, depending on the embodiment.

Other shapes of the first and second regions E1, E2 are also possible. To maintain the functionality of the invention, it is always important that the first and second regions E1, E2 are optically directly adjacent to one another, so that an optical refractive index jump from the first refractive index N1 to the second refractive index N2 (or vice versa) occurs, if possible, without an air gap.

As described above, it is possible that the first regions E1, when viewed in parallel projection perpendicular to the optical element, exhibit different contour shapes on the light incidence side and the light exit side of the optical element, which cannot be made congruent by scaling. The same applies to the second regions E2.

For special embodiments, it is conceivable that a lens structure, preferably a convex lens structure, is applied to at least a part of the first regions E1 and/or the second regions E2, advantageously to all first regions E1 and/or all second regions E2, on whose light exit side a lens structure is applied.

The invention also improves the state of the art in that a top-hat distribution can be achieved with such optical elements, since due to the total reflection more useful light is transmitted into the desired angular ranges than - as is usual in the state of the art - without the total reflection.

For special embodiments, it is possible for at least one first region E1 to be formed on the optical element, which, when viewed in parallel projection perpendicular to the optical element, is at least twenty times as large in its shortest extent as the shortest extent of all second regions E2 when viewed in parallel projection perpendicular to the optical element, so that within said at least one first region E1, except at its edges and except for parallel offsets, there is no restriction of the propagation directions of the light emerging from the optical element on the light exit side compared to the light incident on the optical element on the light entry side.

Furthermore, it is possible that, in addition to the first regions E1 and the second regions E2, further third, fourth, etc. regions are formed with different parameters in terms of shape and/or refractive index than those of the first regions E1 and the second regions E2, so that light which penetrates these further third, fourth regions and exits from the optical element experiences different restrictions of the propagation directions than in the first regions E1.

It should be noted that the optical element of the second or third alternative can, in special embodiments, be designed as a very precise, wavelength-selective color filter: If the dispersion curves of both refractive indices N1, N2 intersect as a function of the wavelength, then, in the case of opaque second regions E2 according to the second alternative, at those wavelengths where the second refractive index N2 is greater than the first refractive index N1, the corresponding wavelength range would be efficiently extinguished, i.e., not coupled out of the optical element, while the wavelength ranges for which the first refractive index N1 is greater than the second refractive index N2 would be coupled out of the optical element. Depending on the configuration of the dispersion curves, such an optical element with wavelength-selective effect would then have to be operated with obliquely directed light, because in any case, the critical angle of total reflection at the interfaces between the first and second regions E1, E2 must be used to separate the spectra. In an exemplary further development, such a wavelength-selective color filter would then be used to separate two spectra, for example one in a narrow UV range and one in a white, spectrally wide range.

Furthermore, it can be helpful to place a polarizer, optionally a reflective polarizer, below and/or above the optical element to optimize the effect. Controlling polarization with a polarizer increases the efficiency of using the refractive index transitions. Furthermore, the p-polarization of the incoming or outgoing light can be used to minimize Fresnel reflections, ie, To optimize the restriction of light propagation directions.

• - in einer ersten Alternative Abformung zweiter Bereiche E2 auf einem Substrat S, wobei die entsprechenden Strukturen mit einem Werkzeug, welches die inverse Form der Strukturen der zweiten Bereiche E2 aufweist, in ein prägbares Material mit der zweiten Brechzahl N2 -welche für den ausgehärteten Zustand gilt- eingeprägt und hernach ausgehärtet werden, z.B. in einem Nanoimprint- oder in einem variothermen oder isothermen Spritzguss-/Spritzpräge-Verfahren,
• - in einer zweiten Alternative Abformung erster Bereiche E1 auf einem Substrat S, wobei die entsprechenden Strukturen mit einem Werkzeug, welches die inverse Form der Strukturen der ersten Bereiche E1 aufweist, in ein erstes, prägbares Material mit der ersten Brechzahl N1 -welche für den ausgehärteten Zustand gilt- eingeprägt und hernach ausgehärtet werden, z.B. in einem Nanoimprint- oder in einem variothermen oder isothermen Spritzguss-/Spritzpräge-Verfahren,
• - in der ersten Alternative Befüllen der Zwischenräume der zweiten Bereiche E2 mit einem Material mit der ersten Brechzahl N1 -welche für den ausgehärteten Zustand gilt-, wodurch die ersten Bereiche E1 entstehen,
• - in der zweiten Alternative Befüllen der Zwischenräume der ersten Bereiche E1 mit einem Material mit der zweiten Brechzahl N2 -welche für den ausgehärteten Zustand gilt-, wodurch die zweiten Bereiche E2 entstehen, (das Befüllen kann in beiden Alternativen in einem oder in mehreren Schritten geschehen, wobei zwischen solchen Befüllungsschritten ggf. auch ein oder mehrere Zwischenaushärteschritte folgen kann),
• - Aushärten des zweiten Materials, z.B. durch Bestrahlung mit UV-Licht, wenn das zweite Material UV-lichthärtend ist, oder durch Auskühlung, wenn es sich um ein Spritzguss- oder -prägeverfahren handelt,
• - Optionales Versiegeln der ersten und zweiten Bereiche E1, E2 auf ihrer nicht dem Substrat S zugewandten Seite durch Aufbringen eines Lackes und oder einer Deckschicht.

The invention further includes a method for producing an optical element as described above, comprising the following steps:

• - in a first alternative, molding of second regions E2 on a substrate S, wherein the corresponding structures are embossed into an embossable material with the second refractive index N2 - which applies to the cured state - using a tool having the inverse shape of the structures of the second regions E2, and are subsequently cured, e.g. in a nanoimprint or in a variothermal or isothermal injection molding/injection compression molding process,
• - in a second alternative, molding of first regions E1 on a substrate S, wherein the corresponding structures are embossed into a first, embossable material with the first refractive index N1 - which applies to the cured state - using a tool which has the inverse shape of the structures of the first regions E1, and are subsequently cured, e.g. in a nanoimprint or in a variothermal or isothermal injection molding/injection compression molding process,
• - in the first alternative, filling the spaces between the second regions E2 with a material having the first refractive index N1 -which applies to the cured state-, whereby the first regions E1 are formed,
• - in the second alternative, filling the spaces between the first regions E1 with a material having the second refractive index N2 - which applies to the cured state -, thereby creating the second regions E2 (in both alternatives, the filling can be carried out in one or more steps, whereby one or more intermediate curing steps can also follow between such filling steps, if necessary),
• - Curing of the second material, e.g. by irradiation with UV light if the second material is UV-curing, or by cooling if it is an injection moulding or embossing process,
• - Optional sealing of the first and second areas E1, E2 on their side not facing the substrate S by applying a varnish and/or a cover layer.

It should also be noted that for a nanoimprint process, depending on the manufacturing process alternative selected, the embossable material with the second or first refractive index N2 or N1—which applies to the cured state—is applied to a substrate S (e.g., glass or polymer) as a separate (usually liquid) material, which is then cured, for example, with UV light. In contrast, in a variothermal or isothermal injection molding/injection-compression molding process, the material of the substrate S simultaneously represents the material into which the structures, i.e., the second or first regions E2, E1, are embossed and then cured by cooling. Other manufacturing processes are possible. In principle, both manufacturing process alternatives can be used, although the first manufacturing process alternative can preferably be used for the first optical element alternative, i.e., when the materials of the first and second regions E1, E2 are transparent. In particular, the second alternative of the manufacturing process can be used flexibly for all alternatives of the design of the optical element.

Depending on the actual design, the aforementioned process for manufacturing an optical element can be implemented as a sheet-to-sheet, roll-to-plate, or roll-to-roll setup. This also simplifies filling, for example, with a varnish. In particular, the first alternative allows for the use of a transparent varnish, which makes the process more cost-effective and simpler.

• - eine Bildwiedergabeeinheit,
• - ein optisches Element wie vorstehend beschrieben, wobei das optische Element in Betrachtungsrichtung eines Betrachters vor oder hinter der Bildwiedergabeeinheit angeordnet ist, wobei bevorzugt bei Parallelprojektion aus senkrechter Richtung auf die Bildwiedergabeeinheit jeweils die zweiten Bereiche E2 vor nicht (oder im Wesentlichen nicht) Licht abstrahlenden Flächenabschnitten der Bildwiedergabeeinheit liegen.

Furthermore, the invention comprises a first screen comprising

• - an image display unit,
• - an optical element as described above, wherein the optical element is arranged in front of or behind the image display unit in the viewing direction of a viewer, wherein preferably in the case of parallel projection from a perpendicular direction onto the image display unit, the second regions E2 are in front of surface sections of the image display unit which do not (or substantially do not) emit light.

Non-light-emitting surface sections of the image display unit can, for example, be the black matrix areas of an OLED, microLED, or LCD panel or deactivated pixels (possibly including the respective black matrix areas of an OLED, LCD, or microLED panel). Other configurations are possible.

Advantageously, the invention can also be implemented in such a way that the optical element is arranged in front of or behind the image display unit in the viewing direction of a viewer in such a way that In the case of parallel projection from a vertical direction onto the image display unit, the first regions E1 of the optical element are located in front of light-emitting surface sections, i.e. in particular pixels (color subpixels, full-color pixels, monochrome or other types of pixels) of the image display unit.

This is where a particular advantage of the invention becomes apparent: It allows the light emitted by a screen to be focused on a desired viewing or angular range with minimal loss. Thus, the invention can achieve a defined distribution of the luminance curve in one or two dimensions. If the luminance curve is rather broad, the content displayed by the image display unit can be viewed from a wide angle, while still allowing greater efficiency to be achieved compared to the prior art by varying the parameters of the optical element to achieve the desired luminance curve.

In the first screen, it is advantageous if the optical element is optically bonded or laminated to the image display unit.

In the event that an optical element according to the invention is arranged in front of an image display unit in the viewing direction in order to limit its light propagation directions, an optical system can optionally be present on the image display unit, which essentially focuses the light emitted by the respective pixels of the image display device onto the surfaces opposite the first regions E1. This is possible, for example, with microlens grids or lenticular lenses that have approximately the periods of the pixel widths (or, if applicable, pixel heights). The period of the first regions E1 should then ideally correspond to the period of the pixel widths or heights, or integer multiples thereof.

• - eine Hintergrundbeleuchtung,
• - ein in Betrachtungsrichtung eines Betrachters vor der Hintergrundbeleuchtung angeordnetes optisches Element, wie vorstehend beschrieben.

Auch hier erlaubt die Erfindung eine definierte Fokussierung des von der Beleuchtungseinrichtung abgesandten Lichtes auf einen gewünschten Betrachtungsbereich, d.h. auf eine definierte Leuchtdichtekurve, sinngemäß wie weiter oben zum ersten Bildschirm beschrieben.Furthermore, the invention also includes a lighting device comprising

• - a backlight,
• - an optical element arranged in front of the backlight in the viewing direction of a viewer, as described above.

Here too, the invention allows a defined focusing of the light emitted by the illumination device onto a desired viewing area, ie onto a defined luminance curve, in the same way as described above for the first screen.

Furthermore, the illumination device can be configured such that at least one partial mirror coating is applied to the first and/or second regions E1, E2 on the light entry side of the optical element. This allows the efficiency of the illumination device to be further increased.

• - eine Beleuchtungseinrichtung wie vorstehend beschrieben, und
• - eine in Betrachtungsrichtung eines Betrachters vor der Beleuchtungseinrichtung angeordnete transmissive zweite Bildwiedergabeeinheit, wie etwa ein LCD-Panel.

Finally, the invention comprises a second screen comprising

• - a lighting device as described above, and
• - a transmissive second image display unit, such as an LCD panel, arranged in front of the illumination device in the viewing direction of a viewer.

In the latter case, the optical element would typically be integrated directly into an illumination device for a transmissive image display unit, such as an LCD panel.

In general, for all optical elements, the roughness _Ra at the interfaces between first and second regions E1, E2 with different refractive indices N1, N2 should preferably be less than or equal to 20 nm. However, other designs, even with higher values of the roughness _Ra , are possible.

A screen comprising at least one optical element as described above and an image display unit can be used, for example, in a monitor or a mobile device. Furthermore, it may also be possible to retrofit an image display unit with a first optical element by arranging it in front of the image display unit.

The invention is particularly advantageous for applications where no air layers or gaps are permitted, i.e., where all layers must be laminated without compromising optical performance. A further advantage, compared to the use of parabolic mirrors for light focusing, is that the structures used in the invention can essentially operate without any reflective coating, since they primarily achieve their advantageous performance through the difference in refractive index.

In principle, the performance of the invention is maintained if the parameters described above are varied within certain limits.

It is understood that the features mentioned above and those to be explained below are not only available in the combinations indicated, but also in other combinations or can be used alone without departing from the scope of the present invention.

Short description of the drawings

• 1 die Prinzipskizze (Schnittdarstellung) eines optischen Elements in einer beispielhaften ersten Ausgestaltung,
• 2 die Prinzipskizze (Schnittdarstellung) eines optischen Elements in einer beispielhaften zweiten Ausgestaltung,
• 3 die Prinzipskizze (Schnittdarstellung) eines optischen Elements in der beispielhaften ersten Ausgestaltung, kombiniert mit Pixeln und einer Blackmatrix einer Bildwiedergabeeinheit,
• 4 die Prinzipskizze (Schnittdarstellung) eines optischen Elements in der beispielhaften zweiten Ausgestaltung, kombiniert mit Pixeln und einer Blackmatrix einer Bildwiedergabeeinheit,
• 5 die Prinzipskizze (Schnittdarstellung) eines optischen Elements in einer beispielhaften dritten Ausgestaltung,
• 6 die Prinzipskizze (Schnittdarstellung) eines optischen Elements in einer beispielhaften vierten Ausgestaltung, kombiniert mit Pixeln und einer Blackmatrix einer Bildwiedergabeeinheit,
• 7a die Prinzipskizze (Perspektivansicht) eines optischen Elements in der beispielhaften fünften Ausgestaltung, kombiniert mit Pixeln und einer Blackmatrix einer Bildwiedergabeeinheit,
• 7b die Prinzipskizze (Perspektivansicht) eines optischen Elements in der beispielhaften sechsten Ausgestaltung, kombiniert mit Pixeln und einer Blackmatrix einer Bildwiedergabeeinheit, sowie
• 8 beispielhafte Simulationsergebnisse für verschiedene Parameter beispielhafter optischer Elemente in der ersten Ausgestaltung im Vergleich mit einem Referenzwert.

The invention will now be explained in more detail using exemplary embodiments with reference to the accompanying drawings, which also disclose features essential to the invention. These exemplary embodiments are merely illustrative and are not to be interpreted as limiting. For example, a description of an exemplary embodiment with a plurality of elements or components should not be interpreted as meaning that all of these elements or components are necessary for implementation. Rather, other exemplary embodiments may also contain alternative elements and components, fewer elements or components, or additional elements or components. Elements or components of different exemplary embodiments may be combined with one another unless otherwise stated. Modifications and variations described for one of the exemplary embodiments may also be applicable to other exemplary embodiments. To avoid repetition, identical or corresponding elements in different figures are designated by the same reference numerals and are not explained more than once. They show:

• 1 the schematic diagram (sectional view) of an optical element in an exemplary first embodiment,
• 2 the schematic diagram (sectional view) of an optical element in an exemplary second embodiment,
• 3 the schematic diagram (sectional view) of an optical element in the exemplary first embodiment, combined with pixels and a black matrix of an image display unit,
• 4 the schematic diagram (sectional view) of an optical element in the exemplary second embodiment, combined with pixels and a black matrix of an image display unit,
• 5 the schematic diagram (sectional view) of an optical element in an exemplary third embodiment,
• 6 the schematic diagram (sectional view) of an optical element in an exemplary fourth embodiment, combined with pixels and a black matrix of an image display unit,
• 7a the schematic diagram (perspective view) of an optical element in the exemplary fifth embodiment, combined with pixels and a black matrix of an image display unit,
• 7b the schematic diagram (perspective view) of an optical element in the exemplary sixth embodiment, combined with pixels and a black matrix of an image display unit, and
• 8 exemplary simulation results for various parameters of exemplary optical elements in the first embodiment in comparison with a reference value.

Detailed description of the drawings

The drawings are not to scale and merely represent schematic diagrams. Furthermore, for clarity, only a few light rays are shown, although in reality there are many.

• - mindestens aus einem transparenten Material mit einer ersten Brechzahl N1 bestehende erste Bereiche E1 und aus einem opaken Material und/oder transparenten und/oder reflektierendem oder streuenden Material mit einer zweiten Brechzahl N2 bestehende zweite Bereiche E2, wobei die ersten Bereiche E1 in einem ein- oder zweidimensionalen (bevorzugt, aber nicht notwendigerweise periodischen) Muster in die zweiten Bereiche E2 eingebettet sind, wobei die erste Brechzahl N1 im gesamten für ein menschliches Auge sichtbaren Wellenlängenbereich größer ist als die zweite Brechzahl N2,
• - wobei die ersten Bereiche E1 jeweils an der Lichtaustrittsseite einen größeren Querschnitt als an der Lichteintrittsseite aufweisen, und wobei ferner (zeichnerisch nicht dargestellt) die ersten Bereiche E1 bei Betrachtung in Parallelprojektion senkrecht auf das optische Element 10 jeweils an der Lichteinfallsseite und an der Lichtausfallsseite unterschiedliche Umrissformen aufweisen, die nicht durch Größenskalierung zur Kongruenz zu bringen sind,
• - so dass an der Lichteintrittsseite des optischen Elements 10 auf dieses auftreffende Licht, welches in erste Bereiche E1 des optischen Elements 10 einfällt, dort je nach geometrischer Einfallsrichtung, Polarisation und dem Verhältnis der ersten Brechzahl N1 zu der zweiten Brechzahl N2
  1. a) innerhalb eines ersten Bereiches E1 ungehindert propagiert oder totalreflektiert wird und hernach an der Lichtaustrittsseite des entsprechenden ersten Bereiches E1 wieder ausgekoppelt wird, oder
  2. b) von dem ersten Bereich E1 in einen angrenzenden zweiten Bereich E2 eindringt und, wenn es im zweiten Bereich E2 nicht absorbiert wird, in einem zweiten Bereich E2 propagiert, bis es auf der Lichtaustrittsseite aus einem zweiten Bereich E2 ausgekoppelt oder in einen oder mehrere nächste erste und/oder zweite Bereiche E1, E2 eingekoppelt wird (und so weiter),
• - und so dass in einer ersten Alternative, in welcher die zweiten Bereiche E2 aus einem transparenten Material bestehen, Licht, das an der Lichteintrittsseite des optischen Elements 10 in zweite Bereiche E2 des optischen Elements 10 einfällt, dieses durchdringt und auf der Lichtaustrittsseite aus dem optischen Element 10 ausgekoppelt wird,
• - und so dass in einer zweiten Alternative, in welcher die zweiten Bereiche E2 mindestens teilweise ein opakes Material umfassen, Licht, das an der Lichteintrittsseite des optischen Elements 10 in zweite Bereiche E2 des optischen Elements 10 einfällt, mindestens teilweise absorbiert wird,
• - und so dass in einer dritten Alternative, in welcher die zweiten Bereiche E2 mindestens teilweise ein reflektierendes und/oder streuendes Material umfassen, Licht, das an der Lichteintrittsseite des optischen Elements 10 in zweite Bereiche E2 des optischen Elements 10 einfällt, mindestens teilweise reflektiert und/oder gestreut wird,
• - wodurch das an der Lichtaustrittsseite des optischen Elements 10 aus diesem austretende Licht gegenüber dem an der Lichteintrittsseite auf das optische Element 10 auftreffende Licht in seinen Ausbreitungsrichtungen verändert ist,
• - und wobei ferner mindestens ein Teil des an der Lichteintrittsseite des optischen Elements 10 in erste Bereiche E1 einfallenden Lichtes nach Durchgang durch das optische Element 10 gebündelt ist.

The 1 shows a schematic diagram of an optical element 10 in an exemplary first embodiment in a sectional view and as an enlarged detail. The optical element 10 shown therein is flat (the surface is notionally perpendicular to the plane of the paper) and has a light entry side (here: lower surface) and a light exit side (here: upper surface).

• - first regions E1 consisting of at least one transparent material with a first refractive index N1 and second regions E2 consisting of an opaque material and/or transparent and/or reflective or scattering material with a second refractive index N2, wherein the first regions E1 are embedded in the second regions E2 in a one- or two-dimensional (preferably, but not necessarily periodic) pattern, wherein the first refractive index N1 is greater than the second refractive index N2 over the entire wavelength range visible to the human eye,
• - wherein the first regions E1 each have a larger cross-section on the light exit side than on the light entry side, and wherein furthermore (not shown in the drawing) the first regions E1, when viewed in parallel projection perpendicular to the optical element 10, each have different outline shapes on the light incidence side and on the light exit side, which cannot be brought into congruence by scaling,
• - so that on the light entry side of the optical element 10, the light incident on the optical element 10, which is incident in first areas E1 of the optical element 10, is reflected there depending on the geometric direction of incidence, polarization and the behavior nis of the first refractive index N1 to the second refractive index N2
  1. a) is propagated or totally reflected unhindered within a first area E1 and is then coupled out again at the light exit side of the corresponding first area E1, or
  2. b) penetrates from the first region E1 into an adjacent second region E2 and, if it is not absorbed in the second region E2, propagates in a second region E2 until it is coupled out of a second region E2 on the light exit side or coupled into one or more next first and/or second regions E1, E2 (and so on),
• - and so that in a first alternative, in which the second regions E2 consist of a transparent material, light which is incident on the light entry side of the optical element 10 into second regions E2 of the optical element 10, penetrates the latter and is coupled out of the optical element 10 on the light exit side,
• - and so that in a second alternative, in which the second regions E2 at least partially comprise an opaque material, light incident on the light entry side of the optical element 10 into second regions E2 of the optical element 10 is at least partially absorbed,
• - and so that in a third alternative, in which the second regions E2 at least partially comprise a reflective and/or scattering material, light incident on the light entry side of the optical element 10 into second regions E2 of the optical element 10 is at least partially reflected and/or scattered,
• - whereby the light emerging from the optical element 10 at the light exit side is changed in its propagation directions compared to the light incident on the optical element 10 at the light entry side,
• - and wherein furthermore at least a part of the light incident on the light entry side of the optical element 10 into first regions E1 is bundled after passing through the optical element 10.

The “geometric direction of incidence” of a light beam into the first regions E1 refers in particular to its direction vector, which describes the horizontal and vertical angle of incidence onto the light entry surface – also referred to as the “lower surface” – of a first region E2 and, in addition to the polarization state, is essential for the further propagation of the light in the first region E1 or at the interfaces to second regions E2.

The "periodic sequence" of the first and second areas E1, E2 does not mean that they must always be the same width and/or height, but rather that the first and second areas simply alternate. Their size can, however, vary. 1 (and also 2 and other drawings), only two first regions E1 and three second regions E2 (or possibly fewer) are shown. However, in the physical design of an optical element 10, significantly more such first and second regions E1, E2 are present.

In general, the smaller the refractive index difference between the first refractive index N1 and the second refractive index N2, the narrower the light distribution of the light leaving the optical element 10 from the first regions E1. For clarity of physics, it should be noted again here that "refractive index" refers to either the first or second refractive index N1, N2 for a selected wavelength, e.g., 580 nm, or the respective dispersion curve across the entire wavelength range visible to the human eye. In the case of the dispersion curve, the refractive index difference refers to the respective value that corresponds to the difference between the two refractive indices N1, N2 at a selected visible wavelength λ.

The interfaces of the first regions E1 and the second regions E2 of the optical element 10 can assume different configurations when viewed in the sectional direction perpendicular to the light exit side of the optical element 10. In the exemplary first configuration according to 1 These are trapezoidal, e.g. funnel-shaped. In contrast, in 2 , which shows an exemplary second embodiment of the optical element 10, the interfaces are formed in an approximately parabolic shape (more precisely as sections of parabolas).

The previously described configurations of the first and second areas E1, E2 allow for a targeted influence on the propagation directions of the light emerging from the optical element 10: Depending on the configuration, the light is focused more or less strongly across the surface. The trapezoidal and parabolic shapes have the advantage of providing good focus for the angular distribution.

Advantageously, but not exclusively, the difference in refractive index between the first refractive index N1 and the second refractive index N2 is less than 0.25.

If, in the context of the second alternative, opaque material is present in second areas E2, this can optionally consist of an originally transparent material with the second refractive index N2, which, however, is mixed with absorbing particles, resulting in an overall opaque effect.

Furthermore, 3 , corresponding to 1 , the schematic diagram (in a sectional view and as a detail) of an optical element 10 in the exemplary first embodiment, combined with pixels 1 and a so-called “black matrix” 2 of an image display unit. In the actual embodiment, there are significantly more pixels 1. The black matrix 2 is shown exaggeratedly large here to underline its effect, namely that no light is actively emitted from there. In the left first area E1 it can be seen that due to the functioning of the optical element 10 the exemplary beams S1 and S2 emitted by a left pixel 1 directly below are directed closer to the vertical. In the right pixel 1, above which a first area E1 is located, an exemplary light beam S3 incident obliquely into the first area E1 is refracted further away from the vertical and penetrates into an adjacent second area E2. Depending on the alternative, it can propagate there (e.g. in the first alternative with transparent material for the second areas E2) and would then be coupled out at the light exit side or alternatively passed on via total reflection, is absorbed (e.g. in the second alternative with opaque material for the second areas E2), or it is scattered or reflected in the (e.g. in the third alternative with reflective and/or scattering material for the second areas E2).

Furthermore, 4 , corresponding to 2 , the schematic diagram (in sectional view and as a detail) of an optical element 10 in the exemplary second embodiment, combined with pixels 1 and a so-called "black matrix" 2 of an image display unit. In the right pixel 1, above which a first region E1 is located, an exemplary light beam S3 incident obliquely into the first region E1 is refracted further away from the normal and penetrates into an adjacent second region E2. Depending on the alternative, it can propagate there (e.g. in the first alternative with transparent material for the second regions E2), is absorbed (e.g. in the second alternative with opaque material for the second regions E2), or it is scattered or reflected (e.g. in the third alternative with reflective and/or scattering material for the second regions E2). The 3 The other explanations given for the exemplary beams S1 and S2 are applicable here mutatis mutandis and are therefore not repeated here.

Insofar as the design involves the two alternatives with opaque material, this can, for example, consist of a lacquer or polymer as the transparent part, which is mixed with, for example, graphite particles having a size of less than 500 nm in the direction of their greatest extent, or nanoparticles of black carbon having a size of less than 200 nm, for example with soot particles, for the opaque part.

If, in the context of the third alternative, reflective or scattering material is present in second regions E2, this consists, for example, of a mixture of a paint and particles, whereby the particles are now reflective and/or scattering. The particles can be, for example, white-scattering particles such as titanium dioxide (TiO2) or reflective particles such as silver particles or chromium particles with a size of less than 500 nm.

If such an optical element of the third alternative is used in an arrangement with a backlight, a (large) part of the light incident on the light entry surface of the optical element 10, which is reflected or scattered at second areas E2, can be recycled, e.g., in an underlying light source, as the said backlight.

Furthermore, the first regions E1 and the second regions E2 can be arranged in strip-like manner distributed alternately over the surface of the optical element 10 when viewed in parallel projection perpendicular to the optical element 10, as for example for the exemplary first and second embodiments according to 1 until 4 .

In addition, 5 the schematic diagram (sectional view and as a detail) of an optical element 10 in an exemplary third embodiment. The arrangement and mode of operation of the first and second regions E1, E2 are governed by the explanations in the drawing. 1 However, here, between a transparent substrate S (e.g., made of glass or polymer) and the first optical element 10, there are transparent and opaque sections 4, 5, wherein, in the projection direction, transparent sections 4 are arranged parallel to the surface center perpendicular between the substrate S and first regions E1, and opaque sections 5 are arranged between the substrate S and second regions E2. This third embodiment ensures that on the light entry side of the optical element 10, only light enters through the first regions E1.

Furthermore, there are 6 the principle sketch (sectional view and as a detail) of an opti optical element 10 in an exemplary fourth embodiment, combined with pixels 1 and a black matrix 2 of an image display unit. Furthermore, on the light exit side of the optical element 10 in the projection direction parallel to the surface center perpendicular, opaque sections 3 are present exclusively in the second regions E2. This embodiment serves to optimize the light direction and avoids crosstalk, for example by exemplary rays S3, as in 3 shown.

A particularly advantageous, exemplary fifth embodiment of an optical element 10, again combined with pixels 1 (which are shown here in a simplified circular manner and can correspond to color subpixels, full-color pixels, monochrome or other types of pixels) and a black matrix 2 of an image display unit, is shown as a schematic diagram (here as a perspective view and in detail) in 7a shown. It is provided that the first regions E1 (which have a funnel shape in section) are arranged, when viewed in parallel projection perpendicular to the optical element 10, in a circular shape on the light incidence side or the light exit side, distributed over the surface of the optical element 10, and the second regions E2 (not shown in the drawing) are each shaped complementarily thereto. This restricts the light propagation directions in at least two planes that are perpendicular to the surface of the optical element 10. In practice, the effect of such an optical element 10 is generally such that the light propagation directions for light emitted (or transmitted) by the pixels 1 are focused at any angle close to the perpendicular bisector of the optical element 10 or parallel thereto. By "close" in this case is meant that the deviations from the perpendicular bisector or the parallel thereto - depending on the design - are less than 20° or 30°.

An advantageous, exemplary sixth embodiment is in modification to 7a in 7b The change to 7a is that the pixels 1 according to 7b are now shown in rectangular form. In practical implementation, completely different shapes or outlines of pixels 1 are also possible, such as chevron structures made of IPS/FFS cells or various sizes and shapes for R, G, and B color subpixels, such as in the case of OLED panels as image display devices.

The invention also improves the prior art in that with such optical elements 10, a top-hat distribution can be achieved, since due to the total reflection more useful light is transmitted into the desired angular ranges than - as is usual in the prior art - without the total reflection.

There is 8 exemplary simulation results for various parameter configurations of exemplary optical elements 10 in the first embodiment in comparison with a reference value.

By varying the input parameters, various defined distributions of the transmission of the optical element 10 can be achieved, for example, a so-called top-hat distribution (see example 1). The graphs are normalized to the 0° viewing angle of the reference and show the relative luminance at the various horizontal viewing angles. Basically, the ratios were calculated according to 1 (i.e., trapezoidal or funnel shape of the interfaces of the first and second areas E1, E2 in section). The simulated parameters are as follows:

Reference: Lambertian light source (e.g. OLED), each with one optical element, but where N1=N2 applies.

1. a. Dicke des optischen Elements 10: 70 µm
2. b. Breite der ersten Bereiche E1 an der Lichteintrittsseite: 10 µm
3. c. Betrag des Grenzwinkels zwischen ersten und zweiten Bereichen E1, E2: 8°
4. d. Versatz zwischen dem Ende eines ersten Bereiche E1 und einer Kante eines darunter angenommenen Pixels 1 einer Bildwiedergabeeinheit: 0.0 µm
5. e. Differenz N2 zu N1: 0.140

Example 1:

1. a. Thickness of optical element 10: 70 µm
2. b. Width of the first areas E1 on the light entrance side: 10 µm
3. c. Amount of the critical angle between the first and second areas E1, E2: 8°
4. d. Offset between the end of a first area E1 and an edge of an assumed pixel 1 of an image display unit: 0.0 µm
5. e. Difference N2 to N1: 0.140

1. a. Dicke des optischen Elements 10: 60 µm
2. b. Breite der ersten Bereiche E1 an der Lichteintrittsseite: 14 µm
3. c. Betrag des Grenzwinkels zwischen ersten und zweiten Bereichen E1, E2: 8°
4. d. Versatz zwischen dem Ende eines ersten Bereiche E1 und einer Kante eines darunter angenommenen Pixels 1 einer Bildwiedergabeeinheit: 5.0 µm
5. e. Differenz N2 zu N1: 0.120

Example 2:

1. a. Thickness of optical element 10: 60 µm
2. b. Width of the first areas E1 on the light entrance side: 14 µm
3. c. Amount of the critical angle between the first and second areas E1, E2: 8°
4. d. Offset between the end of a first area E1 and an edge of an assumed pixel 1 of an image display unit: 5.0 µm
5. e. Difference N2 to N1: 0.120

1. a. Dicke des optischen Elements 10: 60 µm
2. b. Breite der ersten Bereiche E1 an der Lichteintrittsseite: 15 µm
3. c. Betrag des Grenzwinkels zwischen ersten und zweiten Bereichen E1, E2: 7°
4. d. Versatz zwischen dem Ende eines ersten Bereiche E1 und einer Kante eines darunter angenommenen Pixels 1 einer Bildwiedergabeeinheit: 5.0 µm
5. e. Differenz N2 zu N1: 0.140

Example 3:

1. a. Thickness of optical element 10: 60 µm
2. b. Width of the first areas E1 on the light entrance side: 15 µm
3. c. Amount of the critical angle between the first and second areas E1, E2: 7°
4. d. Offset between the end of a first area E1 and an edge of an assumed pixel 1 of an image display unit: 5.0 µm
5. e. Difference N2 to N1: 0.140

These parameters are selected as examples and may need to be adjusted to the size of the pixels or subpixels when using a specific image display unit.

Out of 8 It is evident that different optical elements 10 focus the light to different degrees. This is of great advantage if one wishes to increase the light output of screens, for example, because in certain applications a viewing angle greater than +/-40° is not sensible or necessary. Examples 1 to 3 according to 8 increase the central luminance by a factor of 4 to 7. The power consumption of a screen consisting of an image display device with an optical element 10 can be correspondingly lower, which also has a positive effect on the service life of the screen.

At this point, a particular advantage of the invention becomes apparent again: It allows the light emitted by a screen to be focused onto a desired viewing area with minimal loss. Thus, the invention can achieve a defined distribution of the luminance curve in one or two dimensions. If the luminance curve is rather broad, the content displayed by the image display unit can be viewed from a wide angle, while still allowing greater efficiency to be achieved compared to the prior art by varying the parameters of the optical element 10 to achieve the desired luminance curve.

• - eine Bildwiedergabeeinheit,
• - ein optisches Element 10 wie vorstehend beschrieben, wobei das optische Element 10 in Betrachtungsrichtung eines Betrachters vor oder hinter der Bildwiedergabeeinheit angeordnet ist, wobei bei Parallelprojektion aus senkrechter Richtung auf die Bildwiedergabeeinheit jeweils die zweiten Bereiche E2 vor nicht (oder im Wesentlichen nicht) Licht abstrahlenden Flächenabschnitten der Bildwiedergabeeinheit, also z.B. einer Blackmatrix 2, liegen.

Furthermore, the invention comprises a first screen comprising

• - an image display unit,
• - an optical element 10 as described above, wherein the optical element 10 is arranged in front of or behind the image display unit in the viewing direction of a viewer, wherein in the case of parallel projection from a perpendicular direction onto the image display unit, the second regions E2 are in front of surface sections of the image display unit which do not (or substantially do not) emit light, for example a black matrix 2.

Such a configuration is further ahead of the 3 and 4 It is also advantageous that the optical element 10 is arranged in front of or behind the image display unit in the viewing direction of a viewer in such a way that, in the case of parallel projection from a perpendicular direction onto the image display unit, the first regions E1 of the optical element 10 are in front of light-emitting surface sections 1, i.e. in particular pixels (color subpixels, full-color pixels, monochrome or other types of pixels) of the image display unit.

Non-light-emitting surface sections 2 of the image display unit can, for example, be the black matrix areas 2 of an OLED, microLED, or LCD panel or deactivated pixels (possibly including the respective black matrix areas of an OLED, LCD, or microLED panel). Other configurations are possible.

For the first screen, it may be advantageous if the optical element 10 is optically bonded or laminated to the image display unit.

• - eine Hintergrundbeleuchtung,
• - ein in Betrachtungsrichtung eines Betrachters vor der Hintergrundbeleuchtung angeordnetes optisches Element 10, wie vorstehend beschrieben, und vorzugsweise in der ersten, besonders bevorzugt in der dritten Alternative.

Auch hier erlaubt die Erfindung eine definierte Fokussierung des von der Beleuchtungseinrichtung abgesandten Lichtes auf einen gewünschte Betrachtungsbereich, d.h. auf eine definierte Leuchtdichtekurve, sinngemäß wie weiter oben zum ersten Bildschirm beschrieben.Furthermore, the invention also includes a lighting device comprising

• - a backlight,
• - an optical element 10 arranged in front of the background illumination in the viewing direction of a viewer, as described above, and preferably in the first, particularly preferably in the third alternative.

Here too, the invention allows a defined focusing of the light emitted by the illumination device onto a desired viewing area, ie onto a defined luminance curve, in the same way as described above for the first screen.

• - eine Beleuchtungseinrichtung wie vorstehend beschrieben, und
• - eine in Betrachtungsrichtung eines Betrachters vor der Beleuchtungseinrichtung angeordnete transmissive zweite Bildwiedergabeeinheit, wie etwa ein LCD-Panel.

Finally, the invention comprises a second screen comprising

• - a lighting device as described above, and
• - a transmissive second image display unit, such as an LCD panel, arranged in front of the illumination device in the viewing direction of a viewer.

In the latter case, an optical element 10 would typically be integrated directly into an illumination device for a transmissive image display unit, such as an LCD panel.

A first or second screen comprising at least one optical element as above described, and comprising an image display unit, can be used, for example, in a monitor or a mobile device. Furthermore, it is also possible to retrofit an image display unit with an optical element by placing it in front of the image display unit to increase its efficiency.

The invention described above solves the stated problem: Optical elements have been described that can influence incident light in a defined manner in its propagation directions, wherein at least a portion of the light incident on the light entry side of such an optical element is focused after passing through the optical element. Such optical elements can be implemented inexpensively and, in particular, can be universally used with various screen types to achieve increased efficiency in luminance distribution. Furthermore, they fundamentally offer the possibility of achieving a top-hat light distribution.

Claims (8)

A planar optical element (10) with a light entry side and a light exit side, comprising - first regions (E1) consisting of at least one transparent material with a first refractive index (N1) and second regions (E2) consisting of an opaque material and/or transparent and/or reflective or scattering material with a second refractive index (N2), wherein the first regions (E1) are embedded in the second regions (E2) in a one- or two-dimensional pattern, wherein the first refractive index (N1) is greater than the second refractive index (N2) across the entire wavelength range visible to the human eye, - wherein the first regions (E1) each have a larger cross-section on the light exit side than on the light entry side, and wherein, when viewed in parallel projection perpendicular to the optical element (10), the first regions (E1) each have different outline shapes on the light entry side and on the light exit side, which cannot be made congruent by scaling, - such that, at the light entrance side of the optical element (10), light incident thereon, which enters first regions (E1) of the optical element (10), is propagated there, depending on the geometric direction of incidence, polarization, and the ratio of the first refractive index (N1) to the second refractive index (N2), a) propagated unhindered within a first region (E1) or is totally reflected and is subsequently coupled out again at the light exit side of the corresponding first region (E1), or b) penetrates from the first region (E1) into an adjacent second region (E2) and, if it is not absorbed in the second region E2, propagates in a second region (E2) until it is coupled out of a second region (E2) on the light exit side or coupled into one or more next first and/or second regions (E1, E2), - and such that, in a first alternative, in which the second regions (E2) consist of a transparent material, light which at the light entry side of the optical element (10) is incident on second regions (E2) of the optical element (10), penetrates these regions, and is coupled out of the optical element (10) on the light exit side, - and such that, in a second alternative, in which the second regions (E2) at least partially comprise an opaque material, light incident on the light entry side of the optical element (10) on second regions (E2) of the optical element (10) is at least partially absorbed, - and such that, in a third alternative, in which the second regions (E2) at least partially comprise a reflective and/or scattering material, light incident on the light entry side of the optical element (10) on second regions (E2) of the optical element (10) is at least partially reflected and/or scattered, - whereby the light exiting the optical element (10) on the light exit side is less than the light incident on the optical element (10) is changed in its propagation directions, - and wherein furthermore at least a portion of the light incident on the light entry side of the optical element (10) into first regions (E1) is bundled after passing through the optical element (10). Optical element (10) according to Claim 1 , characterized in that the interfaces of the first regions (E1) and the second regions (E2) are trapezoidal, funnel-shaped, at least partially or completely parabolic, parallelogram-shaped, and/or step-shaped when viewed in the sectional direction perpendicular to the light exit side of the optical element (10). Optical element (10) according to one of the Claims 1 or 2 , characterized in that the first regions (E1) and the second regions (E2) are arranged in strip-like fashion and distributed alternately over the surface of the optical element (10) when viewed in parallel projection perpendicular to the optical element (10). Optical element (10) according to one of the Claims 1 or 2 , characterized in that the first areas (E1) each have a point-, circle-, oval-, rectangular-shaped area on the light incidence side or the light exit side when viewed in parallel projection perpendicular to the optical element (10). have a rectangular or hexagonal outline and are arranged distributed over the surface of the optical element (10) and the second regions (E2) are each shaped complementarily thereto. First screen, comprising - an image display unit, - an optical element (10) according to one of the Claims 1 until 4 , wherein the optical element (10) is preferably arranged in front of the image display unit in the viewing direction of a viewer in such a way that, in the case of parallel projection from a vertical direction onto the image display unit, the second regions (E2) are in front of non-light-emitting surface sections (2) of the image display unit. First screen, comprising - an image display unit, - an optical element (10) according to one of the Claims 1 until 4 , wherein the optical element is preferably arranged in front of or behind the image display unit in the viewing direction of a viewer in such a way that, in the case of parallel projection from a vertical direction onto the image display unit, the first regions (E1) of the optical element (10) are in front of the light-emitting surface sections (1) of the image display unit. Lighting device, comprising - a background light, - an optical element (10) according to one of the Claims 1 until 4 . Second screen, comprising - a lighting device according to Claim 7 , - a transmissive second image display unit arranged in front of the illumination device in the viewing direction of a viewer.