JP3959998B2 - Method for producing light diffuser - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention has anisotropy in light scattering characteristics (light scattering occurs with respect to light incident at a specific range of angles, and light scattering does not occur with respect to light incident at other angles. And a display device using the same.
In particular, a light scatterer capable of displaying not only a change in the light scattering state according to the observation direction but also a selective transparent state / light scattering state according to the light scattering characteristic and a pattern display of characters, pictures, and the like is used. The present invention relates to a display device.
[0002]
[Prior art]
Various proposals have been made as optical films having anisotropy in light scattering characteristics, and the applicant of the present application stated that "by distributing portions with different refractive indexes in a random shape and thickness inside the film, Japanese Patent Application Laid-Open No. 2000-171619 discloses a light scattering film having a structure in which a light and shade pattern having a high and low refractive index is formed and portions having different refractive indexes are distributed in a layered manner in an inclined manner with respect to the thickness direction of the film. Proposed in the gazette.
[0003]
With the above light scattering film, anisotropy that allows light incident at an angle within a specific range to pass through without being scattered, and light incident at an angle other than the above to pass through without being scattered. There is provided a light scattering film that can be controlled and can control the directivity (direction and range) at the time of scattering.
[0004]
In the light scattering film according to the above proposal, light scattering occurs only for light incident at an angle in a specific (one type) range, and the scattering anisotropy is also limited to one type.
Therefore, in a display device to which the light source is applied, if the light source that generates display light does not exist within a specific range, light scattering does not occur, and the degree of dependence on observation conditions is high.
[0005]
In addition, the conventional light scattering film can only be switched between “light scattering / transparency” by anisotropy, and there is no idea about the pattern display by the light scattering film itself and the improvement of the design and visual effects. .
[0006]
Furthermore, light scattering when matched to anisotropy causes large light scattering of short-wavelength light, large scattering of “blue” light in the visible wavelength range, and scattering of “yellow” light in a color-catch relationship. Has been confirmed to be small and transparent.
For this reason, when the light scattering film is viewed in a state where light scattering has occurred, yellowing is felt, which is not preferable for application to a display device (particularly, for use in performing full-color display).
[0007]
[Problems to be solved by the invention]
The present invention further expands the scattering anisotropy of the light scattering film disclosed in JP 2000-171619 A,
Reduces environmental dependency (expands the incident angle of illumination light that causes light scattering), reduces the situation seen with "yellowing" in the light scattering state,
In addition to changes in light scattering depending on the viewing direction, it is also possible to display patterns other than patterns by display devices, such as characters and designs in a selective transparent state / light scattering state, and to improve design and visual effects. An object is to provide an improved light scatterer and a display device using the same.
[0008]
In the present invention, when the terms “scattering” and “diffusion” are used for light, they are synonymous.
Further, the light scatterer according to the present invention is in the form of “film or sheet”, and these “film” and “sheet” are treated as synonyms, and the terms “light scattering film” or “light scattering sheet” are also mixed. Sometimes used as a synonym.
[0009]
[Means for Solving the Problems]
In the present invention, a factor that determines the anisotropy of the light-scattering film is “an inclined direction in which different portions of the refractive index are distributed in a layered manner in the same direction in the thickness direction of the sheet or film”. Instead, the above-described problem is solved by using two or more directions.
[0010]
The invention of claim 1
A shade consisting of a difference in refractive index is formed inside the sheet or film, and the portion having a different refractive index is an indefinite shape having a long side and a short side on the surface of the sheet or film, and the long side Alternatively, the short sides are arranged in a certain direction, and in the thickness direction of the sheet or film, the direction is aligned and inclined, and the light incident on the incident light at an angle along the inclination direction. This is a method of manufacturing a light scatterer that has anisotropy that functions to simply transmit light that does not cause light scattering and does not cause light scattering for light incident at an angle deviating from the tilt direction. There,
Ultraviolet light emitted from the UV light source is converted into parallel light by a collimating optical system, the parallel light is passed through a filter whose aperture shape defines the pattern, and the parallel light that has passed through the filter is placed on the side opposite to the UV light source. Irradiating the arranged mask original, and exposing the pattern of the mask original to the photosensitive material;
A UV light source is arranged so that the angle formed between the parallel light and the mask original is different from the angle formed between the parallel light and the mask original in the exposure step, and the pattern of the mask original is exposed to the photosensitive material in the same manner as in the exposure step. A process comprising:
The distribution of light and shade consisting of a difference in refractive index has two or more inclination directions in the thickness direction of the sheet or film in the sheet or film, and is incident on the light incident at an angle along the inclination direction. Is a method for producing a light scatterer that functions to display a pattern of a pattern in a selective transparent state / light scattering state .
[0011]
The invention of claim 2
A shade consisting of a difference in refractive index is formed inside the sheet or film, and the portion having a different refractive index is an indefinite shape having a long side and a short side on the surface of the sheet or film, and the long side Alternatively, the short sides are arranged in a certain direction, and in the thickness direction of the sheet or film, the direction is aligned and inclined, and the light incident on the incident light at an angle along the inclination direction. This is a method of manufacturing a light scatterer that has anisotropy that functions to simply transmit light that does not cause light scattering and does not cause light scattering for light incident at an angle deviating from the tilt direction. There ,
The laser light emitted from the laser light source is passed through a filter whose opening shape defines a pattern, and the laser light that has passed through the filter is applied to a ground glass in which a photosensitive material is disposed at a predetermined distance F on the side opposite to the laser light source. Irradiating a photosensitive material with a speckle pattern, which is an interference pattern created by laser light irradiated and scattered by ground glass; and
Arranging a laser light source so that an angle formed by the laser beam and the ground glass is different from an angle formed by the laser beam and the ground glass in the exposure step, and exposing the speckle pattern to the photosensitive material in the same manner as the exposure step. Characterized by comprising,
The distribution of light and shade consisting of a difference in refractive index has two or more inclination directions in the thickness direction of the sheet or film in the sheet or film, and is incident on the light incident at an angle along the inclination direction. Is a method for producing a light scatterer that functions to display a pattern of a pattern in a selective transparent state / light scattering state .
[0012]
The invention of claim 3
A display device characterized in that the light scatterer according to claim 1 or 2 is arranged on the front surface (observer side) of the device.
Typical examples of the display device include a liquid crystal display device and an EL display device, and the light scatterer of the present invention is applied to a device that displays a pattern by modulating an image display element.
[0013]
In particular, the present invention is effective when applied to a reflective liquid crystal display device that does not require an illumination light source incorporated in the device.
In recent years, a method of arranging a light scattering film on the front surface (observer side) of a liquid crystal panel has been adopted as a liquid crystal display device of a method that is bright and has high contrast and does not have viewing angle dependency and double image problems. .
Further, a method in which an electrode for driving a liquid crystal also serves as a reflector (hereinafter, such an electrode is referred to as a reflective electrode) is used in combination with the above method.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below.
First, optical characteristics exhibited by the light scatterer (film) according to the present invention will be described.
[0015]
Fig.1 (a) is sectional drawing which shows the light-scattering body (film) based on a prior art.
As shown in FIG. 1 (a), the light scattering film 20 has a refractive index that changes in its interior, so that light and shade having a difference in refractive index is formed. In the thickness direction, the direction is aligned and inclined.
[0016]
In the figure, light scattering is caused for light incident at an angle (n: constant) along the inclination direction of the portions having different refractive indexes,
Light that is incident at an angle (n: change) deviating from the tilt direction does not cause light scattering, but simply functions as a transmission.
[0017]
FIG.1 (b) is sectional drawing which shows the light-scattering film 20 which concerns on this embodiment, and the direction where the part from which a refractive index differs aligns and inclines has two directions.
In the figure, light scattering occurs for light incident at an angle (two directions of 1st and 2nd) along the inclination direction of portions having different refractive indexes.
Accordingly, since light scattering occurs with respect to incident light from two directions of 1st and 2nd, anisotropy is improved as compared with FIG. 1A, and incident light with respect to the light scattering film 20 does not scatter light. The number of situations that occur increases, and when applied to a display device, the viewing conditions under which the display can be visualized are expanded.
[0018]
In the case of FIG. 1B, in the region on the left side of the figure where light scattering occurs with respect to incident light from the 2nd direction, incident light in the downward left direction (1st direction) passes through without causing light scattering. In the region on the right side of the figure where light scatters with respect to incident light from the direction, incident light (2nd direction) in the right-down direction passes without light scattering. As shown in the lower center of the figure, in the area where the light scattering areas with different directions overlap and are recorded, the scattering anisotropy is not affected. Arise.
[0019]
In the method for producing a light scattering film disclosed in Japanese Patent Application Laid-Open No. 2000-171619, diffused light that has passed through a light diffuser having a predetermined shape is incident on the photosensitive material at a predetermined angle, or openings having a predetermined shape are arranged. Such a method is adopted that the light having passed through the mask pattern is incident at a predetermined angle. The produced light scattering film has “scattering anisotropy” controlled according to the above “predetermined angle of incidence on the photosensitive material”, and the above “predetermined shape of the opening of the light diffuser or mask pattern”. Accordingly, “scattering directivity” is controlled.
In the present invention, since the light scattering film has a scattering anisotropy of 2 or more, the photosensitive material is irradiated in two or more directions in production.
[0020]
In the present invention, not only the transmission / light scattering state but also a pattern (image) different from the display pattern (image) by the display device can be realized by the light scattering film 10.
[0021]
When the pattern (image) is displayed by the light scattering film 20 itself, it is only necessary to be able to express a character or a picture based on the difference between the transmission / light scattering states in a state matching the scattering anisotropy.
In this case, the above expression can be achieved by patterning the light incident on the photosensitive material so as to form the above “character or picture”.
[0022]
As a patterning method, it is effective to expose the photosensitive material through a mask having an opening (or an inverted opening) in the shape of “character or pattern”, but is not limited thereto. Further, a mask in which a large number of minute openings are formed inside the shape (or a large number of minute openings are formed in an inverted portion) may be used.
[0023]
FIG. 2 is an explanatory diagram showing an example of a light scatterer that displays a pattern such as a character or a pattern in accordance with a selective transparent state / light scattering state depending on the presence or absence of a region where light scattering occurs due to anisotropy. It is.
In the figure, a region in which different refractive indexes: n are distributed in layers in two directions with respect to the thickness direction of the film, the letter “A” is shown on the left side of the figure, and the letter “A” is shown on the right side of the figure The shape is “B”.
[0024]
As described above, the portions having different refractive indexes: n are inclined in the thickness direction of the film and have two directions distributed in a layered manner, and the region is formed into an arbitrary shape. As shown in FIG. 3, the observer 1 in the first direction can recognize only the letter “A” and the observer 2 in the second direction can recognize only the letter “B”.
[0025]
In addition to the selective “transparent state / light scattering state”, it is also possible to modulate the “light scattering property” for each region to enrich the gradation expression of characters, designs, and the like.
The light scattering property includes the light scattering degree and the light scattering direction / range (scattering directivity).
[0026]
FIG. 4 is an explanatory diagram showing an example of optical characteristics when the light scattering degree is controlled for each of the three regions divided in the light scattering film 20.
In the figure, parallel light incident from the right side of the light scattering film 20 is strongly scattered when passing through the region 21, and the light scattering degree when passing through the regions 22 and 23 becomes relatively weak.
In the example of the figure, the light scattering direction is the same in any region.
[0027]
FIG. 5 is an explanatory diagram showing an example of optical characteristics when the scattering directivity is controlled in the light scattering direction for every three regions divided in the light scattering film 20.
In the example of the figure, the light scattering intensity is equal in any region.
In the figure, parallel light incident from the right side of the light scattering film 20 is scattered upward when passing through the region 21, and scattered around the front or lower side when passing through the regions 22 and 23.
[0028]
Further, as shown in FIG. 6, the light scattering characteristic for each region can be controlled not with respect to intensity and direction but with respect to the range as shown in FIGS.
In the figure, parallel light incident from the right side of the light scattering film 20 is strongly scattered in the vertical (vertical) direction when passing through the region 24, and strongly scattered in the lateral (horizontal) direction when passing through the region 25. The directivity can be given.
[0029]
In the case of FIG. 4, the direction in which the portions having different refractive indexes in the photosensitive material (thickness direction) are inclined in a layered manner is uniform for each region, and the shape of the portions having different refractive indexes on the surface of the light scattering film 20 or The layered density is changing.
In the case of FIG. 5, the direction in which the portions having different refractive indexes in the photosensitive material (thickness direction) are inclined in layers changes for each region.
In the case of FIG. 6, the shape of the portion having a different refractive index on the surface of the light scattering film 20 changes.
As shown in FIGS. 4, 5, and 6, it is possible to change the display of characters, patterns, etc. depending on the observation direction by recording the light scattering area by changing the diffusion direction / directivity arbitrarily. Therefore, it is possible to have a richer expression method.
[0030]
An example in which the light scattering film as described above is arranged on the front surface (observer side) of the device to constitute the display device will be described below.
7 and 8 are cross-sectional views conceptually showing the main part of an example of a display constructed using a light scattering film.
[0031]
<Transparent display>
FIG. 7 shows a main part of a display composed of an image display element (such as a liquid crystal panel) 2 that defines a display image by transmission / non-transmission and a light scattering film 1 disposed on the front surface (observer side). It is sectional drawing shown notionally.
The light scattering film 1 has different light scattering characteristics for each region. In the same figure, the light scattering properties of the regions a and c (colored) are equal, and the light scattering property of the region b is different from that. .
[0032]
As shown in the figure, when illumination light 3 such as a backlight passes through an image display element 2 that defines a display pattern (image) and enters a light scattering film 1, it enters the regions a and c. The light scatters in accordance with the anisotropy of the light scattering film 1 and is emitted as scattered light 4. The light incident on the region b does not match the anisotropy, does not cause light scattering, and is emitted as transmitted light 5 without being scattered.
If the direction of the illumination light 3 is changed, the light incident on the region b may be scattered and emitted as scattered light 4. The scattered light 4 may be a character or a picture having a light scattering pattern.
[0033]
In the description of the figure, the display is of a type that requires the illumination light 3, but the image display element 2 may be of a self-luminous type without requiring the illumination light 3. Examples of such an image display element 2 include an EL element and a plasma display panel, and the light scattering film of the present invention can also be applied.
[0034]
<Reflective display>
FIG. 8 shows a display composed of an image display element (such as a liquid crystal panel including a reflector) 6 that defines a display image by reflection / non-reflection and a light scattering film 1 disposed on the front surface (observer side). It is sectional drawing which shows notionally the principal part.
The light scattering film 1 has different light scattering characteristics for each region. In the same figure, the light scattering properties of the regions a and c (colored) are equal, and the light scattering property of the region b is different from that. .
[0035]
As shown in the figure, after the illumination light (ambient light) 3 such as outside light or indoor illumination is transmitted through the light scattering film 1 and the image display element 2, it is reflected as pattern light according to the display image, and again When the light is incident on the light scattering film 1, the light incident on the regions “a” and “c” is scattered according to the anisotropy of the light scattering film 1 and emitted as scattered light 4. The light incident on the region b does not match the anisotropy, does not cause light scattering, and is emitted as transmitted light 5 without being scattered.
Further, when the direction of the illumination light 3 (ambient light) is changed, light incident on the region b may be scattered and emitted as scattered light 4. The scattered light 4 may be a character or a picture having a light scattering pattern.
In any form of display, if the entire screen is not in the same light scattering state, the entire surface will not be seen with yellowing at the same time, and it is expected to act to counteract yellowing. The problem of yellowing in the light scattering state of the scattering film is reduced.
[0036]
The light scattering film of the present invention is produced as follows.
<Production means 1>
FIG. 9 is an explanatory view showing an example of an optical system for producing a light scattering film using a random mask pattern.
The ultraviolet light emitted from the two UV light sources 7 is converted into parallel light 9 by the collimating optical system 8, and the parallel light 9 passes through the filter 10 whose opening shape defines the pattern and irradiates the mask original plate 11. The mask original 11 comprises a glass substrate 13 and a chromium pattern 14 which is a random pattern.
[0037]
The photosensitive material 12 is disposed in close contact with the side opposite to the UV irradiation side of the mask original 11, and the pattern of the mask original 11 is exposed to the photosensitive material 12.
At this time, one UV parallel light 9 (left side in the figure) is incident on the mask original plate 11 at a predetermined angle α, so that pattern exposure is performed at a predetermined angle in the photosensitive material 12. Since this angle corresponds to the inclination angle of the portion having a different refractive index in the light scattering film, the angle is appropriately selected within the range of about 0 to 60 degrees depending on the application.
Also, by performing the same exposure irradiation at an angle different from the angle α (angle β on the right side of the figure), the direction in which the portions having different refractive indexes are inclined in a layered manner can be a plurality of directions. Become.
[0038]
<Production means 2>
FIG. 10 is an explanatory diagram showing an example of an optical system for producing a light scattering film using a speckle pattern.
The laser light 16 emitted from the laser light source 15 irradiates the ground glass 17 after passing through the filter 10 whose opening shape defines the pattern. On the opposite side of the frosted glass 17 from the filter 10 side, a photosensitive material 12 is arranged at a predetermined distance F, and a speckle pattern, which is a complicated interference pattern generated by laser light transmitted and scattered by the frosted glass 17, is exposed to the photosensitive material 12. Irradiated.
At this time, one laser beam 16 (the lower side in the figure) is incident on the ground glass 17 at a predetermined angle α, so that pattern exposure is performed at a predetermined angle in the photosensitive material 12. Since this angle corresponds to the inclination angle of the portion having a different refractive index in the light scattering film, the angle is appropriately selected within the range of about 0 to 60 degrees depending on the application.
Further, by performing the same exposure irradiation at an angle different from the angle α (the angle β in the upper side of the figure), the direction in which the portions having different refractive indexes are inclined in layers can be set to a plurality of directions. Become.
[0039]
【The invention's effect】
By increasing the scattering anisotropy of the light scattering film, the incident angle of the illumination light causing light scattering is expanded, and the situation of being viewed with “yellowing” in the light scattering state is reduced,
In addition to changes in light scattering depending on the viewing direction, it is also possible to display patterns other than patterns by display devices, such as characters and designs in a selective transparent state / light scattering state, and design and visual effects are improved. improves.
[0040]
[Brief description of the drawings]
1A and 1B are explanatory views showing optical characteristics (anisotropy) of a light scattering film, in which FIG. 1A is a prior art, and FIG. 1B is an explanatory view showing a light scattering film according to the present invention.
FIG. 2 is an explanatory diagram showing an example of a light scatterer that displays a pattern such as a character or a pattern in accordance with a selective transparent state / light scattering state depending on the presence or absence of a region where light scattering occurs due to anisotropy. .
FIG. 3 is an explanatory view showing a state in which the light scattering film of FIG. 2 is observed.
FIG. 4 is an explanatory diagram showing an example of optical characteristics of a light scattering film.
FIG. 5 is an explanatory diagram showing an example of optical characteristics of a light scattering film.
FIG. 6 is an explanatory diagram showing an example of optical characteristics of a light scattering film.
FIG. 7 is a cross-sectional view illustrating an example of a display configured using a light scattering film.
FIG. 8 is a cross-sectional view illustrating an example of a display configured using a light scattering film.
FIG. 9 is an explanatory diagram showing an example of an optical system for producing a light scattering film using a random mask pattern.
FIG. 10 is an explanatory diagram showing an example of an optical system for producing a light scattering film using a speckle pattern.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Light scattering film 2 ... Image display element 3 ... Illumination light 7 ... UV light source 8 ... Collimating optical system 9 ... Parallel light
10 ... Filter
11 ... Mask original
13 ... Glass substrate
14 ... chrome pattern
20 ... Light scattering film
21, 22, 23, 24, 25 ... Light scattering region

Claims (2)

A shade consisting of a difference in refractive index is formed inside the sheet or film, and the portion having a different refractive index is an indefinite shape having a long side and a short side on the surface of the sheet or film, and the long side Alternatively, the short sides are arranged in a certain direction, and in the thickness direction of the sheet or film, the direction is aligned and inclined, and the light incident on the incident light at an angle along the inclination direction. This is a method of manufacturing a light scatterer that has anisotropy that functions to simply transmit light that does not cause light scattering and does not cause light scattering for light incident at an angle deviating from the tilt direction. There,
Ultraviolet light emitted from the UV light source is converted into parallel light by a collimating optical system, the parallel light is passed through a filter whose aperture shape defines the pattern, and the parallel light that has passed through the filter is placed on the side opposite to the UV light source. Irradiating the arranged mask original, and exposing the pattern of the mask original to the photosensitive material;
A UV light source is arranged so that the angle formed between the parallel light and the mask original is different from the angle formed between the parallel light and the mask original in the exposure step, and the pattern of the mask original is exposed to the photosensitive material in the same manner as in the exposure step. A process comprising:
The distribution of light and shade consisting of a difference in refractive index has two or more inclination directions in the thickness direction of the sheet or film in the sheet or film, and is incident on the light incident at an angle along the inclination direction. the manufacturing method of the functional to that light scatterer to perform the pattern display of the picture by selective transparent state / light scattering state. A shade consisting of a difference in refractive index is formed inside the sheet or film, and the portion having a different refractive index is an indefinite shape having a long side and a short side on the surface of the sheet or film, and the long side Alternatively, the short sides are arranged in a certain direction, and in the thickness direction of the sheet or film, the direction is aligned and inclined, and the light incident on the incident light at an angle along the inclination direction. This is a method of manufacturing a light scatterer that has anisotropy that functions to simply transmit light that does not cause light scattering and does not cause light scattering for light incident at an angle deviating from the tilt direction. There ,
The laser light emitted from the laser light source is passed through a filter whose opening shape defines a pattern, and the laser light that has passed through the filter is applied to a ground glass in which a photosensitive material is disposed at a predetermined distance F on the side opposite to the laser light source. Irradiating a photosensitive material with a speckle pattern, which is an interference pattern created by laser light irradiated and scattered by ground glass; and
Arranging a laser light source so that an angle formed by the laser beam and the ground glass is different from an angle formed by the laser beam and the ground glass in the exposure step, and exposing the speckle pattern to the photosensitive material in the same manner as the exposure step. Characterized by comprising,
The distribution of light and shade consisting of a difference in refractive index has two or more inclination directions in the thickness direction of the sheet or film in the sheet or film, and is incident on the light incident at an angle along the inclination direction. the manufacturing method of the functional to that light scatterer to perform the pattern display of the picture by selective transparent state / light scattering state.

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