CN215728917U - Mini LED diffusion sheet and backlight module - Google Patents

Abstract

The utility model discloses a Mini LED diffusion sheet backlight module, which comprises a substrate, a microstructure arranged on one side of the substrate and a filling structure arranged on the other side of the substrate, wherein the microstructure comprises a plurality of micro lens structures and/or a plurality of convex lens bodies, the filling structure comprises a plurality of structural units, the structural units comprise a plurality of filling figures distributed in an equal density line, in the same structural unit, the distribution density of the filling figures is gradually reduced from the center to the periphery of the structural unit, the filling figures are groove structures, and reflective materials are filled in the filling figures. The utility model provides a diffusion piece one side is equipped with the microlens structure, and the opposite side is filled there is the reflectivity material for the even light-emitting of lamp pearl panel has improved the utilization efficiency of light, strengthens the luminousness when guaranteeing haze, and adopts the stack photoetching technique, and the last microlens structure duty cycle of diffusion sheet can reach 100%.

Description

Mini LED diffusion sheet and backlight module

Technical Field

The utility model relates to the technical field of backlight display, in particular to a Mini LED diffusion sheet and a backlight module.

Background

The Mini LED array is used as a light source of the backlight module, and has wide application prospect in display industries such as televisions, computers, mobile phones, vehicles and the like. The Mini LED chip is usually about 100-500 um in size, is mainly applied to a direct type backlight display system, and has the advantages of smaller size, higher brightness, quicker response and local dimming compared with the traditional LED light source.

The divergence angle of the light emitted by a single Mini LED point light source is limited, so that the light-emitting surface has the energy of a central area and a surrounding area with large energy, and the distance between the chips is about 1mm-4mm, therefore, the array light formed by a plurality of LED chips can cause a periodic light and shade area to appear on the screen, the visual effect is poor, and the experience of a user is influenced. In the conventional technology, a diffusion film based on diffusion particles is usually covered above an emergent surface of a Mini LED to realize light diffusion and light mixing, so that the emergent surface is uniform in emergent light, but the light mixing distance corresponding to the mode is in the range of several millimeters to several centimeters, and the requirement of lightness and thinness of the future display industry is not met.

Although there are many types of light-uniformizing sheets on the market, the balance treatment of the haze and the light transmittance of the light-uniformizing sheet is not excellent enough, and it is not guaranteed that a good light transmittance can be ensured when a certain haze is reached. Especially, in order to achieve a certain haze during the manufacturing process of some thick light uniformizing sheets, a large amount of diffusion particles are often added in the preparation material, and the light transmittance of the light uniformizing sheets is affected by the absorption of the diffusion particles. And the luminousness is not high, then can need great backlight power, still can influence the life of lamp pearl when the energy consumption is big. In part prior art, the both sides structure of even slide is pyramid, prism or quadrature cylinder respectively, is processed out through diamond lathe, only needs two-layer diaphragm just can realize even light effect, and just needs to aim at, and the quadrature superposes, and is very inconvenient when the equipment backlight unit. In some prior arts, the concave-convex points are formed by coating glass beads on the substrate of the light homogenizing plate, and optical cement exists in the formation process, so that the light transmittance of the light homogenizing plate is affected. In addition, the composite film adopted in the prior art is obtained by gluing two uniform light films with prisms or glass bead structures on single surfaces, is large in thickness and is not suitable for ultrathin equipment.

The information disclosed in this section is only for background understanding of the inventive concept and provides a new technical solution in combination with the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a Mini LED diffusion sheet which ensures high haze and has high light transmittance. Meanwhile, the microstructure, such as arrangement of micro lenses, is designed, and a superposition photoetching technology is adopted, so that the positioning error of a laser head of a photoetching machine is overcome, and the high quality and the high yield of products are further ensured. Meanwhile, a backlight module using the Mini LED diffusion sheet is provided.

The diffusion sheet mentioned herein may also be referred to as a diffusion film when the thickness is thin, and for convenience of description, the diffusion sheet and the diffusion film are collectively referred to as a diffusion sheet.

In order to achieve the purpose of the present invention, according to one aspect of the present invention, the present invention provides a Mini LED diffusion sheet, which includes a substrate, a plurality of microstructures disposed on one side of the substrate, and a filling structure disposed on the other side of the substrate, wherein the microstructures include a plurality of micro lens structures and/or a plurality of convex lens bodies, the filling structure includes a plurality of structural units, the structural units include a plurality of filling patterns arranged along an isopycnic line, in the same structural unit, the arrangement density of the filling patterns gradually decreases from the center of the structural unit to the periphery, the filling patterns are groove structures, and the filling patterns are filled with reflective materials.

Furthermore, the micro lens structure comprises a concave structure and/or a convex structure, the micro lens structures are arranged in multiple rows, the micro lens structures in two adjacent rows are arranged in a staggered mode, or arranged randomly, or arranged orthogonally, the two adjacent micro lens structures are partially overlapped, the convex surface of the convex structure is a curved surface, and the concave surface of the concave structure is a curved surface.

Further, the size of the micro lens structure is 0.03mm-0.09mm, and the depth or height of the micro lens structure is 0.01mm-0.05 mm.

Further, the thickness of the substrate is 0.1mm-2.0mm, and the overlapping range of two adjacent micro-lens structures is 5% -25%.

Further, the convex lens body is in one or more of a prism shape, a pyramid shape, a semi-cylinder shape and a conical shape, or is in a composite shape formed by one or more of the shapes according to a set rule; the height of the convex lens body is 0.01mm-0.1mm, and when the convex lens body is conical, the included angle of the tip end of the convex lens body is 60-120 degrees.

Furthermore, the filling pattern is in a columnar counter-sunk shape, and the groove bottom of the filling pattern is in a circular arc shape; the reflective material is reflective ink, metal silver or metal aluminum, the size of the filling pattern is 0.005mm-0.1mm, and the depth of the filling pattern is 0.004mm-0.05 mm.

According to another aspect of the utility model, the utility model further provides a backlight module, which comprises the Mini LED diffusion sheet.

Further, it still includes lamp pearl panel, blue light membrane, quantum dot membrane, first brightness enhancement film, second brightness enhancement film and the diffusion barrier that sets gradually, the diffusion piece is located lamp pearl panel with between the blue light membrane, the diffusion piece is the one deck at least, one side orientation that the diffusion piece was filled with reflective material the lamp pearl panel, the constitutional unit on the diffusion piece with lamp pearl one-to-one on the lamp pearl panel.

The application has one or more of the following advantages:

(1) according to the Mini LED diffusion sheet, one side of the Mini LED diffusion sheet is provided with the microstructure, and the other side of the Mini LED diffusion sheet is provided with the filling structure filled with the reflective material, so that the diffusion sheet has high haze, and the diffusion effect of the diffusion sheet on a light emitting line of a Mini LED lamp bead can be effectively guaranteed;

(2) according to the Mini LED diffusion sheet, the microstructure is arranged on one side of the Mini LED diffusion sheet, particularly when the thick diffusion sheet is prepared, the addition amount of diffusion particles can be reduced, high haze can be guaranteed, high light transmittance can be achieved, the power requirement of the Mini LED can be reduced, power consumption and heat dissipation are reduced, the service life of the Mini LED is prolonged, and the Mini LED diffusion sheet is more environment-friendly;

(3) according to the Mini LED diffusion sheet, the microstructures are partially overlapped, so that the duty ratio of the microstructures on the diffusion sheet can reach 100%, and meanwhile, the positioning error of a laser head of a photoetching machine can be overcome;

(4) the utility model provides a Mini LED diffusion piece, its opposite side adopt the variable density to fill reflective material structural design, and the packing figure distribution density that is close to the lamp pearl is greater than the packing figure distribution density who keeps away from the lamp pearl, makes the diffusion piece is being close to the reflection efficiency of lamp pearl department is greater than keeps away from the reflection efficiency of lamp pearl department for the even light-emitting of lamp pearl panel, improved the utilization efficiency of light, reach the vivid effect of feeling of vision and the effect of higher dynamic range and contrast.

Drawings

Fig. 1 is a schematic perspective view of a diffusion sheet provided in an embodiment of the present application at an angle;

fig. 2 is a schematic perspective view of a diffuser at another angle according to an embodiment of the present disclosure;

FIGS. 3a-3c are schematic views of partial arrangements of microlens structures on a diffuser in accordance with an embodiment of the present application;

FIG. 4 is a schematic cross-sectional view of a diffuser in accordance with an embodiment of the present disclosure;

FIGS. 5a and 5b are diagrams illustrating an effect of a microlens structure arrangement of a diffuser sheet according to an embodiment of the present disclosure;

FIG. 6 is a schematic cross-sectional view of a diffuser in the presence of errors according to an embodiment of the present disclosure;

FIG. 7 is a diagram illustrating an arrangement effect of micro-lens structures of a diffusion sheet in the presence of errors according to an embodiment of the present disclosure;

FIG. 8 is a diagram illustrating another arrangement effect of a micro-lens structure of a diffuser in the presence of errors according to an embodiment of the present disclosure;

fig. 9 is a schematic layout view of a diffusion sheet filling pattern according to an embodiment of the present disclosure;

FIG. 10 is a schematic view illustrating filling of a reflective material in a filling pattern of a diffuser according to an embodiment of the present application;

fig. 11 is a schematic structural diagram illustrating a filling pattern filled with a reflective material according to an embodiment of the present disclosure;

fig. 12 is a schematic diagram of positions between a filling pattern and a bead according to an embodiment of the present application;

fig. 13 is a schematic structural diagram of an apparatus for preparing a diffusion sheet according to a first embodiment of the present disclosure;

FIG. 14 is a schematic structural diagram of another apparatus for preparing a diffuser according to an embodiment of the present disclosure;

fig. 15 is a schematic layer structure diagram of a backlight module according to an embodiment of the present application;

fig. 16 is a schematic diagram illustrating a position between a diffusion sheet and a bead in a backlight module according to an embodiment of the present application;

fig. 17 is a schematic view of a position between a diffusion sheet and a lamp bead in the backlight module according to the second embodiment of the present application;

fig. 18 is a schematic perspective view of a diffuser in accordance with a third embodiment of the present invention when the convex lens body is a triangular pyramid;

FIG. 19 is a schematic top view of the diffuser of FIG. 18;

FIG. 20 is a schematic side view of the diffuser of FIG. 18;

FIG. 21 is a cross-sectional view taken at location A of FIG. 19;

fig. 22 is a schematic perspective view of a diffuser in accordance with a third embodiment of the present invention when the convex lens bodies are quadrangular pyramid-shaped;

FIG. 23 is a schematic top view of the diffuser of FIG. 22;

FIG. 24 is a schematic side view of the diffuser of FIG. 22;

fig. 25 is a cross-sectional view taken at position B in fig. 23.

The light source module comprises a substrate, a substrate layer, a base layer, a light source and a light source, wherein the light source comprises 1-boss-shaped structures, 2-recess-shaped structures, 3-melt materials, 4-mold rollers, 5-substrate layers, 6-glue heads, 7-extrusion rollers, 8-mold rollers, 9-guide rollers, 10-ultraviolet lamps, 11-lamp bead panels, 111-lamp beads, 12-diffusion sheets, 121-bases, 122-micro lens structures, 1221-recess structures, 1222-projection structures, 123-filling patterns, 1231-reflective materials, 124-convex lens bodies, 13-blue light films, 14-quantum dot films, 15-first brightness films, 16-second brightness films, 17-diffusion films and 18-uniform light sheets.

Detailed Description

To further illustrate the technical means and effects of the present invention adopted to achieve the intended purpose of the utility model, the following detailed description is given to the specific embodiments, structures, features and effects of the present invention in conjunction with the accompanying drawings and preferred embodiments.

Example one

The embodiment provides a Mini LED diffusion sheet, which includes a substrate 121, a plurality of micro lens structures 122 disposed on one side of the substrate 121, and a filling structure disposed on the other side of the substrate 121, as shown in fig. 1 and 2, the micro lens structures 122 shown in the drawings are circular recessed structures 1221. The concave surface of the microlens structure 122 is preferably a curved surface. The plurality of microlens structures 122 are arranged in a plurality of rows, and the plurality of microlens structures 122 in two adjacent rows are arranged in a staggered manner, as shown in fig. 3a, or arranged randomly, as shown in fig. 3b, or arranged orthogonally, as shown in fig. 3 c. There is partial overlap between two adjacent microlens structures 122 as shown in fig. 3a-3c and fig. 4. The overlap between adjacent microlens structures 122 ranges from 5% to 25%, preferably 10%. A partial overlapping design is adopted between the adjacent micro-lens structures 122, so that on one hand, the coverage range of the micro-lens structures 122 on the diffusion sheet can be effectively improved, and the duty ratio can reach 100%, as shown in fig. 5a and 5 b; on the other hand, the positioning error of the laser head of the photoetching machine can be overcome. As for the lithography machines on the market at present, the positioning accuracy that can be achieved is about 4um-5um, when the lithography is performed on the lithography piece, the positioning error may cause a gap between the pattern structures formed by the lithography, so a convex-shaped structure 1 and a concave-shaped structure 2 are formed, as shown in fig. 6, when the structure is used for stamping or extruding a microlens structure 122 on the diffusion sheet, an area without the microlens structure 122 will exist on the diffusion sheet, as shown in fig. 7 and 8, and the diffusion effect of the diffusion sheet will be affected.

The diffusion effect of the diffusion sheet is related to the curvature radius and the size of the microlens structure 122, and preferably, the microlens structure 122 has a size of 0.03mm to 0.09mm, a depth of 0.01mm to 0.05mm, and a curvature radius of 0.06mm to 0.2 mm. It should be understood that the above range of the parameters related to the microlens structure 122 is only a preferred range of the present application, and the parameters related to the microlens structure 122 can be designed as required in the specific implementation.

The filling structure comprises a plurality of structural units, and each structural unit comprises a plurality of filling patterns 123 arranged in an equal density line. In the same structural unit, the arrangement density of the filling patterns 123 gradually decreases from the center of the structural unit to the periphery. As shown in fig. 9 to 12, the filling patterns 123 on the diffusion sheet are unevenly distributed, and there are regions where the distribution density of the filling patterns 123 is large and regions where the distribution density is small. In each structural unit, the distribution density of the filling patterns 123 close to the central position (i.e. close to the position of the lamp bead 111) is greater than that of the filling patterns 123 far away from the central position (i.e. far away from the position of the lamp bead 111). The filling pattern 123 is a groove structure, and the filling pattern 123 is filled with a reflective material 1231, as shown in fig. 10. Preferably, the filling pattern 123 is a columnar counter-sunk shape, and a groove bottom of the filling pattern 123 is a circular arc shape. The cross-sectional shape is circular, square or any other shape, preferably circular. The size of the groove structure is 0.005mm-0.1mm, and the depth of the groove structure is 0.004mm-0.05 mm. The filling pattern 123 designed by the columnar counter bore can ensure that the reflective material 1231 can be perfectly filled into the filling pattern 123 when the reflective material 1231 is knife-coated, thereby effectively avoiding the phenomena that the reflective material 1231 is not filled in or is taken out in the knife-coating process and the like.

The reflective material 1231 is one of reflective ink, metallic silver, and metallic aluminum, but is not limited thereto, and may be other reflective materials, or a mixture of a plurality of reflective materials. Preferably, a light reflecting ink is used. The effect of reflective material 1231 is to make light reflection, and the light that reflects through reflective material 1231 can be through lamp pearl panel 11 reflection again to the diffusion piece, make full use of light energy, can promote the degree of consistency of whole light simultaneously. Here, the reflective material 1231 formed by mixing the light reflecting ink with the metallic silver or the metallic aluminum is a conventional material. Since the reflective material 1231 is doped with a volatile substance such as water during the filling process, when the reflective material 1231 is cured, the reflective material 1231 in each of the filling patterns 123 is recessed inward at a position close to the middle, and has a recess of about 1-2um, so as to form a recessed surface outside the reflective material 1231, as shown in fig. 11. The concave surface can well change the propagation direction of the light emitting line of the lamp bead 111, and is beneficial to improving the diffusion effect of the micro-lens diffusion plate on the light emitting line of the lamp bead 111.

Through the variable density design, when high light intensity close to the lamp beads 111 passes through the filling patterns 123 with higher aggregation coefficients, the light transmission effect is poor, and the light diffusion effect is good; when the low light intensity far away from the lamp beads 111 passes through the filling pattern 123 with a low aggregation coefficient, the light transmission effect is good, and the light diffusion effect is poor, so that the reflection efficiency of the diffusion sheet close to the lamp beads 111 is higher than that far away from the lamp beads 111, and therefore uniform light emitting on the surface of the diffusion sheet is realized, and the effect of eliminating uneven brightness among the lamp beads 111 is achieved. It should be noted that, the region with the higher distribution density of each structural unit filling pattern 123 on the diffusion sheet corresponds to one lamp bead 111, and the region with the lower distribution density of the filling pattern 123 corresponds to the middle region between two lamp beads 111, as shown in fig. 12. That is, each of the beads 111 has a plurality of filling patterns 123 at positions on the diffusion sheet corresponding to the beads, and the distribution density of the filling patterns 123 decreases with increasing distance from the beads 111.

The diffusion sheet substrate 121 has a thickness of 0.1mm to 2.0mm, wherein the thicker the diffusion sheet substrate 121 is, the better the atomization effect of the diffusion sheet is, and the thinner the substrate 121 is, the higher the light transmittance of the diffusion sheet is. The diffusion sheet is provided with the micro-lens structures 122 and the filling structures on two sides of the substrate 121, so that the haze of the diffusion sheet can be guaranteed, and the light transmittance of the diffusion sheet can be improved. For example, when a thick diffusion sheet (thickness greater than 0.6mm) is manufactured, diffusion particles are added to a material for manufacturing the diffusion sheet in order to secure haze of the diffusion sheet, and the diffusion particles absorb light to affect light transmittance of the diffusion sheet. The microlens structure 122 of the application can reduce the addition amount of diffusion particles during production of the diffusion sheet, reduce the absorption degree of the diffusion particles to light, and greatly improve the light transmittance of the diffusion sheet while ensuring the haze of the diffusion sheet. Tests show that the haze of the diffusion sheet can reach 95%, the light transmittance can reach 85%, and the light transmittance is far greater than 50% -60% of the light transmittance of the existing diffusion sheet. The improvement of luminousness can reduce the demand to Mini LED power to reduce the consumption and dispel the heat, prolong the life of Mini LED lamp, and environmental protection more to a certain extent.

In this embodiment, a preparation process of the Mini LED diffusion sheet is further provided, which includes the following specific steps:

step S1: and photoetching a plurality of first pattern structures corresponding to the shapes of the micro-lens structures 122 on one side of the first photoetching member, wherein the adjacent first pattern structures are partially overlapped. And photoetching a plurality of second pattern structures corresponding to the shapes of the filling patterns 123 on one side of a second photoetching piece. The first and second photolithography parts may be glass substrates coated with photoresist on one side. And then, exposing the photoresist layer according to a required pattern, etching off the developed part, and forming a plurality of sunken pattern structures on the photoresist layer. The first photoetching part and the second photoetching part can also be made of mirror surface metal materials, the metal materials can be stainless steel, nickel, copper and the like, and the metal materials are directly focused on the surface of a metal base material through a shaping light path by a high-power pulse laser to carry out photoetching so as to form a required pattern structure.

Step S2: and transferring the obtained pattern structure on the photoetching object to a template by using a UV transfer printing technology or a metal growth technology to obtain the template with the pattern structure. In this embodiment, the first pattern structure recessed on the first lithography member is transferred to the surface of the template by UV transfer, so as to obtain the first template having a protruding pattern structure on the surface. And transferring the second pattern structure recessed on the second photoetching member to the surface of another template so as to obtain the second template with the raised pattern structure on the surface. Or by means of metal growth by electroforming, a first template having a patterned structure protruding from the surface and a second template having a patterned structure protruding from the surface are obtained. Of course, it can also be obtained by other means.

Step S3: and respectively wrapping the first template and the second template on two mold rollers 4, and impressing or extruding a material for forming the diffusion sheet to obtain a semi-finished diffusion sheet product with two side surfaces respectively provided with a micro-lens structure 122 and a filling structure.

Step S4: and filling a reflective material 1231 in the filling structure, and curing and forming to obtain a finished diffusion sheet.

Among them, in step S3, if a thicker diffusion sheet is to be prepared, it is preferable to integrally form the diffusion sheet by pressing, which needs to be completed by a pressing apparatus. The extrusion equipment comprises two die rollers 4 for extrusion, wherein the two die rollers 4 are arranged in parallel at intervals, and an extrusion flow channel is formed between the two die rollers. The first template and the second template are respectively wrapped outside the two mold rollers 4, and the graphic structures on the first template and the second template face outwards, as shown in fig. 13. The material for forming the diffusion sheet includes diffusion particles and a transparent organic polymer material. The organic polymer material is any one of PET, PC, and PMMA, but is not limited thereto and is not listed here. The diffusion particles may be PET diffusion particles, PC diffusion particles, PMMA diffusion particles, or the like, and the diffusion particles are white diffusion particles or yellow diffusion particles, and preferably white diffusion particles, but the diffusion particles are not limited thereto and may be diffusion particles of other colors. The preparation method comprises the following specific steps:

step S311: providing diffusion particles and a transparent high polymer material, mixing and melting the diffusion particles and the transparent high polymer material to a melt state;

step S312: adding the melted melt material 3 into an extrusion flow channel of the extrusion equipment for extrusion molding, and adjusting the distance between two mold rollers 4 to obtain a uniform diffusion sheet primary finished product with corresponding thickness;

step S313: and cooling and solidifying to obtain a semi-finished diffusion sheet product with the surface provided with the micro-lens structure 122 and the filling structure. In this step, the cooling method may be a natural cooling method or may be cooling by a cooling roller, but is not limited thereto and may be other cooling methods.

This embodiment also provides another method of making a thin diffuser. It should be noted that the diffusion sheet mentioned herein may also be referred to as a microlens diffusion film when the thickness is thin, and for convenience of description, the diffusion sheet and the diffusion film are collectively referred to as a diffusion sheet. The material for forming the diffusion sheet used in this method includes a base material layer 5 and a UV curable resin. The substrate layer 5 may be any one of PET, PC, and PMMA, but is not limited thereto and is not listed here. As shown in fig. 14, the specific preparation steps are as follows:

step S321: providing a substrate layer 5; the substrate layer 5 may be any one of PET, PC, and PMMA, but is not limited thereto and is not listed here; the base material may be a diffusion material in which diffusion particles are added.

Step S322: coating a UV curing resin on the surface of the base material layer, for example, coating the UV curing resin on the surface of the base material layer 5 through a glue head 6 as shown in FIG. 14, and then optionally pre-curing the UV curing resin by using an ultraviolet pre-curing device to form a semi-solid UV curing resin layer on the surface of the base material layer 5. The ultraviolet pre-curing device is, for example, a low-power ultraviolet lamp, and can change the originally liquid UV curing resin into a semisolid state so as to be convenient for imprinting;

step S323: and (4) carrying out UV imprinting on the UV-cured resin layer by using a mold roller 8 with a pattern structure on the surface, wherein the mold roller 8 is manufactured in the same manner as the steps S1 to S3. During imprinting, the side of the mold roller 8 provided with the pattern structure is in close contact with the UV curing resin through the squeezing roller 7, and then the UV curing resin is irradiated through an ultraviolet lamp 10, so that the pattern structure on the UV curing resin is formed before being stripped from the mold roller 8, and the pattern structure on the surface of the mold roller 8 is transferred to the surface of the substrate layer 5.

Step S324: the base material layer 5 is turned over by the guide roller 9, the surface of the other side of the base material layer 5 is uniformly coated with the UV curing resin, the other mold roller 8 is attached to the base material coated with the UV curing resin, the UV curing resin layer on the surface of the base material layer 5 is cured, the solid UV curing resin layer is formed on the surface of the other side of the base material layer 5, and a semi-finished diffusion sheet with the micro-lens structures 122 and the filling structures on the two side surfaces is obtained.

Step S325: and filling a reflective material 1231 in the filling structure, and curing and forming to obtain a finished diffusion sheet.

In the preparation method, the two sides of the prepared diffusion sheet semi-finished product are respectively the micro-lens structure 122 and the filling structure, so that when imprinting is carried out, the diffusion sheet semi-finished product can be prepared by sequential single-side imprinting or simultaneous double-side imprinting, and the imprinting principles of the two are basically consistent, which is not described herein.

It should be noted that, in the two preparation methods, the mold roller may be prepared by applying a template having a desired pattern structure on the surface thereof, or the desired pattern structure may be directly prepared on the surface of the mold roller, and the template or the mold roller may be made of nickel, steel, copper, aluminum, or the like.

The embodiment also provides a backlight module, which comprises the Mini LED diffusion sheet 12.

The backlight module further comprises a lamp bead panel 11, a blue light film 13, a quantum dot film 14, a first brightness enhancement film 15, a second brightness enhancement film 14 and a diffusion film 17 which are arranged in sequence, as shown in fig. 15. The diffusion sheet 12 is arranged between the bead panel 11 and the blue light film 13, and the diffusion sheet 12 is at least one layer. The side of the diffusion sheet 12 filled with the reflective material 1231 faces the lamp bead panel 11, as shown in fig. 16. The structural units on the diffusion sheet 12 correspond to the lamp beads 111 on the lamp bead panel 11 one by one. In addition, one or more light uniformizing sheets may be further added between the blue light film 13 and the diffusion film 17 or between the first brightness enhancement film 15 and the quantum dot film 14 as required, and the light uniformizing sheet may be a light uniformizing sheet having a microlens structure 122 on both sides, or a light uniformizing sheet having a microlens structure 122 on one side and a convex lens body on the other side as shown in fig. 15.

Example two

A difference between this embodiment and this embodiment is that the microlens structure 122 on one side of the diffusion sheet in this embodiment is a circular protrusion structure 1222, as shown in fig. 17. The convex surface of the microlens structure 122 is preferably a curved surface. The preparation method of the diffusion sheet and the backlight module structure in this embodiment are the same as those in the first embodiment, and are not described herein again.

EXAMPLE III

The difference between this embodiment and the first embodiment is that the microstructure on one side of the diffusion sheet in this embodiment is a convex lens 124. The convex lens body 124 is in one or more of a prism shape, a pyramid shape, a semi-cylinder shape and a cone shape, or is in a composite shape formed by one or more of the shapes according to a set rule. When the convex mirror bodies 124 are prism-shaped (such as triangular prism) or semi-cylindrical, the convex mirror bodies 124 are arranged in parallel and continuously on one side of the substrate 121, the axial direction is parallel to the plane, and the bottom edges of two adjacent convex mirror bodies 124 intersect. When the convex mirror bodies 124 are pyramid-shaped, for example, triangular pyramid-shaped, as shown in fig. 18 to 21, or rectangular pyramid-shaped, as shown in fig. 22 to 25, the convex mirror bodies 124 are arranged in series, the bottom sides of two adjacent convex mirror bodies 124 intersect, and the two intersecting bottom sides coincide with the intersecting line, as shown in fig. 19 or 23. Of course, the convex mirror body 124 may also have other pyramid shapes, which are basically the same and will not be described herein again. When the convex lens bodies 124 are cones, the bottom parts of the convex lens bodies 124 are overlapped, and the coverage range of the convex lens bodies 124 on the light homogenizing plate can be increased as same as that of the micro-lens structure 122, and the duty ratio can reach 100%. In addition, the convex mirror body 124 may also be a crossed semi-cylinder formed by combining two semi-cylinders, such as an orthogonal cylinder, and is in a grid shape on one side of the light homogenizing plate. Of course, a composite shape obtained by crossing two other shapes such as a prism shape may be used. The size of the lenticular body 124 is on the order of micrometers, and preferably the height of the lenticular body 124 is 0.01mm to 0.1 mm. When the convex lens body 124 is conical, the included angle of the tip is preferably 60-120 degrees. The preferred longitudinal section apex angle of the cone is 90 degrees.

The preparation method of the diffusion sheet and the backlight module structure in this embodiment are the same as those in the first embodiment, and are not described herein again.

As used herein, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, including not only those elements listed, but also other elements not expressly listed.

In this document, the terms front, back, upper and lower are used to define the components in the drawings and the positions of the components relative to each other, and are used for clarity and convenience of the technical solution. It is to be understood that the use of the directional terms should not be taken to limit the scope of the claims.

The features of the embodiments and embodiments described herein above may be combined with each other without conflict.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (8)

1. The utility model provides a Mini LED diffusion piece, its characterized in that, it includes the base, locates the micro-structure of base one side and locating the filling structure of base opposite side, the micro-structure includes a plurality of microlens structure and/or a plurality of convex mirror body, the filling structure includes a plurality of constitutional unit, constitutional unit includes the packing figure that a plurality of isopycnic line was arranged, and is same among the constitutional unit, the density of arranging of packing figure certainly constitutional unit center diminishes to all around gradually, the packing figure is groove structure, the packing figure intussuseption is filled with reflective material.

2. The Mini LED diffusion sheet of claim 1, wherein the micro lens structures comprise concave structures and/or convex structures, a plurality of the micro lens structures are arranged in multiple rows, a plurality of the micro lens structures in two adjacent rows are arranged in a staggered manner, a random arrangement or an orthogonal arrangement, two adjacent micro lens structures are partially overlapped, the convex surfaces of the convex structures are curved surfaces, and the concave surfaces of the concave structures are curved surfaces.

3. The Mini LED diffuser of claim 2, wherein the size of the micro lens structures is 0.03mm to 0.09mm, and the depth or height of the micro lens structures is 0.01mm to 0.05 mm.

4. The Mini LED diffuser of claim 1, wherein the substrate has a thickness of 0.1mm to 2.0mm and the overlap of two adjacent microlens structures is in the range of 5% to 25%.

5. The Mini LED diffusion sheet according to claim 1, wherein the convex lens body is one or more of prismatic, pyramidal, semi-cylindrical and conical, or a composite shape composed of one or more of the foregoing shapes according to a set rule;

the height of the convex lens body is 0.01mm-0.1mm, and when the convex lens body is conical, the included angle of the tip end of the convex lens body is 60-120 degrees.

6. The Mini LED diffuser of claim 1, wherein the filling pattern is cylindrical and countersunk, and the bottom of the filling pattern is arc-shaped;

the reflective material is reflective ink, metallic silver or metallic aluminum;

the size of the filling pattern is 0.005mm-0.1mm, and the depth of the filling pattern is 0.004mm-0.05 mm.

7. A backlight module comprising the Mini LED diffuser of any one of claims 1 to 6.

8. The backlight module according to claim 7, further comprising a lamp bead panel, a blue light film, a quantum dot film, a first brightness enhancement film, a second brightness enhancement film and a diffusion film, which are sequentially arranged, wherein the Mini LED diffusion sheet is arranged between the lamp bead panel and the blue light film, the Mini LED diffusion sheet is at least one layer, one side of the Mini LED diffusion sheet filled with a reflective material faces the lamp bead panel, and structural units on the Mini LED diffusion sheet correspond to the lamp beads on the lamp bead panel one to one.

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