Abstract:
The present invention is to provide a solution for fabricating a light diffusing sheet-like device capable of emitting light with superior brightness, that is a high brightness diffuser. The high brightness diffuser mainly comprises at least two light diffusing pieces with ridge-shape structure arranged thereon, which can be either convex or concave. The convex ridge-shape structure is consisted of a plurality of large convex ridges and a plurality of small convex ridges, which are associated with a ridgeline existing in between two adjacent ridges where the large ridge and small ridge are interlace-arranged, and the ridges along with the associated ridgelines can be longitudinally extended to the same direction. Likewise, The concave ridge-shape structure is constituted the same way as the convex ridge-shape structure is, but is consisted of concave ridges. The high brightness diffuser is fabricated by stacking up the two light diffusing pieces and enabling an included angle to be formed between the two ridge-extending directions of the two light diffusing pieces. Through the embodiment of the present invention, a high brightness diffuser with reduced thickness capable of emitting light of superior brightness and of wide-angle uniformity can be fabricated, and thus can be applied in a rear projection module.

Description:
1. FIELD OF THE INVENTION  
       [0001]     This invention relates to a kind of sheet-like light diffusing device, capable of emitting light of superior brightness, that is, a high brightness diffuser, and more particularly to a high brightness diffuser consisted of at least two overlapping light diffusing pieces with ridge-shape structure arranged thereon.  
       2. BACKGROUND OF THE INVENTION  
       [0002]     Light diffusers adopted in an ordinary large-scale display (e.g. rear projection screen and large-scale liquid crystal display) are commonly located at the outmost layer of the screen, thereby enabling the light emitted with good output brightness and wide-angle uniformity.  
         [0003]      FIG. 1  shows the photometric performance pertaining to various kinds of similar products available in the current market. Curve A in  FIG. 1  represents the photometric performance of the light diffuser disclosed in U.S. Pat. No. 6,327,083, “REAR PROJECTION SCREEN WITH REDUCED SPECKLE”, curves B and C respectively represents the photometric performance of two different conventional light diffusers, and curve D represents the photometric performance of a rear projection light diffuser. As seen in  FIG. 1  that the foregoing diffuser can only provide a good photometric performance within the 60° front viewing angle at the audience side of the projection screen, whereas the brightness outside the 60° front viewing angle is considerably reduced. Consequently, the viewer sitting in front of the screen would experience a great brightness disparity when his viewing cover wide side angles. Therefore, the large-scale display screen fabricated by the prior art technique is unable to deliver a uniform illuminance required by the wide-angle viewing.  
         [0004]     In addition, for those light diffusers fabricated by the prior art techniques, thick structure of approximately 1 mm is normally needed to boost the light diffusion efficiency when they are used in the large-scale display screen. The design as such would either reduce the brightness output or fail to meet the aforementioned requirement for wide-angle viewing. If the thickness of the light diffusing sheet member can be made thinner, said element can be used in the modern rear projection module.  
         [0005]      FIG. 2  represents a schematic drawing of the diffuser disclosed in the U.S. Pat. No. 6,327,083. As seen in  FIG. 1 , the diffuser  40  is made up of a front lenticular lens array  40   a  having unique microstructure design, a bulk region  48 , and a clear region  49 . The lenticular lens array  40   a  is composed of a plurality of concave elements  42  and convex elements  44  aligned orderly, wherein the concave element  42  is filled with light diffusing particles  46 . Close examination at the structure of concave element reveals a depression of concave shape  441  and a wavy contour of varying flatness. The drawback of aforementioned invention is that the lenticules array  40   a  designed as such would require fabrication technologies involving semiconductor manufacturing and various sophisticated mechanical processing techniques, thus resulting in poor manufacturability and high manufacturing cost. Furthermore, despite having the advantage of being able to reduce the speckle patterns, as is claimed in this prior art, the aforementioned diffusion means is incapable of emitting light with superior brightness and good wide-angle uniformity.  
       SUMMARY OF THE INVENTION  
       [0006]     In light of the drawback associated with the prior art, the primary object of the present invention is to provide a high brightness diffuser consisted of at least two overlapping light diffusing pieces with ridge-shape structure arranged thereon, so that the high brightness diffuser with reduced thickness capable of emitting light of superior brightness and of wide-angle uniformity can be fabricated, and thus can be applied in a rear projection module.  
         [0007]     The secondary object of the present invention is to provide a solution for fabricating a high brightness diffuser comprising at least two light diffusing sheets, and each light diffusing sheet further comprising a substrate, a ridge-shaped layer and a diffusion layer, wherein the diffusion layer includes a transparent region and numerous light-diffusing particles uniformly dispersed inside the transparent region, and the substrate having a rugged external surface is sandwiched in between the ridge-shaped layer and the diffusion layer. Alternatively, the diffusion layer is placed in between the ridge-shaped layer and the substrate and the transparent region of the diffusion layer has a rugged surface facing toward the ridge-shaped layer. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0008]      FIG. 1  is the photometric performance of various light diffusers.  
         [0009]      FIG. 2  is a schematic diagram illustrating a conventional diffuser.  
         [0010]      FIG. 3  is a 3D diagram of the convex diffusing piece according to the present invention.  
         [0011]      FIG. 4  is a 3D diagram of the concave diffusing piece according to the present invention.  
         [0012]      FIG. 5  is a 3D diagram depicting the compound light diffuser that is formed by combining the convex diffusing piece of  FIG. 3  and the concave diffusing piece of  FIG. 4 .  
         [0013]      FIG. 5A  is the A-A sectional view of  FIG. 5 .  
         [0014]      FIG. 6  is a 3D diagram depicting the compound light diffuser that is formed by stacking two convex diffusing piece of  FIG. 3 .  
         [0015]      FIG. 6A  is the A-A sectional view of  FIG. 6 .  
         [0016]      FIG. 7  is a 3D diagram of the convex diffusing piece according to another embodiment of the present invention.  
         [0017]      FIG. 8  is a 3D diagram of the concave diffusing piece according to another embodiment of the present invention.  
         [0018]      FIG. 9  is a 3D diagram depicting the compound light diffuser that is formed by combining the convex diffusing piece of  FIG. 7  and the concave diffusing piece of  FIG. 8 .  
         [0019]      FIG. 9A  is the A-A sectional view of  FIG. 9 .  
         [0020]      FIG. 10  is a 3D diagram depicting the compound light diffuser that is formed by stacking two convex diffusing piece of  FIG. 7 .  
         [0021]      FIG. 10A  is the A-A sectional view of  FIG. 10 .  
         [0022]      FIG. 11  is the photometric performance of the light diffusers embodying the present invention as represented in  FIGS. 5 and 6  and those embodying the prior art. 
     
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT  
       [0023]     For your esteemed members of reviewing committee to further understand and recognize the fulfilled functions and structural characteristics of the invention, several preferable embodiments cooperating with detailed description are presented as the follows.  
         [0024]      FIG. 3  shows a convex diffusing piece according to the present invention. The convex diffusing piece  10  comprises a substrate  11 , a ridge-shaped layer  12  and a diffusion layer  13 . The substrate  11 , ridge-shaped layer  12  and diffusion layer  13  all are transparent. As seen in  FIG. 3 , the substrate is sandwiched in between and the diffusion layer  13  and the ridge-shaped layer  12 . The ridge-shaped layer  12  has a plurality of large convex ridges  121  and small convex ridges arranged thereon where the large convex ridges  121  is disposed immediately next to its smaller counterpart  122 , and all of these ridges are parallel to the X-axis as shown in  FIG. 3 . The large convex ridges  121  has a ridgeline  1211  associated with it. With an inter-ridge distance being defined as the distance between the ridgelines of the two adjacent large ridges, and a ridge height being defined as the difference of altitude between the ridgeline and the line separating the large ridge and the small ridge, the inter-ridge distances are equal to each other and the ridge heights are equal to each other. In addition, the small convex ridges  122  has a ridgeline  1221  associated with it. With an inter-ridge distance being defined as the distance between the ridgelines of the two adjacent small ridges, and a ridge height being defined as the difference of altitude between the ridgeline and the line separating the large ridge and the small ridge, the inter-ridge distances are equal to each other and the ridge heights are equal to each other. The diffusion layer  13  is made up with a transparent thin layer  131  and numerous light-diffusing particles  132 , which are uniformly dispersed within the transparent layer  131 . One side of said transparent layer has a rugged surface, and the sizes of the diffusion particles  132  may range from several tens of nanometers to several units of micrometers. The light-diffusing particles  132  may have the shapes that include but not limited to sphere, oval, cylinder or other polyhedrons. In order to reduce the amount of light absorbed during diffusion, the chemical composition of the light diffusion particles  132  may include those materials having zero extinction coefficient substantially equal to zero, such as TiO 2 , SiO 2 , BaSO 4 , MgO 2  or ZnS.  
         [0025]      FIG. 4  shows a concave diffusing piece according to the present invention. The concave diffusing piece  20  comprises a substrate  21 , a ridge-shaped layer  22  and a diffusion layer  23 . The substrate  21 , ridge-shaped layer  22  and diffusion layer  23  all are transparent. As seen in  FIG. 4 , the substrate  21  is sandwiched in between the ridge-shaped layer  22  and the diffusion layer  23 . The ridge-shaped layer  22  has a plurality of concave ridges  221  arranged thereon. Between every two concave ridge, there has a ridgeline  2211 . With an inter-ridge distance being defined as the distance between the ridgelines  2211  of the two adjacent concave ridges, and a ridge height being defined as the difference of altitude between the ridgeline and the line separating the large ridge and the small ridge, the inter-ridge distances are equal to each other and the ridge heights are equal to each other. Each concave ridge along with its ridgeline have an extension line parallel to the X′-axis, where the X′-axis and aforementioned X-axis makes an included angle of 45°. The diffusion layer  23  is composed with the thin transparent layer  231  and the light-diffusing particles  232  uniformly dispersed within the transparent layer  231 . The transparent layer  231  has a rugged surface, and the sizes of the diffusion particles  232  may range from several tens of nanometers to several units of micrometers. The light diffusing particles  232  may have the shapes that include but not limited to spheres, ovals, cylinders or other polyhedrons. In order to reduce the amount of light absorbed during diffusion, the chemical composition of the light diffusion particles  232  may include those materials having zero extinction coefficient zero, such as TiO 2 , SiO 2 , BaSO 4 , MgO 2  or ZnS.  
         [0026]     Please refer to  FIG. 5  and  FIG. 5A , where the convex light diffusing piece  10  is laid intimately over the top of the concave light diffusing piece  20 . The convex light diffusion piece  10  and the concave light diffusing piece  20  are joined together such that the rugged surface of the diffusion layer  13  faces upward and the side with the convex ridges associated with the ridge-shaped layer  12  faces downward. The inter-ridge distance of the two adjacent large ridges  121  is 60 nanometers and its ridge&#39;s height is 25 nanometers. The inter-ridge distance of two adjacent small ridges  122  is 60 nanometers and its ridge&#39;s height is 10 nanometers. Moreover, the convex ridges extend longitudinally parallel to the X-axis direction as shown in  FIG. 5 . The substrate  11  is 100 nanometers thick. Furthermore, the rugged surface of the diffusion layer  23  of the concave light diffusing piece  20  face upward, while the concave ridges  221  associated with the ridge-shaped layer  22  faces downward. The inter-ridge distance of two adjacent concave ridges is 60 nanometers and the ridge&#39;s height is 20 nanometers. Each concave ridge is extended parallel to the X′-axis, where X′-axis and X-axis makes a included angle of 45°. The substrate  21  is 100 nanometers thick.  
         [0027]     The convex light diffusing piece  10  and the concave light diffusing piece  20  can be joined onto each other intimately, thereby forming a high brightness diffuser. To facilitate joining the convex light diffusing piece  10  onto the concave light diffusing piece  20  with no joining material used, static electricity can be applied onto the rugged surface associated with the diffusion layer  23  such that the joining of the convex light diffusing piece  10  and the concave light diffusing piece  20  can be accomplished in a vacuum environment.  
         [0028]     Another embodiment of the present invention is shown in  FIGS. 6 and 6 A, wherein two convex light diffusing pieces  10  and  10   a  are paired up to form another high brightness diffuser. The two convex diffusing pieces  10  and  10   a  are joined together with one piece laid intimately over the top of the other. The convex light diffusing pieces  10  and  10   a  are configured such that the rugged surface of the diffusion layer  13  of the convex light diffusing piece  10  located at the upper deck faces upward and the ridges associated with the ridge-shaped layer  12  faces downward. The inter-ridge distance of the two adjacent large ridges  121  is 60 nanometers and its ridge&#39;s height is 25 nanometers, whereas the inter-ridge distance of two adjacent small ridges  122  is 60 nanometers and its ridge&#39;s height is 10 nanometers. Moreover, both the large ridges  121  and the small ridges  122  extend longitudinally in the X-axis direction. The substrate  11   a  is 100 nanometers thick. The rugged surface associated with the diffusion layer  13   a  of the convex light diffusing piece  10   a  located at the lower deck faces upward, whereas the ridges associated with the ridge-shaped layer  12   a  faces downward. The inter-ridge distance is 60 nanometers and the ridge&#39;s height is 20 nanometers. The substrate  11   a  is 100 nanometers thick. The present embodiment has the characteristics that the large ridges  121   a  of the lowest layer of this light diffusing piece  10   a  and their associated longitudinal extension lines are parallel to the X′ direction, where X′-axis and X-axis makes an included angle of 8.5°.  
         [0029]     An intimate joining of two light diffusion pieces  10  and  10   a  can form a light diffuser capable of emitting light of superior brightness. The intimate joining can be accomplished through the application of static electricity on the rugged surface  13   a  in a vacuum environment, using no joining materials.  
         [0030]      FIG. 7  shows another convex diffusing piece according to the present invention. The convex diffusing piece  10   bb  comprises a substrate  11 , a ridge-shaped layer  12   b  and a diffusion layer  13   b . The substrate  11   b , ridge-shaped layer  12   b  and diffusion layer  13   b  all are transparent. As seen in  FIG. 7 , the diffusion layer  13   b  is sandwiched in between the substrate  11  and the ridge-shaped layer  12   b . The ridge-shaped layer  12   b  has a plurality of large convex ridges  121   b  and small convex ridges arranged thereon where the large convex ridges  121   b  is disposed immediately next to its smaller counterpart  122   b , and all of these ridges are parallel to the X-axis as shown in  FIG. 7 . The large convex ridges  121   b  has a ridgeline  1211   b  associated with it. With an inter-ridge distance being defined as the distance between the ridgelines of the two adjacent large ridges, and a ridge height being defined as the difference of altitude between the ridgeline and the line separating the large ridge and the small ridge, the inter-ridge distances are equal to each other and the ridge heights are equal to each other. In addition, the small convex ridges  122   b  has a ridgeline  1221   b  associated with it. With an inter-ridge distance being defined as the distance between the ridgelines of the two adjacent small ridges, and a ridge height being defined as the difference of altitude between the ridgeline and the line separating the large ridge and the small ridge, the inter-ridge distances are equal to each other and the ridge heights are equal to each other. The diffusion layer  13   b  is made up with a transparent thin layer  131   b  and numerous light-diffusing particles  132   b , which are uniformly dispersed within the transparent layer  131   b . One side of said transparent layer has a rugged surface, and the sizes of the diffusion particles  132   b  may range from several tens of nanometers to several units of micrometers. The light-diffusing particles  132   b  may have the shapes that include but not limited to sphere, oval, cylinder or other polyhedrons. In order to reduce the amount of light absorbed during diffusion, the chemical composition of the light diffusion particles  132   b  may include those materials having zero extinction coefficient substantially equal to zero, such as TiO 2 , SiO 2 , BaSO 4 , MgO 2  or ZnS.  
         [0031]      FIG. 8  shows a concave diffusing piece according to the present invention. The concave diffusing piece  20   b  comprises a substrate  21   b , a ridge-shaped layer  22   b  and a diffusion layer  23   b . The substrate  21   b , ridge-shaped layer  22   b  and diffusion layer  23   b  all are transparent. As seen in  FIG. 8 , the diffusion layer  23   b  is sandwiched in between the substrate  21   b  and the ridge-shaped layer  22   b . The ridge-shaped layer  22   b  has a plurality of concave ridges  221   b  arranged thereon. Between every two concave ridge, there has a ridgeline  2211   b . With an inter-ridge distance being defined as the distance between the ridgelines  2211   b  of the two adjacent concave ridges, and a ridge height being defined as the difference of altitude between the ridgeline and the line separating the large ridge and the small ridge, the inter-ridge distances are equal to each other and the ridge heights are equal to each other. Each concave ridge along with its ridgeline have an extension line parallel to the X′-axis, where the X′-axis and aforementioned X-axis makes an included angle of 45°. The diffusion layer  23   b  is composed with the thin transparent layer  231   b  and the light-diffusing particles  232   b  uniformly dispersed within the transparent layer  231   b . The transparent layer  231   b  has a rugged surface, and the sizes of the diffusion particles  232   b  may range from several tens of nanometers to several units of micrometers. The light diffusing particles  232   b  may have the shapes that include but not limited to spheres, ovals, cylinders or other polyhedrons. In order to reduce the amount of light absorbed during diffusion, the chemical composition of the light diffusion particles  232   b  may include those materials having zero extinction coefficient zero, such as TiO 2 , SiO 2 , BaSO 4 , MgO 2  or ZnS.  
         [0032]     Please refer to  FIG. 9  and  FIG. 9A , where the convex light diffusing piece  10   b  is laid intimately over the top of the concave light diffusing piece  20   b . The convex light diffusion piece  10   b  and the concave light diffusing piece  20   b  are joined together such that the rugged surface of the diffusion layer  13   b  faces upward and the side with the convex ridges associated with the ridge-shaped layer  12   b  faces downward. The inter-ridge distance of the two adjacent large ridges  121   b  is 60 nanometers and its ridge&#39;s height is 25 nanometers. The inter-ridge distance of two adjacent small ridges  122   b  is 60 nanometers and its ridge&#39;s height is 10 nanometers. Moreover, the convex ridges extend longitudinally parallel to the X-axis direction as shown in  FIG. 5 . The substrate  11   b  is 100 nanometers thick. Furthermore, the rugged surface of the diffusion layer  23   b  of the concave light diffusing piece  20   b  face upward, while the concave ridges  221   b  associated with the ridge-shaped layer  22   b  faces downward. The inter-ridge distance of two adjacent concave ridges is 60 nanometers and the ridge&#39;s height is 20 nanometers. Each concave ridge is extended parallel to the X′-axis, where X′-axis and X-axis makes a included angle of 45°. The substrate  21   b  is 100 nanometers thick.  
         [0033]     The convex light diffusing piece  10   b  and the concave light diffusing piece  20   b  can be joined onto each other intimately, thereby forming a high brightness diffuser. To facilitate joining the convex light diffusing piece  10   b  onto the concave light diffusing piece  20   b  with no joining material used, static electricity can be applied onto the rugged surface associated with the diffusion layer  23   b  such that the joining of the convex light diffusing piece  10   b  and the concave light diffusing piece  20   b  can be accomplished in a vacuum environment.  
         [0034]     Another embodiment of the present invention is shown in  FIGS. 10 and 10 A, wherein two convex light diffusing pieces  10   b  and  10   c  are paired up to form another high brightness diffuser. The two convex diffusing pieces  10   c  and  10   c  are joined together with one piece laid intimately over the top of the other. The convex light diffusing pieces  10   b  and  10   c  are configured such that the rugged surface of the diffusion layer  13   b  of the convex light diffusing piece  10   b  located at the upper deck faces upward and the ridges associated with the ridge-shaped layer  12   b  faces downward. The inter-ridge distance of the two adjacent large ridges  121   b  is 60 nanometers and its ridge&#39;s height is 25 nanometers, whereas the inter-ridge distance of two adjacent small ridges  122   b  is 60 nanometers and its ridge&#39;s height is 10 nanometers. Moreover, both the large ridges  121   b  and the small ridges  122   b  extend longitudinally in the X-axis direction. The substrate  11   b  is 100 nanometers thick. The rugged surface associated with the diffusion layer  13   c  of the convex light diffusing piece  10   c  located at the lower deck faces upward, whereas the ridges associated with the ridge-shaped layer  12   c  faces downward. The inter-ridge distance is 60 nanometers and the ridge&#39;s height is 20 nanometers. The substrate  11   c  is 100 nanometers thick. The present embodiment has the characteristics that the large ridges  121   c  of the lowest layer of this light diffusing piece  10   c  and their associated longitudinal extension lines are parallel to the X′ direction, where X′-axis and X-axis makes an included angle of 8.5°.  
         [0035]     An intimate joining of two light diffusion pieces  10   b  and  10   c  can form a light diffuser capable of emitting light of superior brightness. The intimate joining can be accomplished through the application of static electricity on the rugged surface of the diffusion layer  13   c  in a vacuum environment, using no joining materials  
         [0036]      FIG. 11  shows the brightness performance with respect to viewing angle for the embodiments detailed in  FIGS. 5 and 6  of the present invention and for those embodiments representing the prior art. In  FIG. 11 , Curve A represents the brightness performance of the light diffuser disclosed in U.S. Pat. No. 6,327,083. Similarly, Curves B and C represent the brightness performance of light diffusers employing the prior art, while Curve D represents the brightness performance of a light diffuser of a rear projection screen. Furthermore in  FIG. 11 , Curve E represents the brightness performance of a convex type diffuser  10  and a concave type diffuser  20  detailed in  FIG. 5 , and Curve F represents the compound light diffuser formed by laying double convex type diffusion pieces  10  and  10   a  over each other. From  FIG. 11 , it is known that better performance of brightness of light diffusers embodying the prior art as represented by Curves A, B, C and D can only be realized within the 60° front viewing angle, whereas the brightness beyond the center 60° front viewing angle is considerably reduced. However, the brightness of the light diffuser embodying the present invention as represented by Curves E and F is evenly spread over the center 80° of the front viewing angle, and thus has the merit of high output brightness plus wide-angle uniformity. This is an advantage, which can not be realized by the light diffusers embodying the prior art. The light diffuser embodying the present invention can not only be used in a large-scale screen, but can also be utilized in a rear projection module due to its small size, which is about one quarter the size of the prior-art diffusers. Besides, the light diffuser embodying the present invention can form different kinds of diffusers that have different optical characteristics through various combinations of the convex type diffuser and the concave type diffuser to meet different products&#39; requirements.  
         [0037]     In summary, the present invention has the following the merits: 
    1. Great brightness output,     2. Wide-angle brightness uniformity     3. Thinned structure     4. Joint with shielding effect     5. Flexible structural variation to meet various product requirements    
 
         [0043]     While the preferred embodiment of the invention has been set forth for the purpose of disclosure, modifications of the disclosed embodiment of the invention as well as other embodiments thereof may occur to those skilled in the art. Accordingly, the appended claims are intended to cover all embodiments which do not depart from the spirit and scope of the invention.