JPH0798452A - Reflection type liquid crystal display device - Google Patents
Reflection type liquid crystal display deviceInfo
- Publication number
- JPH0798452A JPH0798452A JP5241860A JP24186093A JPH0798452A JP H0798452 A JPH0798452 A JP H0798452A JP 5241860 A JP5241860 A JP 5241860A JP 24186093 A JP24186093 A JP 24186093A JP H0798452 A JPH0798452 A JP H0798452A
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- Japan
- Prior art keywords
- liquid crystal
- electrode plate
- display device
- crystal display
- refractive index
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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- Optical Elements Other Than Lenses (AREA)
Abstract
Description
【0001】[0001]
【産業上の利用分野】本発明は反射型液晶表示装置に係
り、特に、外光光源の位置に関わりなく視野角が広く、
しかも着色のない明るい画面表示を可能にする反射型液
晶表示装置の改良に関するものである。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reflective liquid crystal display device, and more particularly to a wide viewing angle regardless of the position of an external light source.
Moreover, the present invention relates to an improvement in a reflective liquid crystal display device that enables a bright screen display without coloring.
【0002】[0002]
【従来の技術】この種の液晶表示装置は、一般に、図4
に示すように偏光膜(図示せず)と透明電極a4、b4
が各々設けられた一対の電極板a、bと、これ等電極板
a、b間に封入された液晶物質cとでその主要部が構成
されており、入射した光線をまず入射側の上記偏光膜で
直線偏光にし、かつ、液晶物質cに対して画素毎に電圧
を印加してその配向状態を変化させると共に、その配向
状態によりその部位を透過する上記直線偏光の偏光面を
回転させその回転角に応じて出射側の偏光膜で上記直線
偏光を遮断又は透過させて画面表示を行うものである。
尚、カラー画面を表示するカラー液晶表示装置において
は、上記電極板a、bのいずれか一方に偏光を着色する
ためのカラーフィルター層が設けられている。2. Description of the Related Art A liquid crystal display device of this type is generally shown in FIG.
A polarizing film (not shown) and transparent electrodes a4 and b4 as shown in FIG.
A pair of electrode plates a and b each provided with a liquid crystal substance c enclosed between these electrode plates a and b, the main part of which is formed. The film is made into linearly polarized light, and a voltage is applied to the liquid crystal substance c for each pixel to change its alignment state, and the polarization plane of the linearly polarized light that passes through that portion is rotated according to that alignment state to rotate it. The screen is displayed by blocking or transmitting the linearly polarized light by the polarizing film on the exit side according to the angle.
In a color liquid crystal display device that displays a color screen, a color filter layer for coloring polarized light is provided on one of the electrode plates a and b.
【0003】そして、この種の液晶表示装置としては、
液晶表示装置の背面側に位置する電極板(以下背面電極
板と称する)aの裏面若しくは側面に光源(ランプ)を
配置し、背面電極板a側から光線を入射させた表示画面
の明るいバックライト型あるいはライトガイド型のラン
プ内蔵式透過型液晶表示装置が広く普及している。As a liquid crystal display device of this type,
A bright backlight for a display screen in which a light source (lamp) is arranged on the back surface or side surface of an electrode plate (hereinafter referred to as a back electrode plate) a located on the back side of a liquid crystal display device, and light rays are incident from the back electrode plate a side. Type or light guide type transmissive liquid crystal display device with a built-in lamp is widely used.
【0004】しかし、このランプ内蔵式透過型液晶表示
装置においては、そのランプによる消費電力が大きくC
RTやプラズマディスプレイ等他の種類のディスプレイ
と略同等の電力を消費するため、液晶表示装置本来の低
消費電力といった特徴を損ない、また、携帯先で長時間
の利用が困難となるという欠点を有していた。However, in this transmissive liquid crystal display device with a built-in lamp, the power consumed by the lamp is large.
Since it consumes substantially the same amount of power as other types of displays such as RTs and plasma displays, it has the drawbacks that the original low power consumption characteristics of liquid crystal display devices are impaired and that it becomes difficult to use it for a long time on the portable device. Was.
【0005】他方、このようなランプを内蔵することな
く、装置の観察者側に位置する電極板(観察者側電極板
と称する)bから室内光や自然光等の外光を入射させ、
上記背面電極板aに設けられた金属反射膜で反射させて
この反射光により画面表示する反射型液晶表示装置も知
られている。そして、この装置ではランプを利用しない
ことから消費電力が小さく、従って、携帯先の長時間駆
動に耐えるという利点を有している。On the other hand, without incorporating such a lamp, outside light such as room light or natural light is made incident from an electrode plate (referred to as an observer side electrode plate) b located on the observer side of the apparatus,
There is also known a reflection type liquid crystal display device which reflects on a metal reflection film provided on the back electrode plate a and displays a screen by this reflected light. Since this device does not use a lamp, it consumes less power, and therefore has the advantage that it can withstand the long-term driving of a portable device.
【0006】そして、このような反射型液晶表示装置に
はその背面電極板aとして、例えば、図5に示すように
基材a1と、この基材a1上に一様に形成された金属反
射膜a2と、この金属反射膜a2上にカラーフィルター
層a3R、a3G、a3Bを介して設けられた電圧印加
用透明電極a4とでその主要部が構成されるもの、ある
いは、図6に示すように上記金属反射膜a2が透明電極
a4とは反対側の基板a1面に一様に設けられた背面電
極板等が適用されている。In such a reflective liquid crystal display device, as the back electrode plate a, for example, as shown in FIG. 5, a base material a1 and a metal reflective film uniformly formed on the base material a1. a2 and a voltage application transparent electrode a4 provided on the metal reflection film a2 via color filter layers a3R, a3G, and a3B, or a main part thereof, or as shown in FIG. A back electrode plate or the like in which the metal reflection film a2 is uniformly provided on the surface of the substrate a1 opposite to the transparent electrode a4 is applied.
【0007】ところで、この種の反射型液晶表示装置に
おいては、上記金属反射膜a2が入射光線を正反射する
ためその外光の光源の位置によって視野角が制限される
という欠点を有していた。By the way, in this type of reflective liquid crystal display device, the metal reflection film a2 specularly reflects the incident light beam, so that the viewing angle is limited by the position of the light source of the external light. .
【0008】そこで、特開昭63−228887号公報
あるいは日本印刷学会主催のフォトファブリケーション
シンポジウム’92には、表面凹凸の金属薄膜を金属反
射膜a2として適用することによりこの金属反射膜a2
の正反射を防止して表示画面の視野角を拡大させた液晶
表示装置が紹介されている。すなわち、図7はこの液晶
表示装置を示す説明図で、この液晶表示装置の背面電極
板aは、基材a1と、この基材a1上に絶縁層a5を介
して設けられたTFT素子a6と、このTFT素子a6
上に設けられた表面凹凸の絶縁性樹脂層a7と、この絶
縁性樹脂層a7の凹凸表面に沿って設けられた画素形状
のアルミニウム薄膜製金属反射膜a2とで主要部が構成
されている。そして、この液晶表示装置においては上記
金属反射膜a2が絶縁性樹脂層a7の表面形状を反映し
て凹凸表面を有しているため、光を乱反射して表示画面
の視野角を拡大させることが可能になる。尚、この液晶
表示装置において上記TFT素子a6は、半導体部a6
2とこの半導体部a62をはさんでその両側に設けられ
たソース電極a61及びドレイン電極a63とで構成さ
れており、ドレイン電極a63と上記金属反射膜a2と
を絶縁層a7に設けられた貫通孔(コンタクトホール)
を通して導通させこの金属反射膜a2を液晶物質の駆動
電極として利用している。また、図7中、bは観察者側
電極板を示し、b1はその基材、b2は基材b1上に一
様に設けられた透明電極である。また、cは上記背面電
極板aと観察者側電極板bとの間に封入された液晶物
質、dは液晶表示装置の外周に設けられたシール材を示
している。Therefore, in Japanese Patent Laid-Open No. 63-228887 or Photofabrication Symposium '92 sponsored by The Japan Printing Society, a metal thin film having uneven surface is applied as the metal reflection film a2 to obtain the metal reflection film a2.
A liquid crystal display device has been introduced in which the viewing angle of the display screen is widened by preventing the regular reflection of. That is, FIG. 7 is an explanatory view showing this liquid crystal display device. The back electrode plate a of this liquid crystal display device includes a base material a1 and a TFT element a6 provided on the base material a1 via an insulating layer a5. , This TFT element a6
The insulating resin layer a7 having an uneven surface provided thereon and the pixel-shaped metal thin-film metal reflection film a2 provided along the uneven surface of the insulating resin layer a7 constitute a main part. In this liquid crystal display device, since the metal reflection film a2 has an uneven surface reflecting the surface shape of the insulating resin layer a7, light can be diffusely reflected to widen the viewing angle of the display screen. It will be possible. In this liquid crystal display device, the TFT element a6 is the semiconductor portion a6.
2 and a semiconductor electrode a62 and a source electrode a61 and a drain electrode a63 which are provided on both sides of the semiconductor portion a62. The drain electrode a63 and the metal reflection film a2 are provided in the insulating layer a7 as a through hole. (Contact hole)
This metal reflective film a2 is used as a drive electrode for the liquid crystal substance. Further, in FIG. 7, b represents an electrode plate on the observer side, b1 is a base material thereof, and b2 is a transparent electrode uniformly provided on the base material b1. Further, c is a liquid crystal substance enclosed between the back electrode plate a and the observer-side electrode plate b, and d is a sealing material provided on the outer periphery of the liquid crystal display device.
【0009】このように図7にて示された液晶表示装置
においては表示画面の視野角を拡大できる利点を有して
いるが、その反面、装置の製造に際して上記絶縁性樹脂
層a7を形成する工程とその表面に凹凸を付与する工程
が必要で、かつ、ドレイン電極a63と上記金属金属反
射膜a2とを導通させるため絶縁性樹脂層a7をドライ
エッチングしてコンタクトホールを形成する工程等が必
要となるため、その生産性と収率とが極めて低いという
欠点があった。また、この液晶表示装置においては、表
面凹凸の絶縁性樹脂層a7上に真空蒸着やスパッタリン
グ等の方法で上記金属反射膜a2を直接設ける必要があ
り、この形成段階において上記金属反射膜a2が酸化若
しくは水酸化され易いため、金属反射膜a2本来の反射
性能が損なわれる問題があった。As described above, the liquid crystal display device shown in FIG. 7 has an advantage that the viewing angle of the display screen can be widened, but on the other hand, the insulating resin layer a7 is formed at the time of manufacturing the device. A step and a step of providing unevenness on the surface are required, and a step of dry etching the insulating resin layer a7 to form a contact hole in order to electrically connect the drain electrode a63 and the metal-metal reflective film a2 is required. Therefore, there is a drawback that the productivity and the yield are extremely low. Further, in this liquid crystal display device, it is necessary to directly provide the metal reflection film a2 on the insulating resin layer a7 having the uneven surface by a method such as vacuum deposition or sputtering. At this formation stage, the metal reflection film a2 is oxidized. Alternatively, since it is easily hydroxylated, there is a problem that the original reflection performance of the metal reflection film a2 is impaired.
【0010】このような技術的背景の下、本出願人は上
記背面電極板又は観察者側電極板のいずれか一方に光散
乱層が設けられた液晶表示装置を既に提案している(特
願平5−102124号、特願平5−170280号等
参照)。Under such a technical background, the applicant of the present invention has already proposed a liquid crystal display device in which a light scattering layer is provided on either the back electrode plate or the viewer side electrode plate (Japanese Patent Application No. 2000-242242). See Japanese Patent Application No. 5-102124 and Japanese Patent Application No. 5-170280).
【0011】そして、この液晶表示装置によれば、透明
樹脂とこの透明樹脂中に分散されこの透明樹脂と屈折率
が異なる微粒子とでその主要部が構成される光散乱層の
作用により表示光が散乱されるため、外光光源の位置に
関わりなく表示画面の視野角を拡大でき、かつ、装置の
製造に際してはその工程が簡略できるため生産効率と収
率の向上が図れる利点を有していた。According to this liquid crystal display device, display light is generated by the action of the light scattering layer whose main part is composed of a transparent resin and fine particles dispersed in the transparent resin and having a refractive index different from that of the transparent resin. Since it is scattered, the viewing angle of the display screen can be expanded regardless of the position of the external light source, and the manufacturing process of the device can be simplified, which has the advantage of improving production efficiency and yield. .
【0012】[0012]
【発明が解決しようとする課題】しかし、上記液晶表示
装置においては、透明樹脂中にこの透明樹脂とその屈折
率が異なる微粒子が分散されているため、透明樹脂の屈
折率と微粒子の屈折率との相違、あるいは微粒子の複屈
折や光学的分散に起因して表示光が着色し易い問題点が
あった。However, in the above liquid crystal display device, since the fine particles having a refractive index different from that of the transparent resin are dispersed in the transparent resin, the refractive index of the transparent resin and the refractive index of the fine particles are different from each other. However, there is a problem that the display light is easily colored due to the difference between the two, or the birefringence or optical dispersion of the fine particles.
【0013】本発明はこのような問題点に着目してなさ
れたもので、その課題とするところは、反射型液晶表示
装置の利点を維持したまま、外光光源の位置に関わりな
く視野角が広く、しかも着色のない明るい画面表示を可
能にする反射型液晶表示装置を提供することにある。The present invention has been made by paying attention to such a problem, and its problem is that the viewing angle can be changed regardless of the position of the external light source while maintaining the advantages of the reflective liquid crystal display device. It is an object of the present invention to provide a reflective liquid crystal display device which enables a wide and bright screen display without coloring.
【0014】[0014]
【課題を解決するための手段】すなわち、請求項1に係
る発明は、金属反射層が設けられた背面電極板と、この
背面電極板に対向して配置されかつ透明電極が設けられ
た観察者側電極板と、これ等の電極板間に封入された液
晶物質とを備え、この液晶物質に対し画素毎に電圧を印
加して画面表示する反射型液晶表示装置を前提とし、上
記背面電極板又は観察者側電極板の少なくとも一方に、
透明樹脂とこの透明樹脂中に分散された微粒子とを主成
分とする光散乱層を設けると共に、上記微粒子が透明樹
脂より屈折率が小さく、その光学的平均分散が0.09
以下かつその複屈折が0.02以下であることを特徴と
するものである。That is, the invention according to claim 1 provides a back electrode plate provided with a metal reflection layer, and an observer provided facing the back electrode plate and provided with a transparent electrode. Assuming a reflective liquid crystal display device that includes a side electrode plate and a liquid crystal substance enclosed between these electrode plates and applies a voltage to each liquid crystal substance for each pixel to display a screen, the above-mentioned rear electrode plate Or on at least one of the observer-side electrode plates,
A light-scattering layer containing a transparent resin and fine particles dispersed in the transparent resin as a main component is provided, and the fine particles have a smaller refractive index than the transparent resin, and the optical average dispersion thereof is 0.09.
It is characterized in that it has a birefringence of 0.02 or less.
【0015】このような技術的手段において上記光散乱
層の一部を構成する微粒子としてその屈折率が透明樹脂
の屈折率より小さい材料を適用していることから表示画
面の視野角が極めて広くなるため、外光光源の位置に関
わりなく明るい画面を表示することが可能になる。In such a technical means, since the material having the refractive index smaller than that of the transparent resin is applied as the fine particles forming a part of the light scattering layer, the viewing angle of the display screen becomes extremely wide. Therefore, a bright screen can be displayed regardless of the position of the external light source.
【0016】尚、上記微粒子の屈折率が透明樹脂のそれ
より大きい場合(例えば、屈折率2.5〜2.9のTi
O2 を微粒子として分散させた場合)、光散乱効果が不
十分となり表示画面の視野角が十分拡大されない。図3
はこのことを示したグラフ図である。すなわち、硬膜後
の屈折率が1.57の感光性フェノールノボラックエポ
キシ樹脂中に、CaF2 (屈折率1.43)、PTFE
(ポリテトラフルオロエチレン、屈折率1.35)、及
び、TiO2 (屈折率2.49)のそれぞれの微粒子を
20重量%分散させ、かつ、溶剤としてセルソルブアセ
テートを使用して塗液を求め、この塗液をガラス基板上
に設けられた厚さ0.2μmのアルミニウム薄膜上に塗
布硬膜した後、各塗布硬膜に対しタングステンランプを
使用して視角(法線となす角)0〜60度の範囲で各塗
布硬膜の輝度を測定しこの結果を図3に示す。そして、
この図3から、上記フェノールノボラックエポキシ樹脂
よりその屈折率が小さいCaF2 やPTFEを微粒子と
して適用すると、上記樹脂よりその屈折率が大きいTi
O2 を微粒子として適用した場合に較べて視角10〜6
0度の範囲でその輝度が高く、視野角が広いことが確認
できる。When the refractive index of the fine particles is larger than that of the transparent resin (for example, Ti having a refractive index of 2.5 to 2.9).
When O 2 is dispersed as fine particles), the light scattering effect becomes insufficient and the viewing angle of the display screen is not sufficiently expanded. Figure 3
Is a graph showing this. That is, in a photosensitive phenol novolac epoxy resin having a refractive index of 1.57 after hardening, CaF 2 (refractive index 1.43), PTFE
(Polytetrafluoroethylene, refractive index 1.35) and TiO 2 (refractive index 2.49) fine particles were dispersed in 20% by weight respectively, and a coating solution was obtained using cellosolve acetate as a solvent. After coating and hardening this coating liquid on an aluminum thin film having a thickness of 0.2 μm provided on a glass substrate, a tungsten lamp is used for each coating hard film to form a visual angle (angle with the normal) 0 The brightness of each coated hard film was measured in the range of 60 degrees, and the results are shown in FIG. And
From FIG. 3, when CaF 2 or PTFE having a refractive index smaller than that of the phenol novolac epoxy resin is applied as fine particles, Ti having a refractive index larger than that of the resin is applied.
The viewing angle is 10 to 6 compared with the case where O 2 is applied as fine particles.
It can be confirmed that the brightness is high and the viewing angle is wide in the range of 0 degree.
【0017】また、この技術的手段において上記光学的
平均分散とは、波長0.486μmのF線に対する屈折
率nF と、波長0.656μmのC線に対する屈折率n
C との差(nF −nC )をいう。そして、請求項1に係
る発明においては上記微粒子の光学的平均分散が0.0
9以下であるため、透明樹脂と微粒子との界面において
光線が屈折する際、その屈折方向が光線の波長に依存す
ることがなく全ての可視光線が略同一方向に屈折する。
このため、光学的平均分散に基づく表示画面の着色を防
止することが可能となる。Further, in this technical means, the above-mentioned optical average dispersion means a refractive index n F for an F line having a wavelength of 0.486 μm and a refractive index n for a C line having a wavelength of 0.656 μm.
The difference with C (n F −n C ). In the invention according to claim 1, the optical average dispersion of the fine particles is 0.0
Since it is 9 or less, when the light rays are refracted at the interface between the transparent resin and the fine particles, all visible rays are refracted in substantially the same direction without the refraction direction depending on the wavelength of the light rays.
Therefore, it is possible to prevent the display screen from being colored due to the optical average dispersion.
【0018】次に、上記微粒子が光学的異方性を有する
場合にはこの微粒子中を進行する光線の偏光面に応じて
微粒子の屈折率が異なる。例えば、正方晶系結晶、六方
晶系結晶、菱面格子系結晶等の一軸異方性結晶において
は、これ等結晶の軸に垂直な偏光面を有する光線に対す
る屈折率と、上記結晶の軸に平行な偏光面を有する光線
に対する屈折率との二種類の屈折率がある。また、斜方
晶系結晶、単斜晶系結晶、三斜晶系結晶等の二軸異方性
結晶においては、光線の偏光面によって異なる三種類の
屈折率がある(これ等屈折率のうち最大のものと最小の
ものとの差を複屈折率という)。そして、これ等異方性
結晶に入射した光線は結晶中で互いに偏光面が直交する
各偏光に分離され、分離した偏光がそれぞれの屈折率に
応じた速度(屈折率の逆数に比例する)で進行するため
出射光線の着色を生じる。これに対し、微粒子の複屈折
が0.02以下の場合には複屈折が極めて小さいため、
複屈折に基づく表示画面の着色を防止することが可能と
なる。Next, when the fine particles have optical anisotropy, the refractive index of the fine particles varies depending on the plane of polarization of the light rays traveling in the fine particles. For example, in a uniaxial anisotropic crystal such as a tetragonal crystal, a hexagonal crystal, and a rhombic lattice crystal, the refractive index for a light beam having a polarization plane perpendicular to the axis of these crystals and the axis of the crystal There are two types of index of refraction, the index of refraction for light rays having parallel planes of polarization. Further, in biaxial anisotropic crystals such as orthorhombic crystals, monoclinic crystals, and triclinic crystals, there are three types of refractive indexes that differ depending on the plane of polarization of light rays (of these refractive indices, The difference between the maximum and the minimum is called birefringence). Then, the light rays incident on these anisotropic crystals are separated into respective polarized lights whose polarization planes are orthogonal to each other in the crystal, and the separated polarized lights have a speed (proportional to the reciprocal of the refractive index) corresponding to each refractive index. As it progresses, coloring of the emitted light beam occurs. On the other hand, when the birefringence of the fine particles is 0.02 or less, the birefringence is extremely small,
It is possible to prevent the display screen from being colored due to birefringence.
【0019】上述した各要件を具備する微粒子としては
無機物から成る微粒子と有機ポリマーから成る微粒子を
例示できる。そして、無機物から成る微粒子としては、
等軸晶と呼ばれる立方晶構造を有する微粒子、この等軸
晶に似て複屈折の小さい正方晶構造を有する微粒子、あ
るいは非晶質の微粒子が適用でき、例えば、CaF2、
MgF2 、SrF2 、LiF、NaF等のフッ素化合物
が適用できる。また、有機物から成る微粒子としては、
PTFE(ポリテトラフルオロエチレン)、PFA(ペ
ルフルオロアルコキシ樹脂)、FEP(テトラフルオロ
エチレン−ヘキサフルオロプロピレン共重合体)、PV
DF(ポリフルオロビニリデン)、ETFE(エチレン
−テトラフルオロエチレン共重合体)、PVF(ポリフ
ルオロビニル)等の含フッ素ポリマーを例示でき、ま
た、その他のポリマーにフッ素原子やフッ化アルキル基
を導入させたものであってもよい。Examples of the fine particles satisfying the above-mentioned requirements include fine particles made of an inorganic substance and fine particles made of an organic polymer. And as the fine particles composed of an inorganic substance,
Fine particles having a cubic crystal structure called an equiaxed crystal, fine particles having a tetragonal crystal structure having a small birefringence similar to the equiaxed crystal, or amorphous fine particles can be applied. For example, CaF 2 ,
Fluorine compounds such as MgF 2 , SrF 2 , LiF and NaF can be applied. Further, as the fine particles made of an organic substance,
PTFE (polytetrafluoroethylene), PFA (perfluoroalkoxy resin), FEP (tetrafluoroethylene-hexafluoropropylene copolymer), PV
Fluorine-containing polymers such as DF (polyfluorovinylidene), ETFE (ethylene-tetrafluoroethylene copolymer), PVF (polyfluorovinyl), etc. can be exemplified, and fluorine atoms and fluorinated alkyl groups can be introduced into other polymers. It may be
【0020】更に、これ等フッ素化合物や含フッ素ポリ
マーの表面に適当な表面処理を施したものを上記微粒子
として適用することも可能である。このような表面処理
の例としては、例えば、SiO2 、ZrO2 、Al2O
3 、ZnO、透明樹脂、カップリング剤、又は、界面活
性剤等を塗布被覆する処理が挙げられる。また、この
他、アルコール、あるいはアミンや有機酸等で表面反応
を生じさせたりする処理が例示できる。Further, it is also possible to apply those obtained by subjecting the surface of the fluorine compound or the fluorine-containing polymer to an appropriate surface treatment as the fine particles. Examples of such surface treatment include, for example, SiO 2 , ZrO 2 , Al 2 O
3 , a treatment of coating and coating with ZnO, a transparent resin, a coupling agent, a surfactant, or the like. In addition to this, a treatment of causing a surface reaction with alcohol, amine, organic acid or the like can be exemplified.
【0021】一方、上記微粒子の粒径としては、光散乱
効果を向上させるため可視光線の波長に近い0.05〜
1.0μmが望ましい。そして、この程度の粒径で複屈
折が0.02以下の微粒子を適用した場合、複屈折に起
因した表示画面の着色が実質的に生じない。尚、微粒子
の中に0.05μm未満のものや1.0μmを越えるも
のが多少混入されていてもよいが、液晶が封入される電
極板間距離より小さく、液晶の正常な配向状態を妨げな
い粒径であることが望ましい。またこれら微粒子の形状
としては、球形、円盤形、碁石形、多角形、菱形、正方
板形等の任意の形状であってよい。On the other hand, the particle size of the above-mentioned fine particles is 0.05 to near the wavelength of visible light in order to improve the light scattering effect.
1.0 μm is desirable. When fine particles having a particle diameter of this level and a birefringence of 0.02 or less are applied, coloring of the display screen due to the birefringence does not substantially occur. It should be noted that some particles smaller than 0.05 μm or larger than 1.0 μm may be mixed in the fine particles, but they are smaller than the distance between the electrode plates in which the liquid crystal is sealed and do not disturb the normal alignment state of the liquid crystal. A particle size is desirable. The shape of these fine particles may be any shape such as a sphere, a disc, a gostone, a polygon, a rhombus, and a square plate.
【0022】次に、上記微粒子を分散させる樹脂として
は、可視光線透過率が高く、また液晶表示装置の製造工
程中における熱処理や薬品処理に対する十分な耐性を具
備するものが望ましく、例えば、アクリル樹脂、エポキ
シ樹脂、ポリエステル樹脂、ウレタン樹脂、シリコン樹
脂、ポリイミド樹脂等が適用できる。また液晶表示装置
組み立ての際の必要性(例えば電気的接続のための配線
を設ける場合等)から、光散乱層をパターン状に設ける
場合には感光性と現像性とを有するアクリル系樹脂やエ
ポキシ系樹脂を利用してもよい。また、熱硬化性樹脂や
紫外線硬化型樹脂を利用することも可能である。Next, as the resin in which the above-mentioned fine particles are dispersed, a resin having a high visible light transmittance and having sufficient resistance to heat treatment and chemical treatment during the manufacturing process of the liquid crystal display device is desirable. For example, acrylic resin. , Epoxy resin, polyester resin, urethane resin, silicone resin, polyimide resin, etc. can be applied. When the light scattering layer is provided in a pattern, it is necessary to assemble the liquid crystal display device (for example, when wiring for electrical connection is provided). Therefore, an acrylic resin or epoxy having photosensitivity and developability is used. A system resin may be used. It is also possible to use a thermosetting resin or an ultraviolet curable resin.
【0023】尚、上記光散乱層は、微粒子を透明樹脂中
に混合・分散して透明基板上に塗布し、かつ、乾燥する
ことにより形成することが可能である。その塗布の方法
としては、フレキソ印刷法、スクリーン印刷法、オフセ
ット印刷法、ロールコート法等が適用できる。The light-scattering layer can be formed by mixing and dispersing fine particles in a transparent resin, coating the transparent substrate with the fine particles, and drying. As the coating method, a flexographic printing method, a screen printing method, an offset printing method, a roll coating method or the like can be applied.
【0024】また、上記光散乱層は液晶表示装置を構成
する観察者側電極板と背面電極板のいずれに設けてもよ
いが、表示画面を構成する表示光の光路内に設けること
を要する。The light-scattering layer may be provided on either the observer-side electrode plate or the back electrode plate that constitutes the liquid crystal display device, but it is necessary to provide it on the optical path of the display light that constitutes the display screen.
【0025】次に、この技術的手段において背面電極板
に設けられる金属反射層としては、銀、アルミニウム、
アルミニウム合金、マグネシウム、ニッケル、チタン、
クロム等の可視光線反射率の高い金属の薄膜やこれ等薄
膜を多数積層して構成される多層の金属薄膜が適用でき
る。尚、この金属反射膜をストライプ状又は画素形状に
パターニングして液晶駆動用電極として利用することも
できる。また、この金属反射膜上に更に透明薄膜を積層
してもよい。このような透明薄膜としては、酸化インジ
ウムの中にドーパントとして酸化錫を混合して構成され
るITO薄膜、酸化インジウム薄膜、酸化珪素薄膜、酸
化アルミニウム薄膜、酸化ジルコニウム薄膜、酸化マグ
ネシウム薄膜等が利用できる。また、上記金属反射膜を
表示画面の全面又は画素形状等のパターン状に形成し、
この金属反射膜上に透明絶縁層を介して液晶駆動用透明
電極を設けることもできる。このような透明電極として
は、上記ITO薄膜の他、酸化インジウムに酸化チタ
ン、酸化鉛、酸化アンチモン、酸化ビスマス、酸化ハフ
ニウムあるいは酸化イットリウムを添加して成る薄膜、
酸化亜鉛に酸化アルミニウムを添加して成る薄膜、ある
いはこれらの薄膜を多数積層して成る多層膜が利用でき
る。Next, as the metal reflective layer provided on the back electrode plate in this technical means, silver, aluminum,
Aluminum alloy, magnesium, nickel, titanium,
A thin film of a metal such as chromium having a high visible light reflectance or a multi-layered metal thin film formed by laminating a large number of these thin films can be applied. The metal reflection film may be patterned into a stripe shape or a pixel shape to be used as a liquid crystal driving electrode. Further, a transparent thin film may be further laminated on this metal reflection film. As such a transparent thin film, an ITO thin film composed of indium oxide mixed with tin oxide as a dopant, an indium oxide thin film, a silicon oxide thin film, an aluminum oxide thin film, a zirconium oxide thin film, a magnesium oxide thin film and the like can be used. . Further, the metal reflection film is formed on the entire surface of the display screen or in a pattern such as a pixel shape,
A transparent electrode for driving a liquid crystal can be provided on the metal reflection film via a transparent insulating layer. As such a transparent electrode, in addition to the ITO thin film, a thin film obtained by adding titanium oxide, lead oxide, antimony oxide, bismuth oxide, hafnium oxide or yttrium oxide to indium oxide,
A thin film formed by adding aluminum oxide to zinc oxide, or a multilayer film formed by laminating a large number of these thin films can be used.
【0026】他方、上記観察者側電極板に設けられる透
明電極としては、上記ITO薄膜、酸化インジウムに酸
化チタン、酸化鉛、酸化アンチモン、酸化ビスマス、酸
化ハフニウムあるいは酸化イットリウムを添加して成る
薄膜、酸化亜鉛に酸化アルミニウムを添加して成る薄
膜、あるいはこれらの薄膜を多数積層して成る多層膜が
利用できる。On the other hand, as the transparent electrode provided on the observer side electrode plate, a thin film obtained by adding titanium oxide, lead oxide, antimony oxide, bismuth oxide, hafnium oxide or yttrium oxide to the ITO thin film, indium oxide, A thin film formed by adding aluminum oxide to zinc oxide, or a multilayer film formed by laminating a large number of these thin films can be used.
【0027】また、請求項1記載の発明に係る反射型液
晶表示装置においては表示光の着色がなく白色光による
表示が可能であることから、その表示光の光路内にこの
表示光を着色するカラーフィルター層を設けることによ
りカラー画面の表示が可能となる。このカラーフィルタ
ー層としては周知のものが利用でき、例えば、着色剤を
含む印刷インキを印刷して形成された印刷法によるカラ
ーフィルター層、感光性樹脂を塗布しフォトリソグラフ
ィ法に従ってパターン状に露光・現像した後残存する感
光性樹脂を染料で染色して得られる染色法によるカラー
フィルター層、着色剤を分散させた感光性樹脂を塗布し
フォトリソグラフィ法に従ってパターン状に露光・現像
して得られる顔料分散法によるカラーフィルター層等を
利用することができる。また、この他、着色材を含む電
着樹脂を画素毎に電着させて製造した電着法によるカラ
ーフィルター層を利用することも可能である。In the reflective liquid crystal display device according to the first aspect of the present invention, since display light is not colored and white light can be displayed, the display light is colored in the optical path of the display light. A color screen can be displayed by providing a color filter layer. As this color filter layer, a well-known one can be used. For example, a color filter layer formed by printing a printing ink containing a colorant by a printing method, a photosensitive resin is applied, and a pattern is exposed by a photolithography method. A color filter layer obtained by dyeing the photosensitive resin remaining after development, a pigment obtained by applying a photosensitive resin in which a colorant is dispersed and exposing and developing it in a pattern according to the photolithography method. A color filter layer or the like prepared by a dispersion method can be used. In addition to this, it is also possible to use a color filter layer by an electrodeposition method which is manufactured by electrodepositing an electrodeposition resin containing a coloring material for each pixel.
【0028】尚、上記背面電極板の基板としては、ガラ
ス板やプラスチック板又はプラスチックフィルム等の透
明な基板の他、黒色等に着色された不透明な基板を適用
することが可能である。As the substrate of the back electrode plate, it is possible to use a transparent substrate such as a glass plate, a plastic plate, or a plastic film, or an opaque substrate colored in black or the like.
【0029】[0029]
【作用】請求項1に係る発明によれば、背面電極板又は
観察者側電極板の少なくとも一方に、透明樹脂とこの透
明樹脂中に分散された微粒子とを主成分とする光散乱層
を設けており、かつ、透明樹脂よりその屈折率が小さい
微粒子を適用しているため、表示画面の視野角を増大さ
せることが可能となる。According to the invention of claim 1, a light scattering layer containing a transparent resin and fine particles dispersed in the transparent resin as a main component is provided on at least one of the back electrode plate and the observer-side electrode plate. In addition, since fine particles having a smaller refractive index than the transparent resin are used, the viewing angle of the display screen can be increased.
【0030】また、上記微粒子の光学的平均分散が0.
09以下かつその複屈折が0.02以下であるため、光
学的平均分散や複屈折に基づく表示画面の着色防止を図
ることが可能となる。The optical average dispersion of the fine particles is 0.
Since it is 09 or less and its birefringence is 0.02 or less, it is possible to prevent coloration of the display screen based on optical average dispersion and birefringence.
【0031】[0031]
【実施例】以下、図面を参照して本発明の実施例につい
て詳細に説明する。Embodiments of the present invention will now be described in detail with reference to the drawings.
【0032】[実施例1]この実施例に係る反射型液晶
表示装置は、図1に示すように背面電極板1と、この背
面電極板1に対向して設けられた観察者側電極板2と、
これ等電極板1、2間に封入された液晶物質3と、図示
しない偏光板及び位相差板とでその主要部が構成されて
いる。また、上記背面電極板1は、透明基板10と、こ
の透明基板10上の画面表示領域にピッチ300μm、
幅290μmで計480本のストライプパターンに設け
られた厚さ0.2μmのアルミニウム製金属反射膜11
と、この金属反射膜11上にこの金属反射膜11と同一
パターンに設けられた厚さ0.07μmのITO薄膜1
2とでその主要部が構成されている。他方、観察者側電
極板2は、透明基板20と、表示領域の全面に一様に設
けられた光散乱層21と、この光散乱層21上にピッチ
300μm、幅290μmの計640本のストライプパ
ターンに設けられた厚さ約1.0μmのITO薄膜22
(面積抵抗率約7Ω/□)とでその主要部が構成されて
いる。また、上記金属反射膜11とITO薄膜22とは
互いに直交する方向のストライプパターンに設けられ、
金属反射膜11を走査線としITO薄膜22を信号線と
して両者の間に電圧を印加することによりその交差位置
の液晶物質が駆動されて画面表示を図れるように構成さ
れている。[Embodiment 1] As shown in FIG. 1, a reflective liquid crystal display device according to this embodiment includes a back electrode plate 1 and an observer-side electrode plate 2 provided opposite to the back electrode plate 1. When,
The liquid crystal substance 3 enclosed between the electrode plates 1 and 2 and a polarizing plate and a retardation plate (not shown) form a main part. The back electrode plate 1 has a transparent substrate 10 and a pitch of 300 μm in a screen display region on the transparent substrate 10.
A metal reflection film 11 made of aluminum having a width of 290 μm and a thickness of 0.2 μm provided in a total of 480 stripe patterns.
And an ITO thin film 1 having a thickness of 0.07 μm formed on the metal reflection film 11 in the same pattern as the metal reflection film 11.
The main part is composed of 2 and. On the other hand, the viewer-side electrode plate 2 has a transparent substrate 20, a light-scattering layer 21 uniformly provided on the entire surface of the display region, and a total of 640 stripes having a pitch of 300 μm and a width of 290 μm on the light-scattering layer 21. ITO thin film 22 provided in a pattern and having a thickness of about 1.0 μm
(Area resistivity of about 7Ω / □) constitutes the main part. Further, the metal reflection film 11 and the ITO thin film 22 are provided in a stripe pattern in directions orthogonal to each other,
By applying a voltage between the metal reflective film 11 as a scanning line and the ITO thin film 22 as a signal line, the liquid crystal substance at the intersection is driven so that a screen display can be achieved.
【0033】尚、上記光散乱層21は、硬膜時の屈折率
が1.57の感光性フェノールノボラックエポキシ樹脂
中にCaF2 (屈折率:1.43、光学的平均分散:
0.005、複屈折率:0)を22重量%分散させたも
のから構成されている。The light-scattering layer 21 has CaF 2 (refractive index: 1.43, optical average dispersion :) in a photosensitive phenol novolac epoxy resin having a refractive index of 1.57 when hardened.
22% by weight of 0.005, birefringence: 0).
【0034】また、上記金属反射膜11とITO薄膜1
2とは、透明基板20上に連続して金属薄膜とITO薄
膜を成膜し、かつ、フォトリソグラフィ法に従ってIT
O薄膜をパターニングした後、残存するITO薄膜をエ
ッチングレジストとして金属薄膜をエッチングし形成し
たものである。The metal reflection film 11 and the ITO thin film 1 are also provided.
2 means that the metal thin film and the ITO thin film are continuously formed on the transparent substrate 20, and the IT is performed according to the photolithography method.
This is formed by patterning the O thin film and then etching the metal thin film using the remaining ITO thin film as an etching resist.
【0035】そして、上記金属反射膜11とITO薄膜
22の間に電圧を印加して画面表示したところ、その画
面は着色のない白色で、しかも視野角も広く、画面法線
に対し60度の角度から見ても良好に表示画面を認識す
ることができた。When a screen was displayed by applying a voltage between the metal reflection film 11 and the ITO thin film 22, the screen was white without coloring and had a wide viewing angle of 60 degrees with respect to the normal to the screen. The display screen could be recognized well even from an angle.
【0036】[実施例2]この実施例に係る反射型液晶
表示装置は、図2に示すように背面電極板4と、この背
面電極板4に対向して設けられた観察者側電極板5と、
これ等電極板4、5間に封入された液晶物質6と、図示
しない偏光板及び位相差板とでその主要部が構成されて
いる。また、上記背面電極板4は、透明基板40と、こ
の透明基板40上の画面表示領域にピッチ300μm、
幅290μmで計480本のストライプパターンに設け
られた厚さ0.15μmのアルミニウム製金属反射膜4
1と、この金属反射膜41上にこの金属反射膜41と同
一パターンに設けられた厚さ0.06μmのITO薄膜
42とでその主要部が構成されている。他方、観察者側
電極板5は、透明基板50と、この透明基板50の画面
表示領域の画素と画素との間の部位にピッチ100μm
で計1921本設けられたブラックストライプ53と、
これらブラックストライプの間の画素部位にストライプ
状に計1920本設けられた三色(赤色、緑色、青色)
のカラーフィルター層54R、54G、54Bと、これ
らブラックストライプ51及びカラーフィルター層54
R、54G、54Bを被覆して画面表示領域の全面に一
様に設けられた厚さ約1μmの光散乱層51と、この光
散乱層51の上記画素部位にピッチ100μm、幅90
μmのストライプ状に計1920本設けられたITO薄
膜52(面積抵抗率約8Ω/□)とで主要部が構成され
ている。また、金属反射膜41とITO薄膜52とは互
いに直交する方向のストライプパターンに設けられ、金
属反射膜41を走査線としITO薄膜52を信号線とし
て両者の間に電圧を印加することによりその交差位置の
液晶物質が駆動されて画面表示を図れるように構成され
ている。[Embodiment 2] In the reflection type liquid crystal display device according to this embodiment, as shown in FIG. 2, a back electrode plate 4 and an observer side electrode plate 5 provided facing the back electrode plate 4. When,
The liquid crystal substance 6 enclosed between the electrode plates 4 and 5 and a polarizing plate and a retardation plate (not shown) form a main part. The back electrode plate 4 has a transparent substrate 40 and a pitch of 300 μm in a screen display area on the transparent substrate 40.
A metal reflection film 4 made of aluminum having a width of 290 μm and a thickness of 0.15 μm provided in a total of 480 stripe patterns.
1 and an ITO thin film 42 having a thickness of 0.06 μm, which is provided on the metal reflection film 41 in the same pattern as the metal reflection film 41, constitutes its main part. On the other hand, the observer-side electrode plate 5 has a pitch of 100 μm between the transparent substrate 50 and a portion between pixels in the screen display area of the transparent substrate 50.
With a total of 1921 black stripes 53,
Three colors (red, green, blue) with a total of 1920 stripes in the pixel area between these black stripes
Color filter layers 54R, 54G, and 54B, and these black stripes 51 and color filter layers 54
A light-scattering layer 51 having a thickness of about 1 μm, which is uniformly provided on the entire surface of the screen display region by covering R, 54G, and 54B, and a pitch of 100 μm and a width of 90 at the pixel portion of the light-scattering layer 51.
The ITO thin film 52 (area resistivity of about 8 Ω / □), which is provided in 1920 stripes in total, constitutes the main part. Further, the metal reflection film 41 and the ITO thin film 52 are provided in a stripe pattern in a direction orthogonal to each other, and the metal reflection film 41 is used as a scanning line and the ITO thin film 52 is used as a signal line to apply a voltage between them to intersect each other. The liquid crystal material at the position is driven so that a screen display can be achieved.
【0037】尚、上記光散乱層51は、硬膜時の屈折率
が1.57の感光性フェノールノボラックエポキシ樹脂
中にMaF2 (屈折率:1.38、光学的平均分散:
0.006、複屈折率:0.012)を約18重量%分
散させたものから構成されている。The light-scattering layer 51 is made of a photosensitive phenol novolac epoxy resin having a refractive index of 1.57 when hardened with MaF 2 (refractive index: 1.38, optical average dispersion:
0.006 and birefringence: 0.012) are dispersed in about 18% by weight.
【0038】また、上記カラーフィルター層54R、5
4G、54Bは、エポキシ樹脂を樹脂成分とし、有機顔
料を着色剤成分として凹版オフセット印刷により形成し
たものである。Further, the color filter layers 54R, 5R
4G and 54B are formed by intaglio offset printing using an epoxy resin as a resin component and an organic pigment as a colorant component.
【0039】一方、上記金属反射膜41とITO薄膜4
2とは、透明基板40上に連続して金属薄膜とITO薄
膜とを成膜し、かつ、フォトリソグラフィ法に従ってI
TO薄膜をパターニングした後、残存するITO薄膜を
エッチングレジストとして金属薄膜をエッチングし形成
したものである。On the other hand, the metal reflection film 41 and the ITO thin film 4
2 means that a metal thin film and an ITO thin film are continuously formed on the transparent substrate 40, and I is formed according to the photolithography method.
This is formed by patterning the TO thin film and then etching the metal thin film using the remaining ITO thin film as an etching resist.
【0040】そして、上記金属反射膜41とITO薄膜
52の間に電圧を印加して画面表示したところ、その画
面は色純度が高い鮮やかなもので、しかも視野角も広く
画面法線に対し60度の角度から見ても良好に表示画面
を認識することができた。When a screen was displayed by applying a voltage between the metal reflection film 41 and the ITO thin film 52, the screen was vivid with high color purity, and the viewing angle was wide and the screen normal angle was 60. The display screen could be recognized well even when viewed from the angle of degrees.
【0041】[0041]
【発明の効果】請求項1に係る発明によれば、表示画面
の視野角を増大でき、かつ、光学的平均分散や複屈折に
基づく表示画面の着色を防止できるため、外光光源の位
置に関わりなく着色のない明るい画面表示が可能となる
効果を有している。According to the invention of claim 1, the viewing angle of the display screen can be increased, and the display screen can be prevented from being colored due to optical average dispersion or birefringence. It has the effect of enabling a bright screen display without coloring regardless of the color.
【図1】実施例1に係る液晶表示装置の断面図。FIG. 1 is a cross-sectional view of a liquid crystal display device according to a first embodiment.
【図2】実施例2に係る液晶表示装置の断面図。FIG. 2 is a cross-sectional view of a liquid crystal display device according to a second embodiment.
【図3】微粒子の屈折率に伴う視角と輝度との関係を示
すグラフ図。FIG. 3 is a graph showing the relationship between the viewing angle and the brightness according to the refractive index of fine particles.
【図4】従来例に係る液晶表示装置の断面図。FIG. 4 is a cross-sectional view of a liquid crystal display device according to a conventional example.
【図5】従来例に係る背面電極板の断面図。FIG. 5 is a cross-sectional view of a back electrode plate according to a conventional example.
【図6】従来例に係る背面電極板の断面図。FIG. 6 is a cross-sectional view of a back electrode plate according to a conventional example.
【図7】従来例に係る反射型液晶表示装置の断面図。FIG. 7 is a cross-sectional view of a reflective liquid crystal display device according to a conventional example.
1 背面電極板 2 観察者側電極板 3 液晶物質 4 背面電極板 5 観察者側電極板 6 液晶物質 10 透明基板 11 金属反射膜 12 ITO薄膜 20 透明基板 21 光散乱層 22 ITO薄膜 40 透明基板 41 金属反射膜 42 ITO薄膜 50 透明基板 51 光散乱層 52 ITO薄膜 53 ブラックストライプ 54R カラーフィルター層 54G カラーフィルター層 54B カラーフィルター層 1 Rear Electrode Plate 2 Observer Side Electrode Plate 3 Liquid Crystal Substance 4 Rear Electrode Plate 5 Observer Side Electrode Plate 6 Liquid Crystal Substance 10 Transparent Substrate 11 Metal Reflective Film 12 ITO Thin Film 20 Transparent Substrate 21 Light Scattering Layer 22 ITO Thin Film 40 Transparent Substrate 41 Metal reflective film 42 ITO thin film 50 Transparent substrate 51 Light scattering layer 52 ITO thin film 53 Black stripe 54R Color filter layer 54G Color filter layer 54B Color filter layer
Claims (1)
の背面電極板に対向して配置されかつ透明電極が設けら
れた観察者側電極板と、これ等の電極板間に封入された
液晶物質とを備え、この液晶物質に対し画素毎に電圧を
印加して画面表示する反射型液晶表示装置において、 上記背面電極板又は観察者側電極板の少なくとも一方
に、透明樹脂とこの透明樹脂中に分散された微粒子とを
主成分とする光散乱層を設けると共に、上記微粒子が透
明樹脂より屈折率が小さく、その光学的平均分散が0.
09以下かつその複屈折が0.02以下であることを特
徴とする反射型液晶表示装置。1. A back electrode plate provided with a metal reflective layer, an observer-side electrode plate provided facing the back electrode plate and provided with transparent electrodes, and enclosed between these electrode plates. A liquid crystal substance, wherein a liquid crystal substance is applied to each pixel to display a screen by applying a voltage to the liquid crystal substance, a transparent resin and the transparent resin are provided on at least one of the back electrode plate and the observer side electrode plate. A light-scattering layer containing, as a main component, fine particles dispersed in a resin is provided, and the fine particles have a smaller refractive index than the transparent resin, and the optical average dispersion thereof is 0.
A reflective liquid crystal display device having a birefringence of not more than 09 and not more than 0.02.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP5241860A JP2921356B2 (en) | 1993-09-28 | 1993-09-28 | Reflective liquid crystal display |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP5241860A JP2921356B2 (en) | 1993-09-28 | 1993-09-28 | Reflective liquid crystal display |
Publications (2)
Publication Number | Publication Date |
---|---|
JPH0798452A true JPH0798452A (en) | 1995-04-11 |
JP2921356B2 JP2921356B2 (en) | 1999-07-19 |
Family
ID=17080599
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP5241860A Expired - Fee Related JP2921356B2 (en) | 1993-09-28 | 1993-09-28 | Reflective liquid crystal display |
Country Status (1)
Country | Link |
---|---|
JP (1) | JP2921356B2 (en) |
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