JP3714460B2 - Liquid crystal display device - Google Patents

Description

以上のような構成において、バックライトの利用効率の向上度合いを、ホログラム２を用いて従来のように±５０°の発散光を照射させる照明装置と比較を行ったところ、下記のような結果が得られた。ただし、倍率は、それぞれホログラムを用いないで液晶表示パネルに直接照明光を照射した場合に対する利用効率の向上倍率である。
【００１７】
従来型照明装置 ×１．１５
図１の照明装置 ×２．３０
この結果から、液晶表示装置にホログラム２を設置した場合でも、従来型の照明装置をそのまま用いた場合は、その向上度合は少ないことが分かる。一方、本発明の方式をとった場合、照明光３の平行度合はおよそ±５°程度に抑えられるため、ホログラム２の性能を十分引き出していると言える。
【００１８】
次に、光ファイバーの代わりに導波路を用いる実施例について説明する。図３の断面図及び図４の要部斜視図に示すように、微小凸レンズアレー４の背後に開口マスク１８を配置し、その背後に反射板２１で裏打ちされた導波路２０を配置する。開口マスク１８は、微小凸レンズアレー４を構成する各微小凸レンズ１４の焦点位置に微小な開口１９を有し、それ以外は遮光性で導波路２０側が反射面になっている。そして、導波路２０の１側面が光源１７に対向して取り付けられており、光源１７からの照明光は導波路２０のこの対向する側面から導波路２０に入り、反射板２１と開口マスク１８の反射面との間で多重反射して導波路２０中をガイドされるが、その間開口マスク１８の開口１９から一部の光が漏れる。この開口１９が２次点光源になってそこから出た発散光は、微小凸レンズ１４のレンズ面で平行光３に変換され、ホログラム２の対応する微小ホログラムに入射し、ここで分光されたＲ、Ｇ、Ｂの光は液晶セルを通過してカラーフィルターセルＲ、Ｇ、Ｂに入射して、明るいカラー表示を行う。この場合も、ホログラム２は撮影時の条件通りに平行光で照射されるので、その回析効率及び分光特性が十分発揮され、照明光の高い利用効率が得られる。
【００１９】
なお、図３、図４はカラーフィルターセルＲ、Ｇ、Ｂが正方形、円等の等方的な形状の場合であるが、これがストライプフィルター等の細長いものの場合、開口はその長さに等しいスリット形状にする必要がある。その場合の要部斜視図を図５に示す。この場合は、微小凸レンズアレーの代わりに、ストライプフィルターの方向に母線を有し、その長さに等しい長さの微小円筒レンズからなる微小円筒レンズアレー４′を用い、開口マスク１８′は各微小円筒レンズの焦線位置にスリトット開口１９′を有するようにする。その他は図３、図４の場合と同様である。
【００２０】
以上、本発明の液晶表示装置をいくつかの実施例に基づいて説明してきたが、本発明はこれら実施例に限定されず、種々の変形が可能である。
【００２１】
【発明の効果】
以上の説明から明らかなように、本発明の液晶表示装置によると、背後から入射する照明光の赤、緑、青の各波長成分を分けて対応する液晶セル位置に入射させるホログラム素子が赤を表示する液晶セル、緑を表示する液晶セル、青を表示する液晶セルの組からなる画素のピッチと同じピッチでアレー状に背後に配置されており、そのホログラム素子が、背後から入射するほぼ平行な照明光の赤、緑、青の各波長成分を波長に応じて異なる回折角に回折分光して対応する液晶セル位置に入射させる単一のホログラムからなり、そのホログラム素子の背後にそのホログラム素子に対応するピッチの凸レンズのアレーが配置され、さらにその背後に導波路が配置されており、その導波路からの光でホログラム素子を照明するので、単一のホログラムからなるホログラム素子の分光機能を十分に発揮させて入射光の各波長成分を無駄なく各液晶セルへ入射させることができ、バックライトの利用効率向上を確実にすることができる。
【図面の簡単な説明】
【図１】本発明の１実施例の液晶表示装置の構成を示す図である。
【図２】図１の部分拡大図である。
【図３】別の実施例の断面図である。
【図４】別の実施例の要部斜視図である。
【図５】図３の変形例の要部斜視図である。
【図６】本出願人の提案に係るホログラムを用いたカラー液晶表示装置の概略の構成を示す図である。
【符号の説明】
１…カラーフィルター
２…ホログラム
３…バックライト
４…微小凸レンズアレー
１４…各微小凸レンズ
１５…光ファイバー
１６…遮光膜
１７…光源
１８…開口マスク
１９…開口
２０…導波路
２１…反射板
４′…微小円筒レンズアレー
１８′…開口マスク
１９′…スリトット開口[0001]
[Industrial application fields]
The present invention relates to a liquid crystal display device, and more particularly to a liquid crystal display device in which the illumination light is made parallel and incident on the liquid crystal display panel or spectral hologram to improve the use efficiency of the illumination light. It is.
[0002]
[Prior art]
In the Japanese Patent Application Nos. 5-12170 and 5-11711, the applicant of the present invention uses light efficiently by splitting the backlight into the R, G, B cells of the color filter of the color liquid crystal display device. In order to improve the efficiency, a method using a hologram was proposed. The principle will be briefly described. In the case of FIG. 6A, the backlight 3 parallel to the hologram 5 having no wavelength selectivity and having the spectral property is incident, and the R, G, and B of the spectrum separated by the hologram 5 are incident. Light is made incident on the color filter cells R, G, and B constituting one pixel of the color filter 1 of the liquid crystal display panel to improve the utilization efficiency of the backlight. In the case of FIG. Using holograms 6 and 7 having a diffraction wavelength selectivity with respect to a specific wavelength, such as a hologram, blue light diffracted by hologram 6 is applied to color filter cell B, and red light diffracted by hologram 7 is colored. The remaining complementary color component (green) which is not diffracted by the holograms 6 and 7 is incident on the filter cell R and is incident on the color filter cell G. It is intended to improve the use efficiency of.
[0003]
Conventionally, a liquid crystal display device used in a projection apparatus is illuminated with parallel light and projected on a screen in an enlarged manner.
[0004]
[Problems to be solved by the invention]
However, in the illumination device using the above hologram, if the backlight of the current liquid crystal flat display is used as it is, the expected effect cannot be obtained. This is because, despite the fact that holograms have inherently strict incident angle selectivity, the backlight of a liquid crystal flat display is scattered light of about ± 50 °, so high diffraction efficiency cannot be obtained. This is because a phenomenon such as that the diffracted light of the original color does not enter the color filter cell of the predetermined color occurs, and the use efficiency of the backlight cannot be increased as expected.
[0005]
The present invention has been made in view of such a situation, and an object of the present invention is to use illumination light by making illumination light incident on a hologram for spectroscopy using a waveguide as a backlight light source of a liquid crystal display device. To improve efficiency.
[0006]
[Means for Solving the Problems]
The liquid crystal display device of the present invention that achieves the above object is a liquid crystal display device that is composed of an array-shaped liquid crystal cell and illuminates from behind, and separately handles the red, green, and blue wavelength components of illumination light incident from the back. The hologram element that is incident on the position of the liquid crystal cell is arranged in the back in an array with the same pitch as the pitch of the liquid crystal cell that displays red, the liquid crystal cell that displays green, and the liquid crystal cell that displays blue The hologram element diffracts the red, green, and blue wavelength components of the substantially parallel illumination light incident from behind and diffracts the light into different diffraction angles according to the wavelengths and enters the corresponding liquid crystal cell position. An array of convex lenses having a pitch corresponding to the hologram element is disposed behind the hologram element, and a waveguide is disposed behind the array. It is characterized in that illuminating the hologram element with light.
[0007]
In this case, the waveguide is made of an optical fiber, and the hologram element can be illuminated after diverging light emitted from the end thereof is converted into substantially parallel light by a convex lens.
[0008]
In addition, the waveguide has a minute opening on the side surface, and the hologram element can be illuminated after diverging light emitted from the minute opening is converted into substantially parallel light by a convex lens.
[0009]
[Action]
In the present invention, the hologram element that divides each of the red, green, and blue wavelength components of the illumination light incident from behind and enters the corresponding liquid crystal cell position displays a liquid crystal cell that displays red, a liquid crystal cell that displays green, blue Is arranged behind the array at the same pitch as the pitch of the pixel consisting of a set of liquid crystal cells, and the hologram element has red, green, and blue wavelength components of substantially parallel illumination light incident from behind Is formed of a single hologram that is diffracted and dispersed at different diffraction angles depending on the wavelength and is incident on the corresponding liquid crystal cell position, and an array of convex lenses having a pitch corresponding to the hologram element is arranged behind the hologram element, and A waveguide is arranged behind it, and the hologram element is illuminated with light from the waveguide, so that the spectral function of the hologram element consisting of a single hologram is sufficiently achieved. Volatilizing is brought to each wavelength component of the incident light can be incident to waste without the liquid crystal cell, it is possible to ensure efficient use of the backlight.
[0010]
【Example】
Hereinafter, embodiments of the liquid crystal display device of the present invention will be described with reference to the drawings.
[0011]
In the color liquid crystal display device as shown in FIG. 6, the holograms 5 to 7 exhibit sufficient performance such as diffraction efficiency and diffraction angle when reproduced with the backlight 3 incident according to the conditions at the time of photographing. be able to. However, if the playback conditions are different from those at the time of shooting, the performance is drastically reduced. For this reason, the effect of using the holograms 5 to 7 becomes small in the conventional illumination light that is scattered light.
[0012]
For this reason, in the present invention, an illumination device that can irradiate parallel light of uniform surface emission is used, for example, to improve the efficiency at the time of reproducing a hologram using the parallel light as reference light at the time of photographing. In the following description, a configuration is described in which a backlight is efficiently dispersed and incident on each cell of a color filter of a color liquid crystal display device using such a hologram. However, the present invention is not limited to this and is used for a projection device. It can also be used as a lighting device for a liquid crystal display device.
[0013]
FIG. 1 shows a configuration of a lighting device according to an embodiment of the present invention. In this figure, the spectral action as shown in FIG. 6 (a) or (b) is aligned with each pixel consisting of a set of three color cells R, G, B of the color filter 1 of the color liquid crystal display device. A hologram 2 formed by arranging minute holograms to be arranged in an array at the same pitch as the pixel pitch of the color filter 1 is arranged on the incident side of the backlight 3 of the color filter 1. A liquid crystal display panel (not shown) is arranged between the color filter 1 and the hologram 2 so that the filter cells R, G, B and the liquid crystal cells are aligned. In accordance with the present invention, a minute convex lens array 4 having a pitch corresponding to the minute hologram array is arranged on the incident side of the hologram 2, and as shown in a partially enlarged view in FIG. One end of the optical fiber 15 is attached to the focal position of the convex lens 14. It should be noted that the surface other than the end of the optical fiber 15 at the focal plane of each micro-convex lens 14 is covered with a light-shielding film 16 so that external light does not enter. The other end of the optical fiber 15 corresponding to each micro-convex lens 14 is bundled together and attached to face the light source 17 such as a metal halide lamp.
[0014]
In such a configuration, the illumination light emitted from the light source 17 enters the other end of each optical fiber 15, is guided through the optical fiber 15 and guided to one end, and as shown in FIG. The divergent light emitted from one end portion of the lens 15 as a secondary point light source is converted into parallel light 3 by the lens surface of the minute convex lens 14 and is incident on the corresponding minute hologram of the hologram 2. The split R, G, and B light passes through the liquid crystal cell and enters the color filter cells R, G, and B to perform bright color display. Thus, in the present invention, since the hologram 2 is irradiated with parallel light according to the conditions at the time of photographing, its diffraction efficiency and spectral characteristics are sufficiently exhibited, and high utilization efficiency of illumination light is obtained.
[0015]
Specific experimental results are shown.
[0016]

In the configuration as described above, the degree of improvement in the use efficiency of the backlight was compared with a conventional illumination device that irradiates ± 50 ° divergent light using the hologram 2, and the following results were obtained. Obtained. However, the magnification is a magnification for improving the use efficiency with respect to the case where the liquid crystal display panel is directly irradiated with illumination light without using a hologram.
[0017]
Conventional lighting device × 1.15
Illumination device in FIG. 1 × 2.30
From this result, it can be seen that even when the hologram 2 is installed in the liquid crystal display device, the improvement degree is small when the conventional illumination device is used as it is. On the other hand, when the method of the present invention is employed, it can be said that the parallelism of the illumination light 3 is suppressed to about ± 5 °, so that the performance of the hologram 2 is sufficiently brought out.
[0018]
Next, an embodiment using a waveguide instead of an optical fiber will be described. As shown in the cross-sectional view of FIG. 3 and the perspective view of the main part of FIG. 4, the opening mask 18 is disposed behind the micro-convex lens array 4, and the waveguide 20 lined with the reflector 21 is disposed behind it. The aperture mask 18 has a minute aperture 19 at the focal position of each minute convex lens 14 constituting the minute convex lens array 4, and the other portion is light-shielding and has a reflection surface on the waveguide 20 side. One side surface of the waveguide 20 is attached to face the light source 17, and illumination light from the light source 17 enters the waveguide 20 from the opposite side surface of the waveguide 20, and the reflection plate 21 and the opening mask 18 While being guided through the waveguide 20 by multiple reflections with the reflecting surface, part of the light leaks from the opening 19 of the opening mask 18. The diverging light emitted from the aperture 19 as a secondary point light source is converted into parallel light 3 by the lens surface of the micro-convex lens 14, enters the corresponding micro-hologram of the hologram 2, and is split here. , G, and B light pass through the liquid crystal cell and enter the color filter cells R, G, and B to perform bright color display. Also in this case, since the hologram 2 is irradiated with parallel light according to the conditions at the time of photographing, its diffraction efficiency and spectral characteristics are sufficiently exhibited, and high utilization efficiency of illumination light is obtained.
[0019]
3 and 4 show the case where the color filter cells R, G, and B have an isotropic shape such as a square or a circle. If this is an elongated shape such as a stripe filter, the opening is a slit having the same length. It needs to be shaped. FIG. 5 shows a perspective view of the main part in that case. In this case, instead of the micro-convex lens array, a micro-cylindrical lens array 4 'having a generatrix in the direction of the stripe filter and having a length equal to the length of the micro-cylindrical lens array 4' is used. A slit opening 19 'is provided at the focal line position of the cylindrical lens. Others are the same as the case of FIG. 3, FIG.
[0020]
As described above, the liquid crystal display device of the present invention has been described based on some embodiments. However, the present invention is not limited to these embodiments, and various modifications are possible.
[0021]
【The invention's effect】
As is clear from the above description, according to the liquid crystal display device of the present invention, the hologram element that divides the red, green, and blue wavelength components of the illumination light incident from the back and enters the corresponding liquid crystal cell position emits red. A liquid crystal cell that displays, a liquid crystal cell that displays green, and a liquid crystal cell that displays blue. Consists of a single hologram that diffracts and separates the red, green, and blue wavelength components of the illuminating light at different diffraction angles depending on the wavelength and enters the corresponding liquid crystal cell position, and the hologram element behind the hologram element An array of convex lenses having a pitch corresponding to is arranged, and a waveguide is arranged behind the array, and the hologram element is illuminated with light from the waveguide, so that a single holographic Spectral features of the hologram element consisting sufficiently be exhibited to the respective wavelength components of the incident light can be incident to waste without the liquid crystal cell, it is possible to ensure efficient use of the backlight.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of a liquid crystal display device according to an embodiment of the present invention.
FIG. 2 is a partially enlarged view of FIG.
FIG. 3 is a cross-sectional view of another embodiment.
FIG. 4 is a perspective view of a main part of another embodiment.
FIG. 5 is a perspective view of a main part of a modification of FIG.
FIG. 6 is a diagram showing a schematic configuration of a color liquid crystal display device using a hologram according to the proposal of the present applicant.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Color filter 2 ... Hologram 3 ... Backlight 4 ... Micro convex lens array 14 ... Each micro convex lens 15 ... Optical fiber 16 ... Light shielding film 17 ... Light source 18 ... Opening mask 19 ... Opening 20 ... Waveguide 21 ... Reflecting plate 4 '... Micro Cylindrical lens array 18 '... Opening mask 19' ... Slitto opening

Claims (3)

In a liquid crystal display device that consists of an array of liquid crystal cells and illuminates from behind, the hologram element that divides each red, green, and blue wavelength component of the illumination light incident from the back and enters the corresponding liquid crystal cell position displays red The liquid crystal cell, the liquid crystal cell for displaying green, and the liquid crystal cell for displaying blue are arranged in the back of the array at the same pitch as the pitch of the pixels, and the hologram elements are incident in parallel from the back. red illumination light, green consists of a single hologram to be incident on the liquid crystal cell position corresponding to the diffraction spectroscopy to different diffraction angles depending on the wavelength of each wavelength component of the blue, the hologram element behind the holographic element is disposed an array of corresponding pitch of the convex lens, it is arranged a further waveguide behind, especially to illuminate the hologram element with light from the waveguide A liquid crystal display device. It said waveguide is made of an optical fiber, a liquid crystal display device according to claim 1, wherein the illuminating the hologram element divergent light emitted from the converted substantially parallel light by the lens from its end. Said waveguide is made of those having a microscopic aperture on the side surface, according to claim 1, characterized in that the divergent light emitted from the minute aperture to illuminate the hologram element after converted into substantially parallel light by the lens Liquid crystal display device.

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