TW201122658A - Optical plate and backlight module using the same - Google Patents

Abstract

An optical plate includes a first surface and a second surface opposite to the first surface. The first surface forms a plurality of micro structures. A contour of each micro structure at the first surface is elliptic in shape. In a three-dimensional cartesian coordinate, a longer axis of each contour of each micro structure represent an X-axis, and a shorter axis of each contour of each micro structure represent a Y-axis. The contour of each micro structure is represented by follow equation: , wherein S, y0, A, xc, w1, w2, w3 and θ are constants. The second surface is plane. A backlight module using the optical plate is also provided.

Description

201122658 VI. Description of the Invention: [Technical Field] The present invention relates to a backlight module and an optical plate thereof, and more particularly to a backlight module for liquid crystal display and an optical plate thereof. [Previous Technology] [〇〇〇2] Referring to FIG. 1 , a conventional direct type backlight module 100 includes a frame 11 , a plurality of light sources 设置 2 disposed inside the frame 11 , and a light source 12 disposed above the light source 12 . Diffusion plate 13. When used, the light generated by the complex light source 12 enters the diffusion plate 13 and can be diffused. However, after the diffusion through the diffusion plate 13, the angle of light exiting from the diffusion plate 13 becomes more disordered, so that the brightness is not high in a specific viewing angle range; and since the light source 12 transmits more light directly above it, diffusion It is often difficult for the plate 13 to directly diffuse the light from the light source 12 uniformly, so that the light emitted from the diffusing plate 13 is likely to cause residual light source, that is, a region where light intensity is different. [_From the high-back domain group (9) to the brightness of the specific viewing mode and avoiding the generation of the residual image of the light source, the uniformity of the light emitted from the backlight module 100 is improved. ϋ An optical plate 1 is usually disposed above the diffusion plate 13. As shown in FIG. 2, the optical plate 10 includes a transparent substrate 101 and a ruthenium layer 1 (3) formed on the moon-permeable substrate 101. The enamel layer 1Q3 has a plurality of elongated V-shaped projections 1〇5. The long strip-shaped protrusions of the optical plate 1 can cause the occurrence of light rays to be concentrated, thereby improving the brightness of the backlight module (10) in the range of the viewing angle of the backlight. The upper diffusion sheet 14 can further diffuse light emitted from the optical plate. [0005] 098144396 =: When the optical plate is transported, 0982075912-0 201122658 will be absorbed to cause light loss; and there is an air layer between the optical plate 10 and the upper diffusion sheet 14, which will increase the number of interfaces in the transmission process. Increase the interface loss of light transmission and reduce the brightness of light. SUMMARY OF THE INVENTION [0006] In view of the above circumstances, it is necessary to provide a backlight module having a high light-emitting luminance and an optical plate thereof. [0007] A backlight module includes a frame, a light source, and an optical plate. The light source is located within the frame and the optical plate is positioned above the light source. The optical plate includes a first surface and a second surface opposite the first surface. A plurality of microstructures are formed on the first surface. The contour of the microstructure on the first surface encloses an ellipse, and the long axis and the minor axis of the ellipse form a Χ-Υ-Ζ three-dimensional rectangular coordinate system for the X axis and the Υ axis respectively, and any point on the contour line y The coordinate value and the X coordinate value satisfy the following relationship: [0008] ❹ 1 + exp(- l + exp(- ' [0009] The projection of the protrusion on the xz plane is a closed pattern surrounded by a ridge line and an x-axis, wherein The z coordinate value and the X coordinate value of any point on the ridge line satisfy the following relationship: [(5) 10] 2 — ^xtan(90o-^) 098144396 Form No. A0101 Page 5 of 25 0982075912-0 201122658 [0011] [0012 ] ^^^^:^厂^ and ❷ are constants', respectively, whose range is -13. 549 &lt; y &lt; -9.549, -1 〇&lt; γ / 0 υ 〈 xc&lt; 1. Ο , 62.754 &lt; A < 72.754, 45.72 < '&lt; 28〇2, 8.01 &lt; w2< 53.03, 8.01 &lt;w3&lt; 53.03, 45S < ( 175s, 〇. l &lt; s &lt; 3, the second surface is a plane .

An optical plate comprising a first surface and a second surface opposite the first surface. A plurality of microstructures are formed on the first surface. The outline of the microstructure on the first surface is surrounded by an ellipse, and the long axis and the short axis of the ellipse are respectively defined as an X-γ-Ζ^-dimensional rectangular coordinate system for the X-axis and the Y-axis, respectively, and any point on the contour line The y coordinate value and the X coordinate value satisfy the following relationship: [0013] y = Sx 1 + e^&gt;(- (χ· •f) ·χ(ΐ_- 1 + exp( [0014] The protrusion is on the XZ plane ^敏影 is a closed diagram of a ridge line and ^ axis

a shape in which the z coordinate value and the X coordinate value of the arbitrary-point on the ridge line satisfy the following relationship: [0015] z = y X tan (90°)

Wherein, 51〇, 八, \111213, and 0 are constants, and the ranges are respectively 13. 549 &lt;y〇&lt; -9.549, -1.0 &lt;xc&lt; 1.( , 62. 754 &lt; A &lt; 72. 754,45. 72 &lt; w/ 280. 2, 098144396 Form No. A0101 Page 6 of 25 0982075912-0 [0016] 201122658 8.01 &lt;w&lt; 53. 03 '8. 01 &lt;w&lt; 53.03 ^452 &lt; ( &lt; L ο 175e, 0.1 &lt; S &lt; 3, the second surface is a plane. [0018] [0020] [0021] The above optical plate can be incident thereon The light is refracted, reflected and diffracted, and then a specific diffusion occurs to form a uniform light-emitting surface. The convex structure on the first surface can also converge the light-emitting angle of the outgoing light to enhance the brightness. [Embodiment] The backlight module and the optical plate of the present invention are further described in detail with reference to the accompanying drawings and embodiments. Referring to FIG. 3, there is shown an optical plate 20 according to a preferred embodiment of the present invention having a first surface 201 and A surface 201 is opposite to the second surface 203. The first surface 201 is formed with a plurality of micro-structures 201 arranged in a plurality of arrays. 1. In the present embodiment, the microstructures 2011 are protrusions extending outward from the first surface 201, and the second surface 203 is planar. The optical plate 20 is made of a transparent material. The transparent material is polydecyl methacrylate. , a mixture of one or more of polycarbonate, polystyrene, styrene-mercapto methacrylate copolymer. Referring to Figures 4 to 7, the microstructure 2011 is surrounded by the bottom surface 2012 and the two sides 2013, The side surface 2013 intersects at the top of the microstructure 2011 to form a ridge line 2014. The bottom surface 2012 is substantially elliptical, which is surrounded by two contour lines 2015 of the microstructure 2011 on the first surface 201, and the bottom surface 2012 has a long axis 2016 and A short axis 2017. The long axis 2016 is the X axis, the short axis 2017 is the Y axis, and the intersection of the long axis 2016 and the short axis establishes a three-dimensional Cartesian coordinate system for the origin, and the direction of the Z axis points to the extension direction of the microstructure 2011. Microstructure 098144396 Form No. A0101 Page 7 / Total 25 Page 0992075912-0 201122658 2011 itself is symmetric with respect to both the χ-ζ plane and the YZ plane. In the above three-dimensional Cartesian coordinate system, the trajectory of the contour line 201 5 can be as follows description [0025] [0025] [0025] y〇+^4χ χ 1 + β3φ (W3 In the above equation, y is the coordinate value of any point on the contour line 2015 on the γ-axis, and X is the point on the X-axis. The coordinate value. The rest are constants, wherein the preferred range of χ and each constant is as follows: -] 3.540 &lt;5^&lt;-9.549, _213.5 &lt; χ &lt; 213.5, -1. &lt; 1. 〇, 62.754 &lt; A &lt; 72· 754, 45. 72 &lt; w/ 280. 2, 8. 01 &lt; w &lt; 53. 03 ' 8. 01 &lt;w3&lt; 53· 03, 0· 1< s< 3. Since the microstructure 2011 is symmetric about the χ-ζ axis, the ridge line coil 4 extends in a plane, the projection of the ridge line 2014 on the Χ-Ζ plane is itself, and the microstructure 2011 is arbitrarily parallel to the plane of the γ-ζ plane. The cross section is a triangle (Fig. 5), and the apex angle of the triangle is 0. The ordinate coordinate value 2 of any point on the ridge line 2014 of the microstructure 2〇11 has the following relationship with the γ axis coordinate value 7: Gz = yx tan(90° —) • x(i- xtan(90°- Θ l + exp(- w3 098144396 Form No. A0101 Page 8 of 25 0982075912-0 201122658 [0026] [0028] [0030] [0032] The above formula is the relationship between the coordinates of the Ζ coordinate and the X coordinate of any point on the ridge 20 1 4, that is, the curved trajectory of the ridge line 2014 on the Χ-Ζ plane projection (Fig. 6) wherein, the preferred range of X and each constant in the above formula is as follows: -13. 549 &lt;y〇&lt; -9.549, -213·5 &lt; X &lt; 213.5, -1.0 &lt; X &lt; C 1.0 , &lt; 72.754, 45.72 &lt S &lt; 3. At least the top of the microstructure 2011 Planarization, or arcing, to enhance the overall strength of the optical plate 20. At this time, the projection of the ridge line 2014 on the XZ plane satisfies the trajectory equation of the ridge line 2014. The microstructure 2011 on the optical plate 20 can be used with The transparent material is formed on the first surface 201, and the corresponding groove can be engraved in the female mold. When the injection molding is integrally formed, the second surface 203 of the optical plate 20 is adjacent to the light source as the light incident surface, and the first surface 201 Along from the light source as the light exiting surface, after the light emitted by the light source enters from the second surface 203, specific refraction, diffraction and total reflection occur in the microstructure 2011, and the light exiting angle of the light converges to increase the brightness of the light. Of course, the microstructure 2011 The slanting angles of the ridges 2014 at the ends of the YZ may be different from the X-axis, so that the microstructures 2011 have an asymmetrical shape with respect to the YZ plane. The structure of the microstructures 2011 is not limited to the protrusions, but may be the same shape, The first surface 201 extends toward the inside of the optical plate 20. At this time, the outline of the microstructure 2011 on the first surface 201 is the same as when it is convex, and the ridge line 2014 of the microstructure 2011 will be located in the first table. Below 201, Z-axis pointing to the first sheet number A0101 098 144 396 Page 9/25 Total 201 122 658 0982075912-0 second surface 203. When the microstructure 2011 is a groove, the effect of the optical plate 20 is substantially the same as when the microstructure 2011 is convex. [0033] Referring to FIG. 8, a backlight module 200 according to a preferred embodiment of the present invention includes the optical board 20, a frame 21, and a light source 22. The light source 22 is located in the frame 21, and the optical board 20 is located. Above the light source 22. [0034] The frame 21 may be made of metal or plastic having high reflectivity or metal or plastic coated with a high reflectivity coating. The light source 22 may be a plurality of line sources or a plurality of point sources. In this embodiment, the plurality of line sources are arranged closely. Preferably, the plurality of line sources are a plurality of cold cathode fluorescent lamps. [0036] The second surface 203 of the optical plate 20 in the backlight module 200 faces the light source 22 as a light incident surface and the first surface 201 away from the light source 22 as a light exit surface. The plurality of cold cathode fluorescent lamps are arranged closely, and the emitted light is incident on the optical plate 20 to cause specific optical effects such as refraction, scattering, reflection, and diffraction, and the light emitted from the optical plate 20 is specifically diffused. Thereby, an exit surface with a relatively uniform brightness is formed. Wherein, the structure of the microstructure 118 on the first surface 201 can converge the exit angle of the light, so that the brightness of the emitted light in a specific range is increased. It can be seen that the backlight module 200 can improve the light uniformity of the backlight module and enhance the brightness of the light. Of course, when the light source 22 is a plurality of point light sources, the plurality of point light sources are closely arranged in an array, and the effect of using the plurality of line sources can be achieved. Preferably, the plurality of point sources are complex light-emitting diodes. [0037] In order to further verify the effect of the optical plate 20, nine test points are taken on the light-emitting surface of the backlight module 100 and the backlight module 200 to make a light under the same light source. 098144396 Form No. A0101 Page 10 of 25 0982075912-201122658 Degree comparison test, the test results are shown in the following table. [0038] Table 1 comparison test table (luminance unit: cd / m2) [0039] 2 3 4 〇〇 [0040] [0041] 098144396 5 6 7 8 test point number ι backlight module 100 backlight module 200 brightness improvement The brightness of the luminosity brightness is 1775.〇〇2027.20 14. 2% 1652.60 1904.20 15. 2% 1592.80 1926.80 20. 9% 1771.20 2054.60 16. 0% 1623,8〇-----: 1919.00 18. 2% 1497.80 2082.00 39. 0% 1624.20 2220.40 36. 7% 1570.〇〇2009.60 28. 0% 1566.20 2198,20 40. 3% degrees are better than the backlight brightness of the backlit chess set 100, the brightness is improved by at least 14%, the effect is obvious. When there is a large distance between Tianguangyuan 2, the backlight module 200 can be invented and a diffuser plate is added between the light source and the light source 22, so that the light can be diffused and the light of the whole backlight module can be improved. Uniformity. In summary, the invention has indeed met the requirements of the invention patent and has filed a patent application in accordance with the law. However, the above description is only a preferred embodiment of the present invention. Equivalent modifications or variations made by persons skilled in the art in light of the spirit of the invention are intended to be included within the scope of the following claims. Form nickname A0101 Page 11 of 25 0982075912-0 201122658 [Simple Description of the Drawings] [0042] FIG. 1 is a schematic cross-sectional view of a conventional backlight module. 2 is a perspective view of an optical plate of the backlight module shown in FIG. 1. 3 is a perspective view of an optical plate according to a preferred embodiment of the present invention. 4 is a perspective view showing the protrusion of the optical plate shown in FIG. 3. 5 is a cross-sectional view of the protrusion of the optical plate shown in FIG. 3 on the Y-Z plane. 6 is a projection view of the protrusion of the optical plate shown in FIG. 3 on the X-Z plane. 7 is a cross-sectional view of the protrusion of the optical plate shown in FIG. 3 on the X-Y plane. 8 is a schematic view of a backlight module using the optical plate shown in FIG. 3. [Main component symbol description] [0050] backlight module 100, 200 [0051] optical plate 10, 20 [0052] substrate 101 [0053] 稜鏡 layer 103 r

U

[0054] elongated V-shaped projections 105 [0055] Frames 11, 21 [0056] Light source 12, 22 [0057] Diffusion plate 13 [0058] First surface 2 0 1 [0059] Microstructure 2011 0982075912-0 098144396 Form No. A0101 Page 12 / Total 25 Pages 201122658 [0060] [0065] [0065] 底面 Underside 2012 Ridgeline 2014 Outline 2015 Long Axis 2016 Short Axis 2017 Second Surface 203 Ο 098144396

Form No. Α0101 Page 13 of 25 0982075912-0

Claims (1)

201122658 The scope of the patent application is as follows: A backlight module comprising: (4) a light source and a fresh plate, wherein the light source is located in the miscellaneous frame. The optical plate is located above the light source, and the optical plate comprises a first surface and a side surface. In contrast to the second surface, the second surface faces the light source, and the improvement is that the first surface is formed with a plurality of microstructures, and the outline of the plurality of microstructures on the first surface is surrounded by an ellipse. The long axis and the short axis establish an XYZ three-dimensional rectangular coordinate system for the X axis and the Y axis respectively. The microstructure extends along the z axis direction, and the y coordinate value and the X coordinate value of any point on the rim line satisfy the following relationship: ❹ y = 3x y〇+ Ax- 14- exp(- f), x(l. 1 + ejq&gt;(- hf)) w3 The projection of the microstructure on the X-Z plane is a ridge line and x _ A closed graph in which the two coordinate values and the X coordinate values of any point on the ridge line satisfy the following relationship: z=yxtm(9&lt;P· where S, Λ Wl w. w_ and θ are constants, and the range is 13.549 &lt;;y0&lt;-9.549 ? -1.0 &lt;kc &lt;1.0 ? 62.754 &lt;A &lt;72.754 * 098144396 Form No. A0101 Page 14 of 25 0982075912-0 201122658 45.72 &lt;Wl &lt;280.2 ' 8.01 &lt;w2 &lt;53.03 ' 8.01 &lt;w3 &lt;53.03 ^ 45° &lt;5 &lt;175° 5 The backlight module of claim 1, wherein the microstructure is a protrusion extending outward from the first surface, the microstructure being on the first surface The backlight module of claim 1, wherein the microstructure is a recess in which Q extends from the first surface into the optical plate. The backlight module of claim 3, wherein the light source is a plurality of line sources, and the plurality of line sources are closely arranged. 5. The backlight module of claim 1, wherein the microstructure is arbitrarily The cross section of the parallel YZ plane is an isosceles triangle. 6. The backlight module of claim 1, wherein at least part of the top of the microstructure is planarized. 7. As claimed in claim 1 a backlight module, at least partially The top of the structure is rounded. 8. An optical plate comprising a first surface and a second surface opposite the first surface, wherein the first surface is formed with a plurality of microstructures, the plurality of microstructures The contour line of the contour contour on the first surface is formed into an elliptical shape, and the XYZ three-dimensional rectangular coordinate system is established by the long axis and the short axis of the ellipse for the X axis and the Y axis respectively, and the microstructure extends along the Z axis direction. , the y coordinate value and the X coordinate value of any point on the contour line satisfy the following relationship: 098144396 Form number A0101 Page 15 of 25 0982075912-0 201122658 y=^xy〇+ Ax- 1 + exp(- (Di x(l. 1 + exp(- {x-xe-^p w3 The projection of the microstructure on the XZ plane is a closed pattern enclosed by a ridge line and an x-axis] where the coordinate value of any point on the ridge line And the x coordinate values satisfy the following relationship: z = , y xtan(90o~ , , 2 +c ' wx ' w2 , w3 ^ are constants, and their ranges are -13.549 &lt;-9.549 ^-1.0 &lt;xc &lt;;1.0 62.754 &lt; A &lt;72.754, 45.72 &lt; wx &lt;280.2&quot; 8.01 &lt;w2 &lt;53.03 8 01 &lt; w 3 &lt;53.03 J 45° &lt; 9 &lt; 175 ° * Ctl &lt; S &lt;! 3, the second surface is a plane. The optical plate of claim 8, wherein the microstructure is a protrusion that protrudes outwardly from the first surface, and the contour of the microstructure on the first surface is the bottom surface of the protrusion. The optical sheet as described in claim 8 of the patent application form No. A0101, page 16 of 25, wherein the microstructure is a groove extending from the surface of the surface of 0982075912-0 201122658 to the optical plate. 11 12 . 13 . Ο G = Please ask the silk plate of the ninth item on the patent side. The section of the ❹ 结构 structure is the isosceles triangle cut by the plane of the 仃 仃 仃 ζ plane. An optical plate as described in Patent Document 9, wherein at least a portion of the microstructure top is planarized. The optical sheet of claim 9, wherein at least a portion of the microstructure top is rounded. 098144396 Form No. Α0101 Page 17 of 25 0982075912-0