KR20100095536A - Optical sheet and backlight unit using the same - Google Patents

Abstract

An object of the present invention is to eliminate the luminance gap in accordance with the distance from the CCFL (2) by repeatedly forming a set (S) of a plurality of raised portions (1a to 1c) of isosceles triangles with different low angles, arranged on the upper surface, Moreover, it is providing the optical sheet 1 which does not exist also in the arrangement position of CCFL2, and the backlight unit using the same. The present invention provides an optical sheet (1) in which a plurality of convex ridges are arranged on an upper surface of an optical sheet (1) for use in a direct-lighting backlight unit, the area of the optical sheet (1) corresponding to each CCFL (2). These ridges in the inside are configured by further repeating the arrangement set S of the three types of ridges 1a to 1c having different shapes.

Description

Optical sheet and backlight unit using the same {OPTICAL SHEET AND BACKLIGHT UNIT USING THE SAME}

The present invention relates to an optical sheet in which a plurality of convex ridge portions or concave groove portions are arranged on at least one surface of the transparent resin sheet, and a backlight unit such as a liquid crystal display using the optical sheet.

The backlight of a liquid crystal display used for a television receiver, a personal computer, or the like has a direct light method in which a plurality of linear light sources made of a straight tube type CCFL (cold cathode tube), etc. are arranged on the rear side of the liquid crystal panel at intervals, and the back of the liquid crystal panel. The edge light system etc. which arrange | position the light guide plate in the side and arrange | position the line light source in the side of this light guide plate are mentioned.

The conventional direct light type backlight unit is a flat convex linear Fresnel lens type with a diffusion sheet (diffusion plate) or the like, or instead of the diffusion sheet, between the liquid crystal panel on the front side of the line light source. There existed a case where the optical sheet was arrange | positioned (for example, refer patent document 1). When a flat convex linear Fresnel lens-type optical sheet is used, the light emitted radially from a linear light source is condensed and guided to the liquid crystal panel as a front-facing parallel light as in the case where a flat convex cylindrical lens is disposed. can do. In addition, since the optical sheet can be made thinner than the flat convex cylindrical lens, it is possible to greatly reduce the size and cost of the backlight unit.

Moreover, when using the optical sheet which provided many concave triangular groove parts (a convex triangular ridge) in the surface of a translucent resin sheet, the lower angle is large as the distance from a line light source is used instead of the said optical sheet. (For example, refer patent document 2). Even when this optical sheet is used, as the distance from the line light source increases and the light enters obliquely, the refraction in the groove portion increases, so that the emitted light can be guided to the liquid crystal panel closer to the parallel light toward the front.

In addition, in the backlight unit of the direct light method or the edge light method, an optical sheet in which a large number of convex or pyramidal convex portions are arranged vertically and horizontally on the surface of the translucent sheet may be used (for example, See Patent Document 3). By using this optical sheet, the light incident from the direct light type linear light source or the light incident through the edge light type light guide plate can be diverted to the front direction as far as possible and guided to the liquid crystal panel.

By the way, the optical sheet in which the convex parts, such as the said cone | convex part, were formed longitudinally and horizontally, has the effect | action which raises front brightness by changing the scattered light which has components of various directions into the light with many components of a direction toward a front, and emitting it. Therefore, as shown in FIG. 16, when this optical sheet 1 is used for the direct light type backlight unit, the prism-shaped convex of the upper surface of the optical sheet 1 is located at the position E ₀ of the CCFL 2 directly. Since the total reflection in the part becomes large and light having a lot of upward components is emitted at the position E ₁ which is somewhat separated in the left and right direction, the outgoing light is inclined in this left or right direction at a position E ₂ further apart in the left and right directions. A large luminance gap occurs according to the arrangement position of the CCFL 2. For this reason, when this optical sheet 1 is used for the conventional direct-lighting backlight unit, a plurality of diffusion sheets etc. are arrange | positioned between CCFL 2 and the optical sheet 1, for example, and CCFL ( Since light from 2) must be sufficiently diffused in advance, there is a problem that this diffusion sheet or the like becomes expensive.

On the other hand, as shown in FIG. 17, the said flat sheet convex linear Fresnel lens type optical sheet 1, the recessed triangular groove part etc. which change a low angle, etc. were arranged in the backlight unit of a direct light system. In the case of using (1), the farther the distance from the CCFL 2 is, the larger the angle of refraction on the upper surface of the optical sheet 1 is, so that upward light is emitted regardless of the distance from the CCFL 2. can do.

However, the flat sheet convex linear Fresnel lens type optical sheet 1 and the concave triangular groove portion in which the low angle is changed are arranged so that the lower CCFL 2 corresponds to the uneven pattern on the upper surface. Since the arrangement | positioning position of ()) is determined, as shown in FIG. 18, when this CCFL2 shifts to the left-right direction rather than the center position C of the optical sheet 1, output light will incline rather than become upward. For this reason, conventionally, not only the precise operation | work which prevents a shift | offset | difference in a cutting position of the optical sheet 1, or a shift | offset | difference in a mounting position of the CCFL 2 is required, but also the number of CCFLs 2 is increased or decreased. There was a problem that it could not cope with design changes such as

Patent Document 1: Japanese Unexamined Patent Publication No. 2005-338611 Patent Document 2: Japanese Unexamined Patent Publication No. 2007-114587 Patent Document 3: Publication No. 7-8805

The present invention eliminates the luminance gap in accordance with the distance from the line light source by repeatedly forming a set of a plurality of convex ridges or concave grooves having different shapes, for example, in a triangular shape with different low angles. It is also possible to provide an optical sheet and a backlight unit using the same, which do not depend on the arrangement position of the line light source.

MEANS TO SOLVE THE PROBLEM In order to solve the said subject, the optical sheet of Claim 1 is an optical sheet used for the backlight unit of a direct light type | system | group, and a convex ridge or concave groove | channel is formed in the surface of the light exiting side in a translucent sheet | seat. An optical sheet in which a large number of additions are formed, wherein the ridges or grooves thereof in the region of the optical sheet corresponding to each line light source are arranged by further repeating a set of arrangements of a plurality of ridges or grooves having different shapes. It is characterized by.

The optical sheet of Claim 2 may differ in the order of the arrangement | positioning of the ridge | bulb part or groove part from which the shape in each said set differs. It is characterized by the above-mentioned.

The optical sheet of claim 3 is characterized in that the shape of each ridge or groove is symmetrical about a plane orthogonal to the arrangement direction.

The optical sheet of claim 4 is characterized in that the ridge widths or groove widths of the ridges or groove portions having different shapes in the respective sets are different from each other.

The optical sheet of claim 5 is characterized in that the longitudinal cross-sectional shape orthogonal to the ridge length or groove length of each of the ridges or grooves is a triangular shape whose both inner angles of the base are less than 90 °.

As for the optical sheet of Claim 6, the longitudinal cross-sectional shape orthogonal to the ridge length or groove length of each said ridge or groove part is an isosceles triangle, and the difference of the shape of each ridge or groove part in each said set is an isosceles triangle. It is characterized by being the upper part of the low angle.

The optical sheet of claim 7 has a large sum of both inner angles of the base of the triangle having a longitudinal cross-section orthogonal to the ridge length or groove length of each ridge or groove portion having different shapes in the sets. It is characterized in that the ridge width or groove width of these ridges or grooves is wider.

The optical sheet of claim 8 has a longitudinal cross-sectional shape orthogonal to the ridge length or the groove length of each of the ridges or grooves, wherein the inner corners of the base are 90 degrees or less in polygonal shape, or semi-circular arc shape or less. do.

The optical sheet of claim 9 is characterized by having two or more and ten or more ridges or grooves arranged in each of the sets.

The backlight unit using the optical sheet of Claim 10 arrange | positions the said optical sheet in the front side of one or more linear light sources, It is characterized by the above-mentioned.

According to the invention of claim 1, a set of a plurality of convex ridges or concave grooves having different shapes is formed on the surface of the optical sheet repeatedly so that any one of the ridges of each set is different even if the distance from the line light source is different. The light emitted from the grooves is directed to the front side to some extent, and the luminance gap according to the distance from the line light source can be eliminated. In addition, since each of the sets has ridges and grooves of the same shape, the arrangement position of the line light source is also arbitrary, and the effect of the positional shift of the line light source is not eliminated, and the design of increase or decrease of the number of the line light sources is also made. The change can be easily coped with.

According to the invention of claim 2, since the ridges and grooves of the same shape may exist in each set, and the order of the arrangement of these ridges and grooves is arbitrary, even if the arrangement order may be different, the effect of the present invention is not affected. none.

According to the invention of claim 3, since the shape of each ridge or groove is bilaterally symmetrical, it is possible to prevent the luminance gap depending on which side of the line light source is left or right. In addition, when a plurality of linear light sources are arranged at intervals to the left and right, the light from both linear sources can be effectively used between these linear light sources.

According to the invention of claim 4, the optical narrowness of the ridge width or the groove width can be adjusted according to the shape of the ridge or groove portion. Here, when the ridge width or groove width is wide, more light from the linear light source can be taken in the ridge or groove portion thereof. Therefore, if both the ridge width and the groove width are the same, the utilization ratio of incident light (ratio of the light emitted toward the front side to some extent with respect to the total incident light in the ridge or groove portion) depending on the shape of each ridge or groove portion. If there is a difference between the top and bottom), by adjusting the ridge width or the groove width, the utilization rate of incident light can be made as uniform as possible.

Here, the ridge width or the groove width means the sheet surface of the optical sheet (a surface parallel to the flat surface averaged by equalizing the ridge or groove portion, and in the case where the lower surface is flat, the surface parallel to the lower surface). Refers to the length of the ridge portion or groove portion arrangement direction (direction perpendicular to the ridge length or groove length on the sheet surface of the optical sheet).

According to the invention of claim 5, in the case of the ridge, the triangular prism is formed, and in the case of the groove, the triangular cylindrical inner surface can be emitted, so that most of the light incident on the optical sheet can be emitted. It is possible to reliably emit light toward the front side to some extent.

In addition, a bottom side is an imaginary side according to the sheet surface of the optical sheet in the triangle which made the both sides of the ridge | bulb part or the groove part into the both sides of a longitudinal cross-sectional shape here.

According to the invention of claim 6, the shape of each ridge or groove is symmetrical, and in the case of the ridge, the triangular prism is formed, and in the case of the groove, the triangular cylindrical inner surface is formed. In addition to preventing occurrence, most of the light incident on the optical sheet can be emitted, and it is possible to reliably emit light toward the front side to some extent from any of the ridges or grooves of each set.

In addition, the bottom angle of an isosceles triangle is an internal angle (both inside angles are the same) of an isosceles triangle.

According to the seventh aspect of the present invention, each of the ridges or grooves of each set has a wider ridge width or groove width as the vertex of the triangle having a longitudinal cross section is smaller and sharper, and thus can receive more incident light. Since the utilization rate of incident light decreases as the ridge or groove is small and sharp, the utilization rate of incident light in each ridge or groove having a different vertex angle can be made uniform. Will be.

According to the invention of claim 8, in the case of the raised part, it becomes a half polygonal column shape or a semi-cylindrical shape, and in the case of the groove part, it becomes a half- polygonal cylinder inner surface or a semi-cylindrical inner surface type, so that most of the light incident on the optical sheet can be emitted. It is possible to reliably emit light toward the front side to some extent from any of the ridges or grooves in each set.

According to the invention of claim 9, since each set has a ridge or groove having different shapes, the light emitted from any of the ridge or groove in each set can be reliably directed to the front side to some extent. In addition, since each set of ridges and grooves is 10 or less, the range of one set of ridges and grooves can be sufficiently narrowed, and the luminance gap for each set can be suppressed.

According to the invention of claim 10, it is possible to provide a backlight unit which eliminates the luminance gap according to the distance from the line light source and does not depend on the arrangement position or the number of arrangement of the line light source.

BRIEF DESCRIPTION OF THE DRAWINGS The exploded perspective view which shows one Embodiment of this invention and shows the structure of the backlight unit using an optical sheet.
Fig. 2 is a partial enlarged longitudinal sectional front view of the optical sheet used for the backlight unit, showing one embodiment of the present invention.
Fig. 3 is a partial enlarged longitudinal sectional front view showing one embodiment of the present invention, showing one set of ridges in the optical sheet.
Fig. 4 shows an embodiment of the present invention, and is a partially enlarged longitudinal sectional front view of a position (b) separated from the center position (a) in the right direction and a position (c) further separated to the right in the optical sheet.
FIG. 5 shows another embodiment of the present invention, wherein the enlarged longitudinal cross-sectional front view of the optical sheet in which the ridge width | variety of each ridge part differs. FIG.
Fig. 6 shows another embodiment of the present invention, and is a partially enlarged longitudinal sectional front view of the optical sheet with the height of each raised portion.
Fig. 7 shows another embodiment of the present invention, and is a partially enlarged longitudinal sectional front view of the optical sheet having raised the height of each ridge.
Fig. 8 shows another embodiment of the present invention, and is a partially enlarged longitudinal sectional front view of the optical sheet in which the longitudinal cross-sectional shape of each ridge is trapezoidal.
Fig. 9 shows another embodiment of the present invention, in which a partially enlarged longitudinal sectional front view of an optical sheet in which the arrangement order of the ridges of each set is irregularly shifted.
Fig. 10 shows another embodiment of the present invention, in which a partial enlarged longitudinal sectional front view of an optical sheet in which ridges of each set are dispersed and biased from side to side;
Fig. 11 shows another embodiment of the present invention, wherein a partial enlarged longitudinal sectional front view of an optical sheet in which the ridges of each set are dispersed and shifted left and right, and the arrangement order is irregularly different.
Fig. 12 shows another embodiment of the present invention, and is a partially enlarged longitudinal sectional front view of an optical sheet having two layers of resin sheets.
Fig. 13 shows another embodiment of the present invention, and is a partially enlarged longitudinal sectional front view of an optical sheet having three layers of resin sheets.
FIG. 14 is a graph showing an example of the present invention, showing a uniformity measured by changing the distance between the light source and the sheet in Table 2. FIG.
FIG. 15 shows an embodiment of the present invention, and is a graph showing luminance measured by changing the distance between the light source and the sheet in Table 2. FIG.
Fig. 16 shows a conventional example, in which a partially enlarged longitudinal sectional front view of an optical sheet in which a convex convex portion is arranged longitudinally and horizontally;
Fig. 17 shows a conventional example, and is a partially enlarged longitudinal sectional front view of an optical sheet in which convex portions of concave triangles in which low angles are changed are formed;
18 shows a conventional example, in which a partial enlarged longitudinal sectional front view of the optical sheet when the CCFL is shifted from the center position;

Best Mode for Carrying Out the Invention The best embodiment of the present invention will be described below with reference to Figs. In addition, in these drawings, the same number is attached | subjected to the structural member which has a function similar to the conventional example shown in FIGS. 16-18.

This embodiment demonstrates the backlight unit of the direct light system in a liquid crystal display, as shown in FIG. This backlight unit arranges the CCFL 2 of the linear type which installed the longitudinal direction in the front-back direction at the lower side (back side) of the optical sheet 1, arranged in parallel at right and left directions at equal intervals, Below these CCFL 2, the reflecting plate 3 for effectively utilizing the light radiate | emitted downward is arrange | positioned. And the liquid crystal panel 4 is arrange | positioned above this optical sheet 1 (front side). In addition, a diffusion sheet or the like may be disposed between the liquid crystal panel 4 above the optical sheet 1.

As shown in FIG. 2, the optical sheet 1 is made of a transparent resin sheet, and a lower surface on which light from the CCFL 2 is incident is parallel. In addition, the upper surface of this optical sheet 1 from which the light from CCFL 2 exits is a convex shape in which the longitudinal cross-sectional shape in the plane along the up, down, left, and right directions becomes an isosceles triangle, and the ridges 1a to 1c elongated in the front-rear direction Are arranged in large numbers in the left-right direction. In addition, these ridges 1a to 1c are sets in which a plurality of ridges 1a to 1c having different isosceles triangle lower angles are arranged in the region of the optical sheet 1 corresponding to each CCFL 2. (S) is arranged so that a plurality of sets are repeated.

In the case of this embodiment, one set S of the upper surface of the optical sheet 1 is the raised part 1a whose low angle (theta) ₁ is 55 degrees, and the low angle (theta) ₂ as shown in FIG. Each of the three ridges 1a to 1c of the ridge 1b having the angle of 45 ° and the ridge portion 1c having the low angle θ ₃ of 25 ° is arranged side by side from right to left. In addition, these ridges 1a to 1c have the same ridge width B as the length of the portion corresponding to the base of the isosceles triangle. Therefore, these ridges 1a to 1c have a raised portion 1c having the largest convex shape of the ridge 1a having the largest low angle θ ₁ protruding upwards and having the highest low angle θ ₃ . ), The convex shape is the lowest, and the convex shape of the ridge 1b having the intermediate low angle θ ₂ is the middle height.

Moreover, 2 or more and 10 or less are suitable, and, as for the number of ridge | bulb parts arranged as one set in this invention, More preferably, they are three or more and five or less. In addition, although the number of sets in the area | region of the optical sheet 1 corresponding to each CCFL 2 was shown in FIG. 2 in order to enlarge the convex shape of each ridge 1a-1c, and to make it easy to see, in fact, it is furthermore. It is preferred that multiple sets be arranged.

Here, the area | region of the optical sheet 1 corresponding to each CCFL 2 means the whole area | region of the optically effective part of the optical sheet 1, when there is one CCFL 2, and there are multiple CCFLs 2, When present, each region of the optically effective part of the optical sheet 1 divided into the plane orthogonal to the left-right direction which is exactly center of these CCFLs 2 is said. However, the boundary of the set of ridges 1a does not have to exactly coincide with the boundary of the area of the optical sheet 1, but on the inside of the left and right ends of the set and the inside of the left and right ends of the ridges 1a. There may be a boundary of the region of the optical sheet 1. Therefore, the number of sets in the area of the optical sheet 1 corresponding to each CCFL 2 does not necessarily need to be an integer.

According to the above configuration, in the vicinity of the position E ₀ immediately above the CCFL 2 shown in FIG. 2 in the optical sheet 1, as shown in FIG. 4A, the low angle of the light from the CCFL 2 is reduced. In the large ridge 1a and the ridge 1b, the total reflection is often increased, but the light emitted from the ridge 1c having the smallest low angle is almost upward. In addition, in the vicinity of the position E ₁ which is slightly moved to the left-right direction rather than directly above the CCFL 2 in the optical sheet 1, as shown in FIG. 4B, the low angle of the light from this CCFL 2 is the largest. In the ridge 1a and the ridge 1c which are the smallest, the light emitted from the ridge 1b having the intermediate angle is substantially upward. In addition, in the vicinity of the position E ₂ further distant in the left and right direction in the optical sheet 1, as shown in FIG. 4C, the ridge 1b and the ridge 1b having small low angles of the light from the CCFL 2. Although the base 1c is inclined in the left-right direction, the light emitted from the raised portion 1a having the largest bottom angle is almost upward. In addition, in FIG. 4, the refraction of incident light in the lower surface of the optical sheet 1 is abbreviate | omitted and shown.

Therefore, in the optical sheet 1 of this embodiment, since the set S which consists of three types of ridges 1a-1c in which the low angle of the isosceles triangle which is a convex longitudinal cross-sectional shape is different is repeatedly arranged in the upper surface, Even if the distance in the left-right direction from CCFL 2 differs, the light emitted from any of the ridges 1a to 1c in each set S is substantially upward. For this reason, since a gap can be prevented from occurring in accordance with the distance | distance from the CCFL 2 to the left-right direction, uniformity can be improved. In addition, since the lowering of the luminance can be reduced even at a position far away from the CCFL 2 in the left and right directions, the backlight unit can be made wider by increasing the interval distance of the CCFL 2 as long as it is possible to obtain the same level of uniformity as in the prior art. In addition, the number of CCFLs 2 used in the system can be reduced, and energy saving and cost can be reduced.

In addition, in the optical sheet 1 of this embodiment, since the set S in which the three types of ridges 1a to 1c are arranged is arranged on a plurality of upper surfaces, an arrangement position in the left and right directions of the CCFL 2 is arbitrary. In addition, the influence of the positional shift of the CCFL 2 is not eliminated, and the design change such as increase or decrease of the number of the CCFLs 2 can be easily coped with.

Moreover, in the optical sheet 1 of the said embodiment, although the case where the ridge width | variety B of the three types of ridge | bulbs 1a-1c of each set S was made constant was shown, as shown in FIG. Similarly, the ridge widths B ₁ to B ₃ of the ridges 1a to 1c may be different. In particular, as shown in Fig. 5, the larger the sum of the two inner angles of the bases of the convex longitudinal cross-sectional triangles in the ridges 1a to 1c, in other words, the larger the bottom angle of the isosceles triangles here. When the ridge widths B ₁ to B ₃ are made wider, the smaller the sharp vertices 1a to 1c of the isosceles triangles, the wider the ridge widths B ₁ to B ₃ , and thus the incident light can be received more. . Since the utilization rate of incident light decreases as the ridges 1a to 1c having small vertex angles decrease, the utilization rate of incident light in the three types of ridges 1a to 1c having different vertex angles can be made uniform, and a uniformity system is used. You can increase it.

Moreover, in the optical sheet 1 of the said embodiment, although the case where the height of the convex form of three types of ridges 1a-1c of each set S differed was shown, as shown in FIG. 6, a convex form The height may be equal. In this case, however, contrary to the case shown in Fig. 5, the vertex angle of the isosceles triangle becomes narrower as the ridge widths B ₁ to B ₃ of the small and sharp ridges 1a to 1c become narrower. There is a possibility that the luminance cannot be sufficiently obtained at a position where the distance in the left and right directions is far. Therefore, as shown in Fig. 7, the ridge widths of the ridges 1a to 1c are increased by moving upwards with respect to the ridge 1b or the ridge 1c having the low convex height. While (B) is constant, the height of a convex shape can also be arranged.

Moreover, in the optical sheet 1 of the said embodiment, although the low angles (theta) _1- theta ₃ of each ridge 1a-1c were 55 degrees, 45 degrees, and 25 degrees, they showed these low angles (theta). ₁ to θ ₃ may be different from each other, and thus the specific angle value is arbitrary. However, it is preferable that the maximum value of this low angle is 40 degrees or more and 70 degrees or less, It is more preferable in it being 50 degrees or more and 70 degrees or less, It is more preferable in it being 55 degrees or more and 60 degrees or less. When the maximum value of this low angle exceeds 60 degrees and becomes especially large beyond 70 degrees, when the ridge width | variety B of the ridges 1a-1c is made into sufficient width, the height of a convex-type will become high too much, and the optical sheet 1 ), The moldability worsens, and handling becomes difficult. If the maximum value of the low angle is smaller than 55 °, in particular smaller than 40 °, the difference between the low angles of the ridges 1a to 1c also becomes smaller, so that the effect of eliminating the luminance gap and improving the uniformity cannot be sufficiently obtained. .

Moreover, it is preferable that it is 25 degrees or less, and, as for the minimum value of this low angle, it is more preferable if it is 20 degrees or less. When the minimum value of this low angle exceeds 20 degrees and especially becomes large too much beyond 25 degrees, since the difference of the low angle of each ridge 1a-1c will also become small, the effect of eliminating a brightness gap and raising a uniformity will not be fully acquired. The minimum value of this low angle may be 0 degrees, and therefore the raised part of each set S may be a flat surface.

Moreover, in the optical sheet 1 of the said embodiment, although the longitudinal cross-sectional shape of the ridges 1a-1c was an isosceles triangle (or the shape based on this isosceles triangle), as shown in FIG. The tops of these isosceles triangles may be shaped like trapezoids cut horizontally. In addition, a long-term horse-shaped pentagon in which an isosceles triangle with a small low angle is placed on the cut-out top may be used, or a polygon with a hexagon or more may be used.

Moreover, in the optical sheet 1 of the said embodiment, although the each corner part in the triangle shape etc. of the longitudinal cross-sectional shape of the ridge | bulbs 1a-1c was shown the state which was a pointed state, in reality, each corner part is somewhat for the convenience of manufacture. It may be in a dull state or a rounded state, and may be chamfered. In this embodiment, it is important that each set includes a plurality of raised portions 1a to 1c each having inclined surfaces having different shapes, that is, different angles, and the state of details of the horn portion which is the boundary portion where these inclined surfaces contact each other. Is not important.

Moreover, in the optical sheet 1 of the said embodiment, although the case where the three types of ridges 1a-1c of each set S were arranged in the same order was shown, the number of sets on the optical sheet 1 is sufficient. Since this arrangement order does not affect the effect of this invention in many cases, as shown in FIG. 9, this arrangement order may differ for every set S, and it is preferable that the difference of arrangement orders in this case is irregular.

Moreover, in the optical sheet 1 of the said embodiment, although the case where three types of ridges 1a-1c were arranged in each set S, four or more types of ridges may be arranged. Moreover, even if only two types of ridges are arranged, the effect of this invention can be expected to some extent especially if a longitudinal cross-sectional shape is a polygon more than square.

Moreover, in the optical sheet 1 of the said embodiment, although the case where the longitudinal cross-sectional shape of the protruding parts 1a-1c is a bilaterally equilateral isosceles triangle and a square or more polygon is shown, it is not necessarily limited to the shape of left-right symmetry. However, in order to exhibit the characteristic that the optical sheet 1 does not depend on the position of the left-right direction of the CCFL 2, it is unpreferable that the shape of right and left asymmetry is excessively biased to the right direction or the left direction, and when this bias is too large In the optical sheet 1 as a whole, there is a possibility that a luminance gap may occur depending on the distance from the CCFL 2. Therefore, even if there are some left and right asymmetry in the longitudinal cross-sectional shape of each of the ridges 1a to 1c, all the ridges 1a to 1c of each set S can be obtained by quantifying the degree of bias and making the left and right directions right. It is preferable to disperse | distribute and average it as closely as possible to O as the sum total of ()) is summed. That is, as shown in FIG. 10, if there are five types of ridges 1a to 1e in each set S, for example, the ridges 1a and 1e are biased by a certain amount in the left direction, for example. (1c) is symmetrical with no bias, and it is preferable that the bias is dispersed and averaged as if the ridges 1b and 1d are biased by a certain amount in the right direction. 11 shows a case where the arrangement order of these five types of ridges 1a to 1e differ from each other in the adjacent set S. As shown in FIG.

Moreover, in the optical sheet 1 of the said embodiment, although the case where the convex ridge part was formed was shown, the effect of this invention can be acquired similarly, even if the recessed groove part is formed in an arrangement. In this case, the concave longitudinal cross-sectional shape can use arbitrarily what reversed the vertical direction of the longitudinal cross-sectional shape in the case of the said convex type.

Moreover, in the optical sheet 1 of the said embodiment, although the case where the lower surface was flat was shown, the structure of the lower surface of this optical sheet 1 is arbitrary, for example, it diffuses light by processing into the wrinkle shape which consists of fine unevenness | corrugation, for example. The improvement may be sufficient.

Moreover, in the optical sheet 1 of the said embodiment, although the case where this optical sheet 1 consists of a transparent resin sheet was shown, it is not necessary to be transparent, since it should just be a thing which has light transmissivity which permeate | transmits light. The thickness of the optical sheet 1 is not specifically limited, either, Usually, about 0.3-5 mm in thickness is used suitably.

As the resin sheet of the optical sheet 1 as described above, polycarbonate, polyester, polyethylene, polypropylene, polyolefin copolymer (for example, poly-4-methylpentene-1, etc.), polyvinyl chloride, cyclic polyolefin (example For example, the thing which consists of translucent thermoplastic resins, such as a norbornene structure), an acrylic resin, a polystyrene, an ionomer, a styrene methyl methacrylate copolymer resin (MS resin), can be used. In particular, among the resin sheets made of thermoplastic resins, those made of polycarbonate, polyester (particularly polyethylene terephthalate), and cyclic polyolefin have good heat resistance and are deformed due to heat dissipation from the CCFL 2 when used in a backlight unit. Since wrinkles hardly occur, they are preferably used. Moreover, since the polycarbonate itself is resin with favorable transparency, since the polycarbonate itself is a resin with little hygroscopicity, high brightness, and little curvature, it is used very favorably. Moreover, this resin sheet may consist of translucent thermoplastic resins, such as unsaturated polyester and an epoxy resin. In addition, this resin sheet can also mix and alloy 2 or more types of resin materials, and can use the compounded thing.

Moreover, although the optical sheet 1 of the said embodiment can be produced using the press manufacturing method which presses and forms the resin sheet which is flat on both surfaces, for example, it is another press manufacturing method, casting method, etc., or injection molding method, You may produce by arbitrary manufacturing methods, such as the continuous shaping | molding method by a roll shaping | molding method, an extrusion shaping | molding method, etc. by passing through the shaping | molding method and a die roll.

Moreover, the resin sheet of the optical sheet 1 of the said embodiment may suitably contain the stabilizer, the lubricating agent, the impact resistance improving agent, the antioxidant, the ultraviolet absorber, the light stabilizer, the antistatic agent, the coloring agent, the fluorescent brightener, and the like necessary for molding. Moreover, in the optical sheet 1 which has a multilayered structure, these additives may change suitably the kind and compounding ratio of an additive between a base material layer and a surface layer, for example. FIG. 12 shows an example of two layers of optical sheets 1 in which convex ridges are arranged in the surface layer 12 of the upper layer of the base layer 11, and FIG. 13 shows the back layer 13 in these lower layers. An example of the three-layer optical sheet 1 which added) is shown. Since the ultraviolet ray is directly irradiated from the CCFL 2 on the lower surface of the optical sheet 1, the back layer 13 is a weatherproof layer containing an ultraviolet absorber. The upper base layer 11 and the surface layer 12 Can be protected from ultraviolet rays.

In addition, the resin sheet of the optical sheet 1 of the above embodiment may contain a light diffusing agent. As this light diffusing agent, inorganic particles, metal oxide particles, organic polymer particles, and the like, which differ in light refractive index from the resin material of the resin sheet, are used alone or in combination as appropriate. Examples of the inorganic particles include glass [A glass (soda lime glass), C glass (borosilicate glass), E glass (low alkali glass)], silica, mica, synthetic mica, calcium carbonate, magnesium carbonate, barium sulfate, talc, montmorillonite, Particles such as kaolin clay, bentonite, hectorite, silicon and the like are used. As the metal oxide, particles such as titanium oxide, zinc oxide, and alumina are used, and as organic polymer particles, particles such as acrylic beads, styrene beads, and benzoguanamine are used. When such a light diffusing agent is contained, the light can be sufficiently diffused in the optical sheet 1, thereby eliminating the need to use an expensive diffusion sheet or the like in the backlight unit.

The light diffusing agent has an average particle diameter of 0.1 to 100 µm, preferably 0.5 to 50 µm, and more preferably 1 to 30 µm. Since the light diffusing agent having a particle size smaller than 0.1 m is easy to aggregate, the dispersibility is poor. Even if the light diffusing agent can be uniformly dispersed, the light scattering efficiency is poor because the wavelength of light is large. Therefore, the particle | grains of the size of 0.5 micrometer or more and 1 micrometer or more are preferable. On the other hand, the light diffusing agent having a particle size larger than 100 µm causes light scattering to be uneven, light transmittance is lowered, or particles are visible. For this reason, the particle | grains of 50 micrometers or less, especially the particle | grains of 30 micrometers or less are preferable.

Moreover, in the optical sheet 1 of the said embodiment, although the case where this optical sheet 1 was a resin sheet was shown, what is necessary is just a translucent sheet (including a thin plate), and thin glass etc. may be sufficient as it.

Moreover, although the case where the linear CCFL 2 was used as a light source was shown in the backlight unit of the said embodiment, it does not necessarily need to be a linear type, for example, a U-shaped tube etc. can also be used. In addition, the CCFL 2 does not necessarily need to be used, and a heat cathode tube or the like such as a fluorescent tube for general lighting may be used, or an LED (light emitting diode) may be used in a line, and the type of light source is not limited. Moreover, the reflecting plate 3 is also not essential, for example, it is also possible to arrange | position another optical sheet 1 under the CCFL 2 of the said embodiment, and to supply light to both top and bottom.

Moreover, although the backlight unit of the said embodiment showed the case where the liquid crystal panel 4 was arrange | positioned directly above the optical sheet 1, the diffusion sheet etc. are provided above and / or below this optical sheet 1, respectively. You can also place it. Moreover, the backlight unit of the said embodiment can also be used as backlights other than the liquid crystal panel 4.

Example

Examples 1-4 of the optical sheet 1 shown by the said embodiment, and Comparative Examples 1-2 of the optical sheet 1 shown by the conventional example were produced. And the result of having measured the brightness and uniformity of the backlight unit using these optical sheets 1 is shown in Table 1.

Here, in Embodiment 1, as shown in Figs. 2 to 4, three types of raised portions having an isosceles triangle longitudinal section shape of 55 °, 45 °, and 25 °, are formed on the upper surface, and the lower surface is flat. It is an optical sheet 1, and Example 2 is the optical sheet 1 which processed the lower surface of the optical sheet 1 of this Example 1 into the wrinkle shape (25 micrometers unevenness | corrugation), and Example 3, An optical sheet (1) in which five types of raised portions having an isosceles triangular longitudinal section of 55 °, 45 °, 35 °, 25 °, and 10 ° are arranged on the upper surface, and the lower surface is flat. Is an optical sheet 1 in which three types of ridges having a longitudinal cross-sectional shape of an isosceles triangle having a bottom angle of 40 °, 25 °, and 10 ° are arranged on the upper surface, and the lower surface is flat. Moreover, the comparative example 1 is the optical sheet 1 which formed only the ridge part which has the longitudinal cross-sectional shape of the isosceles triangle whose bottom angle is 45 degrees on the upper surface, and made the lower surface flat. Moreover, the comparative example 2 is an optical sheet 1 in which only the ridge part which has the longitudinal cross-sectional shape of the isosceles triangle whose bottom angle is 25 degrees is arranged in the upper surface, and the lower surface is flat.

In the optical sheets 1 of Examples 1 to 4 and Comparative Examples 1 to 2, both the ridge widths of the ridges were 200 µm, and all the diffusing agents were not contained. Moreover, the backlight unit using these optical sheets 1 sets the distance between light sources which are the distance distance of several CCFL2 to 24 mm, and starts each optical sheet 1 from each CCFL (2: the center of a discharge tube). The distance between the light source and the sheet | seat which is the distance to ()) is 14.5 mm.

The measurement of the brightness | luminance and the uniformity of the optical sheet 1 was measured in the environment of 23 degreeC of room temperature, and 50% RH humidity using the color luminance meter BM-7 by Topcon Corporation. In addition, the brightness | luminance of Table 1 represents the average value of the brightness | luminance measured at the measurement point of nine points in total between the directly above CCFL2 and CCFL2. In addition, the uniformity system of Table 1 shows the ratio of the value of the lowest brightness | luminance to the value of the highest brightness | luminance among the luminance measured by each of these measurement points.

As is clear from Table 1, the luminance of Examples 1 to 4 is somewhat lower than that of Comparative Example 1, but the luminance of Examples 1 to 4 is almost the same as that of Comparative Example 2, or It is slightly higher than that, and furthermore, it can be seen that the bactericides of Examples 1 to 4 are considerably higher than those of Comparative Examples 1-2.

In Examples 1 to 4 and Comparative Examples 1 to 2, the case where the ridge widths of the ridges of the optical sheet 1 were all set to 20 [mu] m, but as the bottom angle of the isosceles triangle became larger, the ridge widths became wider. The Example of the sheet | seat 1 was also produced. And the result of having measured the brightness and uniformity at the time of changing the distance between a light source and a sheet about the backlight unit using these optical sheets 1 is shown in Table 2.

Here, the same optical sheet 1 is used for the backlight units of Examples 5 to 8, the same optical sheet 1 is used for the backlight units of Examples 9 to 12, and the same for the backlight units of Comparative Examples 3 to 6, The optical sheet 1 is used. Further, the optical sheet 1 used in Examples 5 to 8 and Examples 9 to 12 has three types of raised portions having an isosceles triangular longitudinal section shape having a low angle of 60 °, 45 ° and 20 ° on an upper surface thereof. It is. However, as for the optical sheet 1 used for Examples 9-12, the ridge width | variety of the ridge of a ridge of 60 degrees of low angles is 400 micrometers, and the ridge width of the ridge of a ridge of 45 degrees of low angles is 200 micrometers, and the ridge of 20 degrees of low angles. The ridge width is 100 µm. On the other hand, the optical sheet 1 used for Examples 5-8 is 200 micrometers in all the ridge width | variety of each ridge part similarly to Examples 1-4 shown in Table 1. Not using the optical sheet 1 of Examples 1-4 in Examples 5-8, it is necessary to arrange the shape of a ridge for comparison with the optical sheet 1 used for Examples 9-12. Because. The optical sheet 1 used for Comparative Examples 3-6 is a ridge part which has an isosceles triangle-shaped longitudinal cross-section with an angle of 25 degrees on the upper surface, and made the ridge width of each ridge part 200 micrometers, and is shown in Table 1 It is the same as the optical sheet 1 of the comparative example 2.

As for the optical sheet 1 used for the said Example 5-8, Examples 9-12, and Comparative Examples 3-6, all of the lower surfaces were flat, and neither contained the diffusing agent. In the backlight unit using these optical sheets 1, the distance between the light sources of the plurality of CCFLs 2 is 24 mm. However, in Example 5-8, Examples 9-12, and Comparative Examples 3-6, the distance between a light source and a sheet is changed to 14.5 mm, 6 mm, 5 mm, and 4 mm, respectively. Therefore, since the distance between a light source and a sheet becomes 14.5 mm, the comparative example 3 is the same as the measurement conditions of the optical sheet 1 of the comparative example 2 shown in Table 1. As shown in FIG. The measuring apparatus, measurement environment, and measurement conditions used for the measurement of these Examples 5-8, Examples 9-12, and Comparative Examples 3-6 are the same as the case of Table 1.

In this Table 2, in each of Examples 5 to 8, Examples 9 to 12, and Comparative Examples 3 to 6, the uniformity measured by changing the distance between the light source and the sheet is shown in FIG. 14, and the distance between the light source and the sheet is shown. The luminance measured by the change is shown in FIG.

As is clear from Table 2 and Fig. 15, luminance is almost inferior to Comparative Examples 3 to 6 in Examples 5 to 8 and Examples 9 to 12 at any distance between the light sources and the sheets. When the distance between sheets is long, Examples 5-8 and Examples 9-12 are exceeding Comparative Examples 3-6. In addition, as is clear from Table 2 and Fig. 14, in any distance between the light source and the sheet, the leveling agent is considerably higher in Examples 5 to 8 and Examples 9 to 12 than in Comparative Examples 3 to 6.

In addition, in Examples 5 to 8, as the distance between the light source and the sheet becomes shorter from 14.5 mm to 6 mm, 5 mm, and 4 mm, the leveling agent also decreases significantly. In Examples 9 to 12, the light source. It can be seen that the leveling agent maintains a high level not only when the distance is 14.5 mm but also when 6 mm or 5 mm. In the case of Comparative Examples 3 to 6, when the distance between the light source and the sheet is shortened from 14.5 mm to 6 mm, 5 mm, and 4 mm, the homogenizer that is not very high is further lowered and practically sufficient homogenizer cannot be obtained. The distance between the light source and the sheet was generally about 14 to 20 mm. However, in Examples 9 to 12 using the optical sheet 1 in which the ridge width of the bulge spreads as the bottom angle increases, the distance between the light source and the sheet can be made shorter than before. You can contribute.

However, also in Examples 9 to 12, when the distance between the light source and the sheet is shortened to 4 mm, the uniformity is sharply lowered, so the distance between the light source and the sheet is preferably 5 mm or more. In addition, when the distance between the light source and the sheet is shortened in this way, the optical sheet 1 is more susceptible to the influence of heat radiation from the CCFL 2, and thus the optical sheet 1 is made of polycarbonate having particularly high heat resistance. It is preferable to use the resin sheet which consists of.

Industrial availability

In the optical sheet of the present invention and the backlight unit using the same, a plurality of convex ridges and concave groove portions having different shapes are repeatedly arranged on the surface, thereby eliminating the luminance gap according to the distance from the line light source. Moreover, since it can be made not to depend also on the arrangement position of this line light source, it becomes extremely useful when used as backlights, such as a liquid crystal panel.

1: optical sheet
1a to 1e: ridge
11: base layer
12: surface layer
13: back layer
2: CCFL
3: reflector
4: liquid crystal panel
B: ridge width
S: set

Claims (10)

An optical sheet for use in a direct light type backlight unit, comprising: an optical sheet in which a plurality of convex ridges or concave grooves are arranged on the surface of the light-transmitting sheet on the side from which light is emitted;
These ridges or grooves in the region of the optical sheet corresponding to each line light source are arranged by repeating a plurality of sets of arrangements of a plurality of ridges or grooves of different shapes. 2. The optical sheet according to claim 1, wherein the order of the arrangement of the ridges or groove portions in which the shapes in the sets are different is different. The optical sheet according to claim 1 or 2, wherein the shape of each ridge or groove is symmetrical about a plane orthogonal to the array direction. The optical sheet according to any one of claims 1 to 3, wherein the ridge widths or groove widths of the ridges or groove portions having different shapes in the sets are different from each other. The longitudinal cross-sectional shape orthogonal to the ridge length or groove length of each of the ridges or grooves is a triangular shape with both inner angles of less than 90 °, the optical sheet according to any one of claims 1 to 4. . The longitudinal cross-sectional shape orthogonal to the ridge length or the groove length of each of the ridges or grooves is an isosceles triangle, and the difference between the shapes of the ridges or the grooves in the respective sets is the bottom angle of the isosceles triangle. The optical sheet, characterized in that the upper. The ridges or grooves of different shapes in the above-mentioned sets are each of the two inner corners of the triangular base of the longitudinal cross section perpendicular to the ridge length or groove length of these ridges or groove portions. The larger the sum, the wider the ridge width or groove width of these ridges or grooves. The longitudinal cross-sectional shape orthogonal to the ridge length or the groove length of each of the ridges or the grooves is a polygon or the like, or a semi-circular arc whose base angle is 90 ° or less. It is the following circular arc shape, The optical sheet characterized by the above-mentioned. The optical sheet according to any one of claims 1 to 8, wherein two or more ridges or groove portions of two or more and ten or less are arranged in each of the sets. The optical sheet in any one of Claims 1-9 was arrange | positioned at the front side of one or more linear light sources, The backlight unit using the optical sheet characterized by the above-mentioned.

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