KR20200037429A - Multi-layer reflector for direct-illumination backlights - Google Patents

Abstract

Disclosed herein are light guide assemblies comprising a backlight unit, the backlight unit comprising a substrate comprising a second major surface opposite to the first major surface emitting light, optically coupled to the substrate (optically coupled) At least one light source, and a reflector positioned adjacent to the first or second major surface of the substrate, the reflector comprising two or more layers of reflective material, each of the layers having a first region and a first It has two regions, the first region is more reflective than the second region, and the second region is more transmissive than the first region, and includes a reflector.

Description

Multi-layer reflector for direct-illumination backlights

This application claims the benefit of the priority of U.S. Provisional Application No. 62 / 551,491 filed on August 29, 2017, the content of which is incorporated herein by reference in its entirety, as set forth below.

The present disclosure relates generally to backlight units and displays or lighting devices comprising such backlight units, and more particularly to backlight units comprising a patterned glass light guide plate and a patterned reflective layer.

Liquid crystal displays (LCDs) are commonly used in various electronic devices such as cell phones, laptops, electronic tablets, televisions, and computer monitors. LCDs may include a backlight unit (BLU) to generate light that is converted, filtered, and / or polarized to form the desired image. The BLUs include, for example, a light source coupled to the edge of a light guide plate (LGP) and can be edge-lit, for example a two-dimensional array of light sources disposed behind an LCD panel. And can be back-lit.

LCDs can be recognized as displays based on light valves, where the display panel includes a pair of polarizers and an array of individually addressable light valves using an electrically controlled liquid crystal layer. BLU is required to generate an image emitting from the LCD. Due to the high efficiency and small size of the latest light emitting diodes (LEDs), the latest BLUs use LEDs. BLUs are introduced in two variants. Edge-illuminated BLUs include an array of linear LEDs edge-coupled to a light guide plate (LGP) that emits light from its surface. Direct-lit BLUs contain a two-dimensional array of LEDs directly behind the LCD panel. Direct illumination BLUs may have the advantage of improved dynamic contrast compared to edge emitting BLUs. For example, displays with direct-illuminated BLU can independently adjust the brightness of each LED to optimize the dynamic range of brightness across the image. This is commonly known as local dimming. However, in order to obtain the required light uniformity and / or to prevent hot spots in the direct illumination BLUs, the light source (s) can be located at a distance from the LGP and / or diffuser film, and thus more than the edge illumination BLU. Forms a large overall display thickness. Lenses located on the LEDs have also been proposed to improve the lateral dispersion of light in direct-illuminated BLUs, but in these configurations the optical distance between the LED and the diffuser film, for example about 15 to 20 mm, is still These assemblies can create unwanted optical losses as they cause undesired high overall display thickness, and / or as the BLU thickness decreases. Edge illuminated BLUs can be thinner, but the light from each LED can be scattered across a large area of the LGP so that turning off individual LEDs or groups of LEDs has only minimal impact on the dynamic contrast ratio. . Direct-illuminated BLUs also have an advantage because they can enable enhanced dynamic contrast by employing 2D local dimming, where 2D local dimming, where the LEDs in the dark areas of the screen can be turned off.

Therefore, it would be advantageous to provide thin BLUs with improved local dimming efficiency without adversely affecting the uniformity of light emitted by the BLU.

Aspects described herein seek to address some of the problems described above.

In various embodiments, the present disclosure relates to a design for a multi-layer patterned reflector comprising two or more layers and a method of manufacturing the same, each of the layers having a first region and a second region, each of which has a first region It is designed to be more reflective than the second region, and the second region to be more transmissive than the first region.

The multi-layer patterned reflector can be optimized for use in thin, direct-lit LCD backlights, which is the light of abnormal LED sources within the backlight surface by multiple reflections between the patterned reflector and the uniform back reflector. It functions to disperse, thereby providing uniform luminance illumination for the LCD panel.

A method of manufacturing a multi-layer patterned reflector may include applying paint or ink to a suitable glass or plastic substrate by using reflective white paint or ink and successively printing multiple layers using digital printing technology. have. The patterned reflector can have several layers, each patterned with a relatively low resolution, which can be manufactured simply and inexpensively by printing a highly reflective ink. When these reflectors are used in a direct illumination backlight, this allows for a smaller thickness, better light efficiency and better brightness uniformity than conventional direct illumination backlights using variable reflectors.

In one embodiment where the patterned reflector is fabricated on the top surface of the light guide plate, the same printing process can also be used to form light extraction features.

Additional features and advantages of the embodiments of the present disclosure will be set forth in the detailed description that follows, in part, which is immediately apparent to those skilled in the art from the detailed description or appended drawings, as well as the detailed description, claims that follow. It will be appreciated by practicing the methods described herein, including.

Both the foregoing general description and the detailed description that follows describe embodiments of the present disclosure, which are intended to provide an overview or outline for understanding the properties and characteristics of the embodiments disclosed herein as they are described and claimed. Will be understood. The accompanying drawings are included to provide further understanding, and are incorporated and constituted within a part of the specification. The drawings illustrate various embodiments of the present disclosure, and together with the detailed description serve to explain the principles and operation of the various embodiments.

The detailed description that follows may be better understood when read in conjunction with the drawings below.
1 shows a light guide plate and an array of light sources optically coupled to the light guide plate.
2 shows an exemplary patterned reflective layer according to certain embodiments of the present disclosure.
3 and 4 show cross-sectional views of exemplary BLUs according to various embodiments of the present disclosure.
5A and 5B show lateral dispersion of light in light guide plates.
6A-6D are plots of light extraction efficiency of example BLUs with various patterned reflective layers.
7 shows an LGP patterned into microstructures according to additional embodiments of the present disclosure.
8A and 8B show some embodiments of a multilayer variable reflector according to some embodiments of the present disclosure.

Disclosed herein is a light guide plate having a first major surface that emits light, an opposite second major surface, and a plurality of light extraction features; At least one light source optically coupled to the second major surface; A rear reflector positioned adjacent to the second major surface of the light guide plate; And a patterned reflective layer positioned adjacent to the first major surface of the light guide plate and comprising at least one optically reflective component and at least one optically transmissive component. Display and lighting devices comprising such backlight units are also disclosed herein.

For example, televisions, computers, telephones, tablets, and other display panels, lighting fixtures, solid state lighting, such as elements, displays, lighting, and electronic devices, including such backlights. Billboards, and other building components, are also disclosed herein.

Various embodiments of the present disclosure will now be discussed with reference to FIGS. 1-8B, which show exemplary components and aspects of the backlight units disclosed herein. The following general description is intended to provide an overview of the claimed devices, and various aspects will be discussed in more detail throughout the present disclosure with reference to non-limiting illustrated embodiments, which are within the context of this disclosure. Interchangeable with each other.

1 shows a top view of an array of light sources 110 optically coupled to an exemplary light guide plate (LGP) 100 and LGP 100. For illustrative purposes, the light sources 110 can be seen through the LGP 100 of FIG. 1, but in some embodiments this may not be the case. Alternative configurations including other light source positions, sizes, shapes, and / or spacings are also intended to fall within the scope of the present disclosure. For example, although the illustrated embodiment includes a periodic and canonical array of light sources 110 having the same size, shape, and spacing, other embodiments are contemplated where the array is atypical or aperiodic.

The LGP 100 can have any dimensions, such as length (L) and width (W), which can vary depending on the display or lighting application. In some embodiments, the length L includes all ranges and subranges therebetween, such as about 0.1 m to about 5 m, about 0.5 m to about 2.5 m, or about 1 m to about 2 m. , About 0.01 m to about 10 m. Similarly, the width W is about 0.01, including all ranges and subranges therebetween, such as about 0.1 m to about 5 m, about 0.5 m to about 2.5 m, or about 1 m to about 2 m. m to about 10 m. Each light source 110 in the array of light sources can define a unit block (represented by dashed lines) having an associated unit length L ₀ and a unit width W ₀ , which are the dimensions of the LGP 100. And the number and / or spacing of the light sources 110 along the LGP 100. In non-limiting embodiments, the unit width W ₀ and / or unit length L ₀ is from about 1 mm to about 120 mm, from about 5 mm to about 100 mm, from about 10 mm to about 80 mm, about 20 It may be up to about 150 mm, including all ranges and subranges therebetween, such as in the range of mm to about 70 mm, about 30 mm to about 60 mm, or about 40 mm to about 50 mm. The length (L) and width (W) of the LGP may be substantially the same in some embodiments, or they may be different. Similarly, the unit length L ₀ and the unit width W ₀ may be substantially the same, or they may be different.

Of course, it should be understood that while the rectangular LGP 100 is shown in FIG. 1, the LGP can have any regular or atypical shape, such as suitable for generating the required light distribution for the selected application. The LGP 100 may include four edges, as shown in FIG. 1, or four or more edges, for example, a multi-sided polygon. In other embodiments, LGP 100 may include less than four edges, for example a triangle. As a non-limiting example method, the LGP may include a rectangle, square, or rhomboid with four edges, but other shapes and configurations with one or more curved portions or edges are within the scope of the present disclosure. It is intended to belong.

According to various embodiments, the LGP can include any transparent material used in the technology for lighting and display applications. As used herein, the term “transparent” is intended to indicate that the LGP has an optical transmittance greater than about 80% over a length of 500 mm within the visible region of the spectrum (˜420 to 750 nm). . For example, the exemplary transparent material includes all ranges and subranges therebetween, such as a transmittance of greater than about 90%, greater than about 95%, or greater than about 99% within a visible light range over a length of 500 mm. Thus, it may have a transmittance greater than about 85%. In certain embodiments, the exemplary transparent material is greater than about 55%, greater than about 60%, greater than about 65%, greater than about 70% within the ultraviolet (UV) range (~ 100 to 400 nm) over a length of 500 mm. All ranges and subranges therebetween, such as permeability greater than about 70%, greater than about 75%, greater than about 80%, greater than about 85%, greater than about 90%, greater than about 95%, or greater than about 99% Including, it may have an optical transmittance of greater than about 50%. According to various embodiments, the LGP can include at least 98% optical transmission over a path length of 75 mm for wavelengths ranging from about 450 nm to about 650 nm.

The optical properties of LGP can be influenced by the refractive index of the transparent material. According to various embodiments, the LGP is about, including all ranges and subranges therebetween, such as about 1.35 to about 1.7, about 1.4 to about 1.65, about 1.45 to about 1.6, or about 1.5 to about 1.55. It may have a refractive index ranging from 1.3 to about 1.8. In other embodiments, the LGP may have a relatively low level of light attenuation (eg, due to absorption and / or scattering). The light attenuation (α) of LGP may be less than about 5 dB / m for wavelengths in the range of about 420 to 750 nm, for example. For example, α is less than about 4 dB / m, less than about 3 dB / m, less than about 2 dB / m, less than about 1 dB / m, less than about 0.5 dB / m, less than about 0.2 dB / m, or the like. Or less, including all ranges and subranges therebetween, for example from about 0.2 dB / m to about 5 dB / m.

LGP 100 is a polymer material such as plastics, for example, polymethyl methacrylate (PMMA), methyl methacrylate styrene (methylmethacrylate styrene, MS), polydimethylsiloxane (polydimethylsiloxane, PMDS) or Other similar materials may be included. LGP 100 may also include glass materials such as aluminosilicates, alkali-aluminosilicates, borosilicates, alkali-borosilicates, aluminoborosilicates, alkali-aluminoborosilicates, soda limes or other suitable glasses. You can. Non-limiting examples of commercially available glasses suitable for use as a glass light guide include, for example, EAGLE XG®Lotus ^™ , Willow®Iris ^™ , and Gorilla® glasses from Corning.

Some non-limiting glass compositions include about 50 mole% to about 90 mole% SiO ₂ , about 0 mole% to about 20 mole% Al ₂ O ₃ , about 0 mole% to about 20 mole% B ₂ O ₃ , And about 0 mol% to about 25 mol% R _x O, wherein R is any one or more of Li, Na, K, Rb, Cs, and x is 2, or Zn, Mg, Ca , Sr or Ba and x is 1. In some embodiments, R _x O-Al ₂ O ₃ >0; 0 <R _x O-Al ₂ O ₃ <15; x = 2 and R ₂ O-Al ₂ O ₃ <15; R ₂ O-Al ₂ O ₃ <2; x = 2 and R ₂ O-Al ₂ O ₃ -MgO>-15; 0 <(R _x O-Al ₂ O ₃ ) <25, -11 <(R ₂ O-Al ₂ O ₃ ) <11, and -15 <(R ₂ O-Al ₂ O ₃ -MgO) <11; And / or -1 <(R ₂ O-Al ₂ O ₃ ) <2 and -6 <(R ₂ O-Al ₂ O ₃ -MgO) <1. In some embodiments, the glass contains less than 1 ppm each of Co, Ni, and Cr. In some embodiments, the concentration of Fe is <about 50 ppm, <about 20 ppm, or <about 10 ppm. In other embodiments, Fe + 30Cr + 35Ni <about 60 ppm, Fe + 30Cr + 35Ni <about 40 ppm, Fe + 30Cr + 35Ni <about 20 ppm, or Fe + 30Cr + 35Ni <about 10 ppm. In other embodiments, the glass is from about 60 mole percent to about 80 mole percent SiO ₂ , from about 0.1 mole percent to about 15 mole percent Al ₂ O ₃ , from 0 mole percent to about 12 mole percent B ₂ O ₃ , And about 0.1 mol% to about 15 mol% of R _x O, wherein R is at least one of Li, Na, K, Rb, Cs, x is 2, or Zn, Mg, Ca, Sr or Ba, and x is 1.

In other embodiments, the glass composition is from about 65.79 mol% to about 78.17 mol% SiO ₂ , from about 2.94 mol% to about 12.12 mol% Al ₂ O ₃ , from about 0 mol% to about 11.16 mol% B ₂ O ₃ , about 0 mole% to about 2.06 mole% Li ₂ O, about 3.52 mole% to about 13.25 mole% Na ₂ O, about 0 mole% to about 4.83 mole% K ₂ O, about 0 mole% to about 3.01 mol% ZnO, about 0 mol% to about 8.72 mol% MgO, about 0 mol% to about 4.24 mol% CaO, about 0 mol% to about 6.17 mol% SrO, about 0 mol% to about 4.3 mol % BaO, and about 0.07 mol% to about 0.11 mol% SnO ₂ .

In further embodiments, the glass may include an R _x O / Al ₂ O ₃ ratio of 0.95 to 3.23, where R is any one or more of Li, Na, K, Rb, Cs, and x is 2 to be. In further embodiments, the glass may include an R _x O / Al ₂ O ₃ ratio of 1.18 to 5.68, where R is any one or more of Li, Na, K, Rb, Cs, and x is 2 Or Zn, Mg, Ca, Sr or Ba, and x is 1. In still other embodiments, the glass may include R _x O-Al ₂ O ₃ -MgO at -4.25 to 4.0, where R is any one or more of Li, Na, K, Rb, Cs and x Is 2. In still other embodiments, the glass is from about 66 mole% to about 78 mole% SiO ₂ , from about 4 mole% to about 11 mole% Al ₂ O ₃ , from about 4 mole% to about 11 mole% B ₂ O ₃ , about 0 mol% to about 2 mol% Li ₂ O, about 4 mol% to about 12 mol% Na ₂ O, about 0 mol% to about 2 mol% K ₂ O, about 0 mol% to about 2 mol% ZnO, about 0 mol% to about 5 mol% MgO, about 0 mol% to about 2 mol% CaO, about 0 mol% to about 5 mol% SrO, about 0 mol% to about 2 mol % BaO, and about 0 mol% to about 2 mol% SnO ₂ .

In further embodiments, the glass is from about 72 mole percent to about 80 mole percent SiO ₂ , from about 3 mole percent to about 7 mole percent Al ₂ O ₃ , from about 0 mole percent to about 2 mole percent B ₂ O ₃ , About 0 mole% to about 2 mole% Li ₂ O, about 6 mole% to about 15 mole% Na ₂ O, about 0 mole% to about 2 mole% K ₂ O, about 0 mole% to about 2 Molar% ZnO, about 2 mol% to about 10 mol% MgO, about 0 mol% to about 2 mol% CaO, about 0 mol% to about 2 mol% SrO, about 0 mol% to about 2 mol% BaO, and about 0 mol% to about 2 mol% of SnO ₂ . In certain embodiments, the glass is from about 60 mol% to about 80 mol% SiO ₂ , from about 0 mol% to about 15 mol% Al ₂ O ₃ , from about 0 mol% to about 15 mol% B ₂ O ₃ , And about 2 mol% to about 50 mol% of R _x O, where R is any one or more of Li, Na, K, Rb, Cs, x is 2, or Zn, Mg , Ca, Sr or Ba, x is 1, Fe + 30Cr + 35Ni <about 60 ppm.

In some embodiments, LGP 100 has a color shift (Δy) of less than 0.015, such as in a range from about 0.005 to about 0.015 (e.g., about 0.005, 0.006, 0.007, 0.008, 0.009, 0.010, 0.011, 0.012, 0.013) , 0.014, or 0.015). In other embodiments, the LGP can include a color shift of less than 0.008. The color shift can be characterized by measured changes in x and y chromaticity coordinates along the length L using the CIE 1931 standard for color measurement. For LGPs, the color shift Δy can be reported as Δy = y (L2) -y (L1), where L ₂ and L ₁ are Z positions along the panel or substrate direction away from the source collision, L _2- L ₁ = 0.5 meters. Exemplary LGPs have Δy <0.01, Δy <0.005, Δy <0.003, or Δy <0.001. According to a particular embodiment, the LGP is less than about 3 dB / m, less than about dB / m, less than about 1 dB / m, less than about 0.5 dB / m, and about 0.2 dB / m for wavelengths from about 420 to 750 nm Light attenuation less than about 4 dB / m α ₁ (eg, absorption and / or scattering loss), less than or equal to, or less than, ranging from 0.2 dB / m to about 4 dB / m (Due to field).

The LGP 100 may include, for example, ion exchanged, chemically strengthened glass in some embodiments. During the ion exchange process, ions in the glass sheet or close to the surface of the glass sheet can be exchanged with larger metal ions, for example from a salt bath. The incorporation of larger ions into the glass can strengthen the sheet by creating compressive stress within the region close to the surface. The corresponding tensile stress can be introduced into the central region of the glass sheet to balance the compressive stress.

The ion exchange method can be carried out, for example, by immersing the glass in a bath of molten salt for a period of time. Exemplary salt baths include, but are not limited to, KNO ₃ , LiNO ₃ , NaNO ₃ , RbNO ₃ , and combinations thereof. The temperature and duration of treatment of the molten salt bath can vary. Determining the time and temperature according to the required application is within the skill of the skilled artisan. As a non-limiting example method, the temperature of the molten salt bath may range from about 400 ° C. to about 800 ° C., such as from about 400 ° C. to about 500 ° C., and certain periods of time, such as from about 4 hours to about 10 hours It may range from about 4 to about 24 hours, but other temperature and time combinations are envisioned. As a non-limiting example method, the glass can be immersed in a KNO ₃ bath, for example, at about 450 ° C. for about 6 hours to obtain a K-reinforced layer that imparts surface compressive stress.

2, which shows a top view of an exemplary patterned reflective layer 120, the reflective layer can have at least two regions with different optical properties. For example, the patterned reflective layer may have optical reflectivity components 120A (expressed in white dots), and / or reflective properties that may have higher optical reflectivity than optically transmissive components 120B (expressed in black dots). And transmissive components 120B that may have greater optical reflectivity than components 120A. Once again, for illustrative purposes, two exemplary light sources 110 can be seen through the patterned reflective layer 120 in FIG. 2, but this may not be the case in some embodiments.

In certain embodiments, the first region 125A may be disposed with more dense reflective components 120A within regions corresponding to the at least one light source 110 as shown in FIG. 2. The second region 125B may similarly be arranged in such a manner that the transmissive components 120B are more densely disposed in regions between the light sources 110, as illustrated in FIG. 2. On the assembly, a first region 125A of high reflectivity and / or low transmittance may be distributed at a higher density over each discrete light source 110 within the array of light sources, and the low reflectivity and / or high transmittance agent may be used. The two regions 125B may be distributed at higher densities within regions adjacent to or between the light sources.

The patterned reflective layer 120 may include any material capable of at least partially converting light output from the LGP 100. In some embodiments, the patterned reflective layer 120 can include a patterned metal film, a multi-layer dielectric film, or any combination thereof. In certain examples, the reflective and transmissive components 120A, 120B and / or the first and second regions 125A, 125B of the patterned reflective layer 120 may have different diffusion or specular reflectance. have. In other embodiments, the patterned reflective layer 120 can adjust the amount of light transmitted by the LGP 100. For example, the reflective and transmissive components 120A and 120B and / or the first and second regions 125A and 125B of the patterned reflective layer 120 may have different transmissivity.

According to various embodiments, the first reflectivity of the first region 125A may be about 50% or more, and the second reflectivity of the second region 125B may be about 20% or less. For example, the first reflectivity is at least about 50%, at least about 60%, at least about 70 &, at least about 80%, at least including all ranges and subranges therebetween, such as in the range of about 50% to 100%. About 90%, or at least about 92%. The second reflectivity can be about 20% or less, about 15% or less, about 10% or less, or about 5% or less, including all ranges and subranges therebetween, such as in the range of 0% to about 20%. In some embodiments, the first reflectivity can be at least about 2.5 times greater, including all ranges and subranges therebetween, such as about 2.5 to about 20 times greater than the second reflectivity, such as about It may be 3 times larger, about 4 times larger, about 5 times larger, about 10 times larger, about 15 times larger, or about 20 times larger, and at least about 2.5 times larger. The reflectivity of the patterned reflective layer 120 can be measured, for example, by a UV / Vis spectrometer available from Perkin Elmer.

In further non-limiting embodiments, the first transmittance of the first region 125A may be less than or equal to about 50%, and the second transmittance of the second region 125B may be greater than or equal to about 80%. For example, the first transmittance is about 50% or less, about 40% or less, about 30% or less, about 20% or less, including all ranges and subranges therebetween, such as in the range of about 0% to about 50%. , Or about 10% or less. The second transmittance may be 80% or more, about 85% or more, about 90% or more, or about 95% or more, including all ranges and subranges therebetween, such as about 80% to 100%. In some embodiments, the second transmittance is about 2 times greater, or about 3 times greater, including all ranges and subranges therebetween, such as from about 1.5 times to about 20 times the first transmittance. Or about 4 times larger, about 5 times larger, about 10 times larger, about 15 times larger, or about 20 times larger, and at least about 1.5 times larger. The transmittance of the patterned reflective layer 120 can be measured, for example, by UV / Vis available from Perkin Elmer.

Reflective and / or transmissive components 120A, 120B are positioned within reflective layer 120 to create any given pattern or design that can be random or arranged, repeatable or non-repetitive, uniform or non-uniform, for example. can do. As such, it should be understood that while FIG. 2 shows an exemplary repeating pattern of reflective and transmissive components 120A, 120B, other formal and irregular patterns can be used and are intended to fall within the scope of the present disclosure. . In some embodiments, these components are gradient, for example, from the first region 125A to the second region 125B, from the light sources to the regions between the light sources, or of each unit block. It is possible to form a gradient of reduced reflectivity from the center to the edges and / or corners of each unit block. In further embodiments, the reflective and transmissive components are from the first region 125A to the second region 125B, from the light sources to the regions between the light sources, or from the center of each unit block to each unit block. To the edges and / or corners, a gradient of increasing transmittance of the back can be formed.

Referring to FIG. 3 showing a cross-sectional view of an exemplary BLU, the LGP 100 may include a first main surface 100A emitting light and an opposite second main surface 100B. In certain embodiments, the major surfaces may be flat or substantially flat, and / or parallel or substantially parallel. In certain embodiments, LGP 100 may have a thickness t extending between the first and second major surfaces, for example from about 0.1 mm to about 2.5 mm, from about 0.3 mm to about 2 mm, from about 0.5 mm to about 1.5 mm, or from about 0.7 mm to about 1 mm, and can be less than about 3 mm, including all ranges and subranges therebetween.

The patterned reflective layer 120 may be positioned adjacent to the first major surface 100A of the LGP 100. As used herein, the term “contiguously positioned” and variations thereof refers to the fact that one component or layer is located close to a particular surface or a listed component, but is not necessarily in direct physical contact with such a surface or component. Is intended to. For example, in the non-limiting embodiment shown in FIG. 3, the patterned reflective layer 120 does not have direct physical contact with the first major surface 100A, for example, there is an air gap between these two components. do. However, in some embodiments, the patterned reflective layer 120 can be monolithically integrated with the LGP 100, such as disposed on the first major surface 100A of the LGP 100. As used herein, the term “placed on” and variations thereof are intended to indicate that one component or layer is in direct physical contact with a particular surface or listed component. In other embodiments, one or more layers and films, such as a contact layer, may be present between these two components. As such, component A located adjacent to the surface of component B may or may not be in direct physical contact with component B.

It should be understood that while FIG. 3 shows a single patterned reflective layer 120, the reflective layer 120 can include multiple pieces, films, or layers. For example, the patterned reflective layer 120 can be a multi-layer composite film or coating, such as a dielectric coating. In other embodiments, portions of the reflective layer corresponding to the first regions 125A may be applied to the LGP 100 first, and portions of the reflective layer corresponding to the second regions 125B may be subsequently applied to the LGP. Can, or vice versa. Alternatively, a first film or layer having first optical properties may be located on one or more portions of LGP 100, and a second film or layer having second optical properties covered by the first film It can be placed on top to cover substantially the entire portion of the LGP 100, including the parts. In this embodiment, the first region 125A of the multilayer reflective layer may have optical characteristics that are the sum of the first and second films, while the second region 125B may have optical characteristics of the second film alone. Or vice versa. Accordingly, the patterned reflective layer 120 can include a single film, or a composite film, a single layer or multiple layers, as appropriate to produce the desired optical effect.

Regardless of the patterned reflective layer configuration, the embodiments disclosed herein are compared to the second regions 125B (eg, lower reflectivity and / or higher transmittance) than the first regions 125A (eg, It should be understood that it may include a patterned reflective layer having at least one other optical property (within higher reflectivity and / or lower transmittance). A second where higher density reflective components 120A are present in the first region 125A located above the light sources 110 and a higher density transmissive components 120B are located between the light sources 110. The area density of the reflective and transmissive components 120A, 120B to be within the region 125B can vary across the reflective layer 120. Moreover, embodiments of the BLUs disclosed herein can produce substantially uniform light, for example, light emitted from regions corresponding to light sources is substantially the same as light emitted from regions between light sources. It may have luminance.

As shown in FIG. 3, at least one light source 110 may be optically coupled to the second major surface 100B of the LGP 100. Non-limiting exemplary light sources include light emitting diodes (LEDs), eg, blue, UV, or near ultraviolet, for example, LEDs that emit light having wavelengths ranging from about 100 nm to about 500 nm. You can. As used herein, the term “optically coupled” is intended to indicate that the light source is located on the surface of the LGP, to introduce light into the LGP that propagates at least partially due to total internal reflection. The light sources 110 may be in direct physical contact with the LGP 100 as shown in FIG. 3. However, the light source can also be optically coupled to the LGP even if it is not in direct physical contact with the LGP. For example, as shown in FIG. 4, an optical adhesive layer 150 can be used to attach the light sources 110 to the second major surface 100B of the LGP 100. In certain embodiments, the optical adhesive layer has a refractive index that is, for example, within 10% of the refractive index of LGP, or within 5%, within 3%, within 2%, within 1%, or the same refractive index as LGP, and LGP The refractive index can be matched to (100).

Referring back to FIG. 3, the BLU may further include a rear reflector 130 positioned adjacent to the second major surface 100B of the LGP 100. Therefore, the optical distance OD for light moving between the two reflectors may be defined as the distance between the patterned reflective layer 120 and the rear reflector 130. Exemplary back reflectors 130 may include metallic foils, such as, for example, silver, platinum, gold, copper, and the like. As further illustrated in FIG. 4, the backlight unit may include one or more additional films and components, such as one or more supplemental optical films and / or structural components. Exemplary supplemental optical films 170 are, in the name of diffusion films, prism films, for example, brightness enhancing films (BEF) or reflective polarizing films, for example dual brightness enhancing films, DBEF), but is not limited thereto. In some embodiments, light sources 110 and / or back reflector 130 may be disposed on printed circuit board 140. Supplemental optical components such as a diffusion film 160, a color conversion layer 170 (eg, including quantum dots and / or phosphors), a prism film 180, and / or a reflective polarizing film 190 ( S) may be positioned between the patterned reflective layer 120 and the display panel 200. Although not shown in FIG. 4, the BLUs disclosed herein are thin film transistor (TFT) arrays, liquid crystal (LC) layers, and other components commonly present in display and lighting devices, such as color filters, to name some exemplary components. Or combinations of these.

Referring back to FIG. 3, the light rays emitted from the light source 110 are illustrated by broken lines, dashed lines, and solid arrows. For illustrative purposes only, the transmissive components 120B are shown as points along the light guide plate with varying dimensions, represented by their density, for example light sources 110 at low density above the light sources 110. It has an increased density as it moves away from it. The density of the reflective and / or transmissive components 120A, 120B can be increased or decreased by increasing the number and / or size of the components. Moreover, the reflective and / or transmissive components 120A, 120B can be circular, elliptical, square, rectangular, triangular, or any other regular or irregular, including shapes with straight and / or curved edges. It can include any shape or combination of shapes, including red polygons.

The first light beam (dashed arrow) injected into the LGP 100 does not propagate in the lateral direction within the LGP 100, can move directly through the LGP, is not reflected back through the LGP, and is not reflected again through the patterned reflective layer 120. Passing through the second region 120B, the first transmitted light T ₁ is caused. The second light beam (dashed arrow) injected into the LGP 100 may move directly through the LGP without propagating laterally into the LGP 100, but may collide with the reflective component 120A in the patterned reflective layer 120. It is possible to move back through the LGP 100 to the rear reflector 130. The second light beam may thus traverse one or more optical distances OD during reflection between the patterned reflective layer 120 and the back reflector 130. As a result, the second light beam will pass through the transmissive component 120B of the patterned reflective layer 120, causing the _second light beam T ₂ .

50] The third ray (solid arrow) can be injected into the LGP 100 and total internal reflection until they collide with the light extraction feature or collide with the surface of the LGP at an incident angle less than the critical angle and are transmitted through the LGP. It can propagate within LGP due to (TIR). Therefore, the optical distance moved by the third light beam can be reduced to the thickness t of the LGP 100. While the third light ray may experience some optical losses during TIR due to absorption by the LGP 100, these optical losses shift the optical distance (OD) because they travel shorter vertical and / or horizontal distances Can be relatively small compared to the optical losses of the second ray. In particular, the rays tend to travel only about half of the distance (pitch) between the light sources before being extracted out of the LGP 100. In certain embodiments, the light source pitch may correspond to a unit width W ₀ (not shown) or unit length (not shown), which is about 150 mm or less, or about 80, as discussed with reference to FIG. 1. It can even be less than or equal to mm. Eventually, the third light beam will also pass through the patterned reflective layer's transmissive component 120B, causing the _third light beam T ₃ .

Total internal reflection (TIR) is a second material comprising a second index of refraction where light propagating within a first material (eg, glass, plastic, etc.) comprising the first index of refraction is lower than the first index of refraction (eg For example, it is a phenomenon that can be completely reflected at the interface with air. TIR can be described using Snell's law.

This accounts for the refraction of light at the interface between two materials with different refractive indices. According to Snell's law, n ₁ is the refractive index of the first material, n ₂ is the refractive index of the second material, θ _i is the angle (incident angle) of light incident at the interface to the normal of the interface, θ _r is the normal The angle of refraction of the reflected angle. When the refractive angle θ _r is 90 ^o , for example, sin (θ _r ) = 1, the Snell's law can be expressed as follows.

The angle of inclination θ _i under these conditions can also be referred to as the critical angle θ _c . Light having an angle of incidence greater than the critical angle (θ _i > θ _c ) will be totally internally reflected in the first material, wherein light having an angle of incidence equal to or less than the critical angle (θ _i > θ _c ) is the first Will be permeated by the material.

In the case of an exemplary interface between air ( n ₁ = 1) and glass ( n ₂ = 1.5), the critical angle θ _c can be calculated as 41 ^o . Thus, if the light propagating in the glass collides with the air-glass interface at an angle of incidence greater than 41 ^° , all of the incident light will be reflected from the interface at an angle equal to the angle of incidence. If the reflected light encounters a second interface having the same refractive index relationship as the first interface, the light incident on the second interface will be reflected back at the same reflection angle as the incident angle.

According to various embodiments, the first and / or second major surfaces 100A, 100B of the LGP 1000 are patterned to have a plurality of light extraction features. As used herein, the term “patterned” is any given pattern or design that can be repetitive or non-repetitive, uniform or non-uniform, on or under the surface of the LGP, for example random or arranged. As, it is intended to indicate that there are multiple light extraction features. In other embodiments, light extraction features may be located in a matrix of the LGP adjacent the surface, for example below the surface. For example, light extraction features can be distributed across the surface, for example as textured features that form a roughened or raised surface, or within or across LGP and parts thereof, for example For example, it can be distributed as laser-damaged sites or features. These methods for creating these light extraction features include inkjet printing, screen printing, microprinting, and printing, texturing, mechanical roughening, etching, injection molding, coating, laser damage, or any of these. It may include a combination of. Non-limiting examples of these methods can include, for example, a method of laser damage to a substrate by acidic etching of the surface, coating the surface with TiO ₂ , and focusing the laser in or on the substrate matrix.

LGP can be processed to generate light extraction features according to any methods known in the art, for example, the methods are co-pending and co-owned international patent applications PCT / US2013 / 063622 and PCT / US2014 / 070771, the full text of each of which is incorporated herein by reference. For example, the surface of the LGP can be polished and / or polished to achieve the required thickness and / or surface quality. The surface can then be selectively cleaned and / or a process for removing contaminants can be applied to the surface to be etched, such as exposing the surface to ozone. As a method of a non-limiting example, the surface to be etched is an acidic bath, for example glacial acetic acid (GAA) and ammonium fluoride (NH ₄ ) in a ratio ranging from about 1: 1 to about 9: 1. F). The etching time can range, for example, from about 30 seconds to about 15 minutes, and the etching can take place at room temperature or elevated temperature. Process variables such as acid concentration / ratio, temperature, and / or time can affect the size, shape, and distribution of the resulting extraction features. Differentiating these parameters to achieve the desired surface extraction features is within the skill of the artisan.

The light extraction feature pattern can be selected to improve the uniformity of light extraction along the length and width of the LGP 100, while regions of the LGP corresponding to individual light sources can emit light with higher intensity. And, for example, the overall light output of the LGP may not be uniform. Thus, the patterned reflective layer 120 can be engineered to have regions of varying optical properties to further homogenize the light output. For example, the patterned reflective layer 120 may have increased reflectivity and / or reduced transmittance in the first region 125A corresponding to the light sources, and increased transmittance in the second region 125B between the light sources, and / or Or it can provide reduced reflectivity. Such a configuration may allow for a closer placement of the diffusion film or other optical films to the light sources, thus resulting in a thinner overall BLU and resulting lighting or display device without adversely affecting the uniformity of light generated by the BLU or device. Can be allowed.

In traditional direct-illuminated BLU assemblies, as the optical distance between the back reflector and the patterned reflector becomes smaller, the number of light reflections increases, which results in increased optical losses. However, in the BLUs disclosed herein, the integration of the LGP optically coupled to the light sources follows the length of the LGP with reduced optical losses compared to a device that relies solely on reflectors for lateral dispersion of light. Lateral dispersion of light can be tolerated.

In the basic assembly in which light is only distributed laterally by the reflectors, for example in the assembly of FIG. 3 without LGP, the light with an incident angle (θ) undergoes one or more reflections between the two reflective layers, resulting in a vertical distance ( It is possible to move the lateral distance X over d). The number of reflections N can be expressed as N = X / d * tan (θ). Assuming both reflectors with 98% reflectivity, light after N reflections will have a residual power of 98% ^ N. Table 1 below shows the number of reflections and Table 2 shows the residual percentage of optical power for different combinations of angles of incidence θ and ratios X / d.

Table 1: Number of reflections

θ ( ^o ) ＼X / d 5 10 15 20 25 30 35 40 45 50 10 28 57 85 113 142 170 198 227 255 284 20 14 27 41 55 69 82 96 110 124 137 30 9 17 26 35 43 52 61 69 78 87 40 6 12 18 24 30 36 42 48 54 60 50 4 8 13 17 21 25 29 34 38 42 60 3 6 9 12 14 17 20 23 26 29 70 2 4 5 7 9 11 13 15 16 18 80 One 2 3 4 4 5 6 7 8 9

Table 2: Percentage of residual power

θ ( ^o ) ＼X / d 5 10 15 20 25 30 35 40 45 50 10 56% 32% 18% 10% 6% 3% 2% One% One% 0% 20 76% 57% 43% 33% 25% 19% 14% 11% 8% 6% 30 84% 70% 59% 50% 42% 35% 29% 25% 21% 17% 40 89% 79% 70% 62% 55% 49% 43% 38% 34% 30% 50 92% 84% 78% 71% 65% 60% 55% 51% 47% 43% 60 94% 89% 84% 79% 75% 70% 66% 63% 59% 56% 70 96% 93% 90% 86% 83% 80% 77% 75% 72% 69% 80 98% 97% 95% 93% 91% 90% 88% 87% 85% 84%

The light loss due to the multiple reflections between the reflectors becomes significantly important as the ratios X / d increase. As mentioned above, the pitch between the light sources can be as high as 150 mm. As the vertical distance decreases, the ratio (X / d) can increase rapidly, and in many cases will exceed 50. When X / d = 50, the residual power of light having an incident angle θ = 10 ^o is less than 1%.

Referring to Figure 5a, the light beam is emitted from the light source 110 at a divergence angle (θ _LED ), and passes into the LGP (100). Light rays are incident on the light emitting surface of the LGP at an angle of incidence (θ _LGP ) that does not exceed the critical angle θ _C , and therefore do not cause TIR in the LGP 100. A portion of the light travels the lateral distance (X ₁ ,), which is expressed as X ₁ = t * tan (sin ^-1 (sin (θ) / n)), where n is the refractive index of LGP and t is LGP It has a thickness of (100) and is transmitted as the first transmission (T ₁ ). The smaller portion of the light travels the second lateral distance X ₂ , which is expressed as X ₂ = 3X ₁ and is transmitted as the second transmission T ₂ . Table 3 below assumes that the refractive index (n) of the LGP is 1.5, the first reflection (R ₁ ) and the second reflection (R ₂ ) for different divergence angles (θ _LED ) = 20 ^o , 41 ^o and 60 ^o ), Percent of the luminous flux relative to the first transmission (T ₁ ), and the second transmission (T ₂ ). Since the total luminous flux is less than 1%, higher order reflections R ₃ and transmissions T ₃ (see FIG. 5B) are negligible. Most of the light independent of the divergence angle moves only the lateral distance (X ₁ ), is transmitted as T ₁ , and less than 1% of the light is transmitted as T ₂ . Even the light transmitted as T ₂ moves only the maximum lateral distance X ₂ = 3X ₁ in the illustrated configuration.

Table 3: Luminous flux percentage

θ _LED ( ^o ) θ _LGP  ( ^o ) R _One T _One R ₂ T ₂ R ₃ T ₃ 20 13.2 4.0% 92.1% 3.7% <1% <1% <1% 41 25.9 4.7% 90.9% 4.2% <1% <1% <1% 60 35.3 8.9% 83.0% 7.4% <1% <1% <1%

Referring to FIG. 5B, light rays are emitted from the light source 110 optically coupled to the LGP 100 such that the divergence angle θ _LED is substantially equal to the incident angle θ _LGP . For example, optical coupling with a refractive index-matched optical adhesive allows at least a portion of the light to move laterally along the length of the LGP due to the TIR. Part of the light travels the lateral distance (X ₁ ,), which is expressed as X ₁ = t * tan (θ), where t is the thickness of the LGP 100 and as the first transmission (T ₁ ) Permeate. A portion of the light travels the second lateral distance (X ₂ ), which is expressed as X ₂ = 3X ₁ due to the reflection between them, and is transmitted as the second transmission (T ₂ ). Once the angle of incidence exceeds the critical angle, for example, about 42 in the illustrated configuration ^If greater than ^o , the ray may experience TIR, which allows it to travel significantly larger lateral distances in the LGP before light is extracted outward. Thereby, the third part of the light can move the lateral distance X ₃ due to the TIR, and can be transmitted as the third transmission T ₃ .

Table 4 below assumes that the refractive index (n) of the LGP is 1.5, the first reflection (R ₁ ), the second reflection (R ₂ ), the _second for different divergence angles (θ _LED ) = 20 ^o , and 41 ^o The percentages of the luminous flux for the first transmission (T ₁ ), the second transmission (T ₂ ), and the third transmission (T ₃ ) are listed. In both Tables 3 and 4, most of the light is transmitted as T ₁ for the divergence angle (θ _LED ) = 20 ^o . However, in Table 3 (without optical coupling), X ₁ = 0.23 t, and in Table 4 (with optical coupling) X ₂ = 0.36 t, which means that light with the same divergence angle (20 ^o ) is optically transmitted to the light source. Indicates that the longer lateral distance is moved within the coupled LGP. For the divergence angle (θ _LED ) = 41 ^o , it is optically coupled compared to the light-uncoupled LGP (Table 3) as implied by the higher T ₂ and T ₃ values in Table 4. In the LGP (Table 4), travel a much longer lateral distance.

Table 4: Luminous flux percentage

θ _LED  ( ^o ) θ _LGP  ( ^o ) R _One T _One R ₂ T ₂ R ₃ T ₃ 20 20 0% 95.8% 4.0% <1% <1% <1% 41 41 0% 62.0% 23.6% 8.9% 3.4% 1.3%

6A-6D, the effect of TIR on lateral light dispersion is further enhanced by comparing backlight assemblies comprising a back reflector, a patterned reflector, at least one LED, and an LGP located between the reflectors. Can be demonstrated. Four cases were studied,

a) the bottom reflector has a Lambertian reflectivity of 98% and an absorption rate of 2%;

b) The LED has a Lambertian reflectivity of 60% and an absorbance of 40%;

c) LGP comprises glass optically coupled to the LED and having a refractive index of 1.5 and a thickness varying from 0.1 mm to 5 mm;

d) The patterned reflector has one of four different characteristics:

e) Case 1: 98% specular reflectance and 2% absorbance (FIG. 6A);

f) Case 2: Specular reflectance of 92% and absorbance of 8% (FIG. 6B);

g) Case 3: Lambertian reflectivity of 98% and absorbance of 2% (FIG. 6C); or

h) Case 4: Lambertian reflectivity of 92% and absorbance of 8% (Figure 6d).

i) The above assemblies comprising LGPs were compared to the same assemblies without LGPs and instead comprising an air gap with a distance corresponding to the thickness of the LGP.

Referring to FIGS. 6A-6D plotting light extraction efficiency as a function of LGP / air gap thickness, the light extraction efficiency of assemblies comprising an air gap in all four cases decreases as thickness t decreases. . In contrast, the light extraction efficiency of assemblies comprising LGP increases as the thickness t decreases from 5 mm to 0.7 mm. In all cases, the light extraction efficiency of assemblies comprising LGP is significantly higher than the light extraction efficiency of assemblies with air gaps for a thickness of about 2 mm or less. As consumer demand for thinner display devices increases, modifications to reduce the overall thickness of the BLU are likewise desired. By locating the optically coupled LGP between the patterned reflective layer and the back reflector, the optical losses that can occur as the distance between the reflectors decreases can be alleviated and the overall thickness of the BLU can be effectively reduced. have.

In other embodiments, such as the configuration shown in FIG. 7, it may be desired to include one or more microstructures 105 on the first major surface 100A of the LGP 100. These microstructures 105 in some embodiments further promote lateral dispersion of light from the light source and / or reduce optical losses due to absorption by the light sources, eg, LEDs, It can function to redirect vertically incident light towards an off-axis angle. The light extraction efficiency in these embodiments is from about 1% to about 4%, or from about 2% to including all ranges and subranges therebetween, compared to configurations without microstructures on the LGP. Like about 3%, it can be improved by 5%.

In certain embodiments, the microstructures 105 may have a pyramid shape, which may be individual raised features (as shown) or linear grooves. Elevated microstructures can be made of the same or different material than LGP, for example glass and plastics. Elevated microstructures can be formed, for example, by molding or microprinting the microstructures on the first major surface 100A. In further embodiments, the microstructures can be imprinted or etched into the first major surface 100A. According to further embodiments, the basic angle (θ _M ) that the microstructures form with the first major surface 100A includes from about 25 ^o to about 35 ^o , or about 30 including all ranges and subranges therebetween. ^It may be in the range of about 20 ^o to about 40 ^o , such as ^o .

8A and 8B show some embodiments of a multiple variable reflector according to some embodiments of the present disclosure. Referring to FIG. 8A, one non-limiting embodiment is shown having an LED size of approximately 1 mm × 1 mm and an LGP thickness of approximately 1 mm. In this non-limiting embodiment, the pitch of the LEDs (center-to-center distance) is 100 mm, and the size of individual 2D dimming zones or areas in which one LED emits is 100 mm × 100 mm. As shown in FIG. 8A, rays having an angle of at least about 42 degrees relative to the surface normal (relative to the refractive index of 1.5 of the LGP), emitted by the LED located outside the escape cone, will be totally internally reflected. , Thereby captured by LGP. If there is no upper reflector, the rays in the cone will escape. Within this non-limiting embodiment, the intersection of the LGP top surface and the escape cone is approximately 3 mm x 3 mm, or 1000 times smaller than the size of the dimming area. At the same time, about 45% of the total divergent flux for an emitter with Lambertian angular light distribution is in the escape cone. Therefore, if the reflector as shown in Fig. 8A accurately covers the escape cone, in order to achieve uniform illumination over the LGP, approximately 0.1% to 0.2% of the light impinging on it (the exact value of the reflectivity) And other design parameters that determine backlight efficiency). Thus, for a 3 mm × 3 mm square, if a single pattern feature or “hole” is formed in the reflector, this feature will be about 95 μm × 95 μm to about 134 μm × 134 μm in size. Having only one feature will inevitably create a lighter area (hot spot) on top of the feature and a dimmer (cold spot) surrounding the feature. In practice, it may be necessary to form a plurality of pattern features of correspondingly smaller size in some embodiments to improve luminance uniformity on a 3 mm × 3 mm region. These small features will generally require some form of photolithography process to manufacture. If the variable reflector is formed using highly reflective paint or ink, it may also be necessary to build up a thickness of 100 μm or more before high reflectivity is achieved.

Referring to FIG. 8B, another non-limiting embodiment with a reflector comprising two or more layers is shown. In some embodiments, the exemplary reflective paint can transmit about 95% of the incident light, and if the first layer of the reflector only sends 5% of the light outward, the second layer is 2% to 4% of the incident light % Should be permeable. In embodiments where the second layer is completely opaque, this will correspond to a pattern feature size in the second layer that is about 0.42 mm × 0.42 mm to about 0.6 mm × 0.6 mm. This feature size is easier to manufacture and easier to achieve a more uniform brightness than the embodiment described in FIG. 8A.

8A and 8B thus show that two features may vary within exemplary embodiments, and to maintain a ratio of feature size to layer thickness within an easily accessible range for printing, one pattern feature Size (eg, "holes" or "islands"), and the other is transmittance / reflectivity for each of the reflective layers. Depending on the type of possible reflective ink or paint, such as inkjet printing, screen printing, flexographic printing, or the like, any suitable digital printing technique can be used. In some embodiments, the advantage of using white paint or ink as a reflector material in a thin backlight design is that the paints generally have diffuse reflectivity rather than specular reflectance, which causes too much reflected light back to the LED source. It helps to prevent coming, and further improves the backlight efficiency.

If used within the thin backlight designs disclosed herein, the exemplary variable reflector is not only on the top surface of the LGP, but also on any suitable surfaces on the LGP, for example an optical diffuser plate, diffuser sheet, or brightness enhancement film It can be printed on the bottom surface of (BEF). If an exemplary variable reflector is printed on the LGP, the additional advantage provided to the corresponding display is that the light extraction features are the same as the first layer of the variable reflector, since white paint is well known in the art as an efficient light extractor. It can be printed on pass.

In some embodiments, if an exemplary variable reflector is printed on the bottom surface of a BEF, diffuser, or other component of a backlight other than an LGP, the presence of LGP may not be necessary, but still ease of manufacture and higher luminance uniformity This can provide an advantage.

To illustrate some embodiments, a number of samples were prepared by printing a commercially available white ink LH-100 on glass with different thickness (d) using a Mimaki UJF7151 plus printer. One sample had d = 0, ie there was no white ink; The second sample has d = d0 = 0.25 μm; Another sample had ink thicknesses of 0-6xd0. The cosine corrected bi-directional transmission distribution function (ccBTDF) is vertically incident at a wavelength of 550 nm with an Imaging Sphere for Scatter and Appearance (IS-SA) (available from Radiant Imaging, Inc.). Were measured on each sample using a light source (it was determined that ccBTDF (0) at 0 degrees is an excellent metric for transmitted intensity). The cosine corrected bi-directional reflection distribution function (ccBRDF) was also measured using the same device. CcBRDF (0) could not be obtained because the reflected beam and the incident beam spatially overlap when having vertical incidence, but total integrated scattering (TIS_R) from ccBRDF quantifies the reflected light. It was decided to be an excellent metric system.

Table 5 below provides TIS_R and ccBTDF (0) at 0 degrees relative to the relative ink thickness (d / d0) at a wavelength of 550 nm.

d / d0 TIS_R ccBTDF (0) 6 92.9% NA 4 92.1% NA 2 88.5% NA One 82.8% 0.0493 0.25 52.6% 6.233 0.111 34.7% 18.93 0.063 21.1% 52.25 0 4.1% 124

Referring to Table 5, it can be observed that the transmitted light intensity of vertical incidence quantified by ccBTDF (0) can be varied by more than 3 orders of magnitude by controlling the thickness of the white ink. It should be noted that when the ink thickness is 2 x d0 or thicker, the transmitted light intensity may be too low to be accurately measured. The total cumulative scattering of the reflected light can vary from about 21% to about 93%. Thus, these experimental results show exemplary variable reflectors with different reflections and transmissions and spatially varying thicknesses of white ink.

The BLUs disclosed herein can be used in a variety of display devices including, but not limited to, televisions, computers, telephones, small devices, billboards, or other display screens. The BLUs disclosed herein can also be used in various lighting devices, such as luminaires or solid state lighting devices.

Some embodiments include a substrate comprising a second major surface opposite the first major surface emitting light, at least one light source optically coupled to the substrate, and a first or second major surface of the substrate. As an adjacently positioned reflector, the reflector comprises two or more layers of reflective material, each of the layers having a first region and a second region, wherein the first region is more reflective than the second region, and the The second region provides a backlight unit that includes a reflective portion that is more transparent than the first region. In some embodiments, the substrate includes glass. The glass comprises 50 to 90 mole% SiO ₂ , 0 to 20 mole% Al ₂ O ₃ , 0 to 20 mole% B ₂ O ₃ , and 0 to 25 mole% R _x O (x is 2 , R is selected from Li, Na, K, Rb, Cs, and combinations thereof, or x is 1, and R is selected from Zn, Mg, Ca, Sr, Ba, and combinations thereof) It can be included based on the mole percentage of. In some embodiments, the substrate includes a color shift (Δy) of less than about 0.015. In other embodiments, the substrate includes a thickness ranging from about 0.1 mm to about 2 mm. In some embodiments, the reflective material is a white ink, and the total integrated scattering of reflections from the white ink varies between 4% and 93%. In some embodiments, the substrate is a volume diffuser plate, surface diffuser sheet, light guide plate, brightness enhancement film, or reflective polarizer. In some embodiments, the at least one light source is optically coupled to the second major surface of the light guide plate through an optical adhesive layer.

Additional embodiments include a substrate comprising a second major surface opposite to the first major surface emitting light, a plurality of discrete light sources, a reflector positioned adjacent to the second major surface, the first A multi-layer patterned reflector positioned adjacent to a primary surface, each layer having a first region and a second region, the first region being more reflective than the second region, and the second region being the A backlight unit including a multi-layer patterned reflector that is more transparent than the first region is provided. In some embodiments, the discrete light sources are located below and above the multi-layer patterned reflector, due to multiple reflections at reflective surfaces of the bottom and patterned reflector, the light source The light emitted by the field moves laterally between the bottom reflector and the patterned reflector. In some embodiments, the substrate includes glass. The glass comprises 50 to 90 mole% SiO ₂ , 0 to 20 mole% Al ₂ O ₃ , 0 to 20 mole% B ₂ O ₃ , and 0 to 25 mole% R _x O (x is 2 , R is selected from Li, Na, K, Rb, Cs, and combinations thereof, or x is 1, and R is selected from Zn, Mg, Ca, Sr, Ba, and combinations thereof) It can be included based on the mole percentage of. In some embodiments, the substrate includes a color shift (Δy) of less than about 0.015. In other embodiments, the substrate includes a thickness ranging from about 0.1 mm to about 2 mm. In some embodiments, the substrate is a volume diffuser plate, surface diffuser sheet, light guide plate, brightness enhancing film, or reflective polarizer. In some embodiments, the at least one light source is optically coupled to the second major surface of the light guide plate through an optical adhesive layer.

Additional embodiments include a substrate that includes a first major surface that emits light, a second major surface that is opposite, and a plurality of patterned features on the first or second major surfaces, a plurality of discrete light sources, the first 2 Reflectors positioned adjacent to the main surface, multi-layer patterned reflectors positioned adjacent to the first major surface, each layer having a first region and a second region, the first region being the first Provided is a backlight unit including a multi-layer patterned reflector, which is more reflective than the two regions, and the second region is more transparent than the first region.

In some embodiments, the discrete light sources are located directly under the patterned substrate, the first portion of the light moves laterally within the patterned glass light guide due to total internal reflection and Extracted to the outside by a pattern of light extractors, the second portion of the light is between the bottom reflector and the patterned reflector due to multiple reflections on the reflective surfaces of the bottom reflector and the patterned reflector To move laterally, the light from the discrete light sources is optically coupled to the patterned glass light guide. In some embodiments, the substrate includes glass. The glass comprises 50 to 90 mole% SiO ₂ , 0 to 20 mole% Al ₂ O ₃ , 0 to 20 mole% B ₂ O ₃ , and 0 to 25 mole% R _x O (x is 2 , R is selected from Li, Na, K, Rb, Cs, and combinations thereof, or x is 1, and R is selected from Zn, Mg, Ca, Sr, Ba, and combinations thereof) It can be included based on the mole percentage of. In some embodiments, the substrate includes a color shift (Δy) of less than about 0.015. In other embodiments, the substrate includes a thickness ranging from about 0.1 mm to about 2 mm. In some embodiments, the substrate is a volume diffuser plate, surface diffuser sheet, light guide plate, brightness enhancing film, or reflective polarizer. In some embodiments, the at least one light source is optically coupled to the second major surface of the light guide plate through an optical adhesive layer. In some embodiments, the substrate is a patterned glass light guide plate having a pattern of light extractors on both the second and second major surfaces.

It will be understood that various disclosed embodiments may be associated with specific features, components, or steps described in connection with the specific embodiment. It should also be understood that, although described in connection with one particular embodiment, a particular feature, component, or step may be interchanged or combined with alternative embodiments within various unillustrated combinations or permutations.

It should also be understood that as used herein, the terms “above,” “one,” or “day” mean “at least one,” and vice versa, unless explicitly indicated to the contrary, not limited to “only one”. do. Thus, for example, reference to “light source” includes examples having two or more of these light sources, unless the context clearly indicates otherwise. Likewise, “plurality” or “array” is intended to denote “one or more”. As such, “plurality of light scattering features” includes two or more such features, such as three or more of these features, and “array of holes” means two or more such holes, such as three or more of these holes, and the like. Includes

Ranges can be expressed herein as from “about” one particular value, and / or to “about” another particular value. When such a range is expressed, embodiments may include from one particular value, and / or to another particular value. Similarly, it will be understood that when values are expressed as approximations by the use of a leading phrase of "about", a particular value forms another aspect. It will be further understood that each of the endpoints of these ranges is important in connection with the other endpoints, and independently of the other endpoints.

It is intended to note that the terms “substantial”, “substantially” and variations thereof, as used herein, are the same or approximately the same as a value or description being described. For example, a “substantially flat” surface is intended to point to a flat or approximately flat surface. Moreover, "substantially similar" is intended to indicate that the two values are the same or approximately the same. In some embodiments, “substantially similar” may refer to values that are within about 10% of each other, such as within about 5% of each other, or within about 2% of each other.

Various features, components, or transition phrases of certain embodiments may be disclosed using “comprising”, while transition phrases may be described using “consisting of” or “consisting essentially of” It should be understood that alternative embodiments can be deduced. Thus, inferred alternative embodiments for a device comprising A + B + C include embodiments in which the device consists of A + B + C and embodiments in which the device consists essentially of A + B + C. do.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present disclosure without departing from the spirit and scope of the present disclosure. Since combinations, sub-combinations and variations of the disclosed embodiments that incorporate the spirit and substance of the present disclosure may occur to those skilled in the art, the present disclosure includes all that fall within the scope of the appended claims and their equivalents. It should be interpreted as.

Claims (28)

A substrate including a second major surface opposite to the first major surface emitting light;
At least one light source optically coupled to the substrate; And
A reflector positioned adjacent to the first or second major surface of the substrate, wherein the reflector comprises two or more layers of reflective material, each of the layers having a first region and a second region, the A backlight unit comprising a reflector, wherein a first region is more reflective than the second region, and the second region is more transmissive than the first region. According to claim 1,
The substrate is a backlight unit, characterized in that it comprises a glass. According to claim 2,
The glass,
50 to 90 mol% of SiO ₂ ,
0 to 20 mol% of Al ₂ O ₃ ,
0 to 20 mol% of B ₂ O ₃ , and
0 to 25 mole% of R _x O (x is 2, R is selected from Li, Na, K, Rb, Cs, and combinations thereof, or x is 1, R is Zn, Mg, Ca, Sr , Ba, and combinations thereof),
It characterized in that it comprises a composition based on the mol% of the oxide backlight unit. According to claim 1,
The substrate is a backlight unit, characterized in that it comprises a color shift (color shift) (Δy) of less than about 0.015. According to claim 1,
The substrate is a backlight unit, characterized in that it comprises a thickness in the range of about 0.1 mm to about 2 mm. According to claim 1,
Wherein the reflective material is white ink, and the total integrated scattering of reflections from the white ink varies between 4% and 93%. According to claim 1,
The substrate is a volume diffuser plate (volume diffuser plate), a surface diffuser sheet, a light guide plate, a brightness enhancement film (brightness enhancement film), and a backlight unit characterized in that it is selected from the group consisting of a reflective polarizer. According to claim 1,
And the at least one light source is optically coupled to the second major surface of the light guide plate through an optical adhesive layer. A display or lighting device comprising the backlight unit of claim 1. A substrate including a second major surface opposite to the first major surface emitting light;
A plurality of discrete light sources;
A reflector positioned adjacent to the second major surface;
A multi-layer patterned reflector positioned adjacent to the first major surface, each layer having a first region and a second region, the first region being more reflective than the second region, and the second region A backlight unit including a multi-layer patterned reflector that is more transparent than the first region. The method of claim 10,
The discrete light sources are located below the multilayer patterned reflector and above the bottom reflector,
Due to multiple reflections at the reflective surfaces of the bottom reflector and the patterned reflector, the light emitted by the light sources moves laterally between the bottom reflector and the patterned reflector. Backlight unit characterized by. The method of claim 10,
The substrate is a backlight unit, characterized in that it comprises a glass. The method of claim 12,
The glass,
50 to 90 mol% of SiO ₂ ,
0 to 20 mol% of Al ₂ O ₃ ,
0 to 20 mol% of B ₂ O ₃ , and
0 to 25 mole% of R _x O (x is 2, R is selected from Li, Na, K, Rb, Cs, and combinations thereof, or x is 1, R is Zn, Mg, Ca, Sr , Ba, and combinations thereof),
It characterized in that it comprises a composition based on the mol% of the oxide backlight unit. The method of claim 10,
The substrate is a backlight unit, characterized in that it comprises a color shift (Δy) of less than about 0.015. The method of claim 10,
The substrate is a backlight unit, characterized in that it comprises a thickness in the range of about 0.1 mm to about 2 mm. The method of claim 10,
The substrate is a volume diffuser plate (volume diffuser plate), a surface diffuser sheet, a light guide plate, a brightness enhancement film (brightness enhancement film), and a backlight unit characterized in that it is selected from the group consisting of a reflective polarizer. The method of claim 10,
And the at least one light source is optically coupled to the second major surface of the light guide plate through an optical adhesive layer. A display or lighting device comprising the backlight unit of claim 10. A substrate comprising a first major surface that emits light, an opposite second major surface, and a plurality of patterned features on the first or second major surfaces;
A plurality of discrete light sources;
A reflector positioned adjacent to the second major surface;
A multi-layer patterned reflector positioned adjacent to the first major surface, each layer having a first region and a second region, the first region being more reflective than the second region, and the second region A backlight unit including a multi-layer patterned reflector that is more transparent than the first region. The method of claim 19,
The discrete light sources are located directly under the patterned substrate,
The first portion of the light moves laterally within the patterned glass light guide due to total internal reflection and is extracted outside by a pattern of light extracting portions, and the second portion of the light is The light from the discrete light sources is patterned to move laterally between the bottom reflector and the patterned reflector due to multiple reflections at the reflective surfaces of the bottom reflector and the patterned reflector. A backlight unit, characterized in that it is optically coupled to a glass light guide. The method of claim 19,
The substrate is a backlight unit, characterized in that it comprises a glass. The method of claim 21,
The glass,
50 to 90 mol% of SiO ₂ ,
0 to 20 mol% of Al ₂ O ₃ ,
0 to 20 mol% of B ₂ O ₃ , and
0 to 25 mole% of R _x O (x is 2, R is selected from Li, Na, K, Rb, Cs, and combinations thereof, or x is 1, R is Zn, Mg, Ca, Sr , Ba, and combinations thereof),
It characterized in that it comprises a composition based on the mol% of the oxide backlight unit. The method of claim 19,
The substrate is a backlight unit, characterized in that it comprises a color shift (Δy) of less than about 0.015. The method of claim 19,
The substrate is a backlight unit, characterized in that it comprises a thickness in the range of about 0.1 mm to about 2 mm. The method of claim 19,
The substrate is a backlight unit, characterized in that it is selected from the group consisting of a volume diffuser plate, a surface diffuser sheet, a light guide plate, a brightness enhancing film, and a reflective polarizer. The method of claim 19,
And the at least one light source is optically coupled to the second major surface of the light guide plate through an optical adhesive layer. A display or lighting device comprising the backlight unit of claim 19. The method of claim 19,
The substrate is a backlight unit, characterized in that a patterned glass light guide plate having a pattern of light extractors on both the first and second major surfaces.

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