JP2002196336A - Liquid crystal display device - Google Patents

Liquid crystal display device

Info

Publication number
JP2002196336A
JP2002196336A JP2000392815A JP2000392815A JP2002196336A JP 2002196336 A JP2002196336 A JP 2002196336A JP 2000392815 A JP2000392815 A JP 2000392815A JP 2000392815 A JP2000392815 A JP 2000392815A JP 2002196336 A JP2002196336 A JP 2002196336A
Authority
JP
Japan
Prior art keywords
liquid crystal
substrate
alignment
alignment film
display device
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.)
Pending
Application number
JP2000392815A
Other languages
Japanese (ja)
Inventor
Takeshi Suzaki
剛 須崎
Hiroyuki Kase
裕之 賀勢
Yoshitaka Mori
善隆 森
Shinichiro Tanaka
慎一郎 田中
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Tokyo Sanyo Electric Co Ltd
Sanyo Electric Co Ltd
Original Assignee
Tokyo Sanyo Electric Co Ltd
Tottori Sanyo Electric Co Ltd
Sanyo Electric Co Ltd
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by Tokyo Sanyo Electric Co Ltd, Tottori Sanyo Electric Co Ltd, Sanyo Electric Co Ltd filed Critical Tokyo Sanyo Electric Co Ltd
Priority to JP2000392815A priority Critical patent/JP2002196336A/en
Publication of JP2002196336A publication Critical patent/JP2002196336A/en
Pending legal-status Critical Current

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  • Liquid Crystal (AREA)
  • Devices For Indicating Variable Information By Combining Individual Elements (AREA)

Abstract

PROBLEM TO BE SOLVED: To provide a liquid crystal display device manufactured in a simplified manufacturing process and having different alignment sections in a pixel. SOLUTION: The liquid crystal display device is provided with a first substrate 1 having a pixel electrode 2 formed thereon, a second substrate 8 having a counter electrode 7 formed thereon, alignment layers 4 and 6 layered on the both substrates 1 and 8, respectively, and having a vertical alignment property and a liquid crystal layer 5 encapsulated between the substrates 1 and 8 and having negative dielectric anisotropy. A line shaped protrusion 3 is formed on the pixel electrode 2 and the alignment layer 6 on the second substrate 8 side is subjected to rubbing treatment in the direction nearly parallel to the protrusion 3 after irradiated with non-polarized UV.

Description

【発明の詳細な説明】DETAILED DESCRIPTION OF THE INVENTION

【0001】[0001]

【発明の属する技術分野】本発明は広視野角な液晶表示
装置に関する。
The present invention relates to a liquid crystal display device having a wide viewing angle.

【0002】[0002]

【従来の技術】液晶表示装置には薄型、軽量という特徴
があり、携帯端末から大型テレビに至るまで幅広く利用
されている。特にテレビなどに用いる場合には広視野角
が要求され、例えば1画素を複数の領域に分割し、領域
毎に異なる配向区分を形成して視野角を改善したものが
提案されている。このような液晶表示装置が特開平9−
61825号公報に開示されている。これは垂直配向膜
を設けた一対の基板間に誘電率異方性が負の液晶を挟持
する。そして液晶層に電圧を印加しない時は液晶分子が
基板に対して垂直に配列し、電圧を印加した時は液晶分
子が1画素内で2以上の異なる傾斜方向に傾斜する。1
画素を2つ領域に分割し、互いに配向方向が逆方向なる
場合の配向処理を以下に説明する。まず垂直配向性の配
向膜にラビング法により1度目の配向処理を行う。この
ときの配向方向が第1の領域の配向方向になる。次に配
向膜上にレジスト膜をパターンニング形成する。これは
例えばポジ型レジストをスピンコート法によって全面塗
布し、露光及び現像を行って、第1の領域にレジストパ
ターンを形成する。そしてラビング法により2度目の配
向処理を行い、レジストパターンの存在しない第2の領
域の配向膜表面を配向処理する。第2の領域では第1の
領域の配向方向と逆方向になるため、2度目の配向処理
は1度目の配向処理方向と180度異なる方向にラビン
グする。配向処理後にはレジスト剥離を兼ねた洗浄を行
う。
2. Description of the Related Art Liquid crystal display devices are characterized by being thin and lightweight, and are widely used from portable terminals to large televisions. In particular, when used for a television or the like, a wide viewing angle is required. For example, a device in which one pixel is divided into a plurality of regions and different orientation sections are formed for each region to improve the viewing angle has been proposed. Such a liquid crystal display device is disclosed in
No. 61825. This means that a liquid crystal having a negative dielectric anisotropy is sandwiched between a pair of substrates provided with a vertical alignment film. When no voltage is applied to the liquid crystal layer, the liquid crystal molecules are arranged perpendicular to the substrate, and when a voltage is applied, the liquid crystal molecules are inclined in two or more different inclination directions within one pixel. 1
An alignment process in a case where a pixel is divided into two regions and the alignment directions are opposite to each other will be described below. First, a first alignment treatment is performed on a vertically oriented alignment film by a rubbing method. The orientation direction at this time is the orientation direction of the first region. Next, a resist film is patterned on the alignment film. In this method, for example, a positive resist is applied on the entire surface by spin coating, and exposure and development are performed to form a resist pattern in the first region. Then, a second alignment process is performed by a rubbing method, and an alignment process is performed on the alignment film surface in the second region where no resist pattern exists. Since the direction of the second region is opposite to the direction of the orientation of the first region, the second alignment is rubbed in a direction 180 degrees different from the direction of the first alignment. After the alignment treatment, cleaning is performed which also serves as resist removal.

【0003】[0003]

【発明が解決しようとする課題】しかしながら上記の方
法では、第2の領域にそれぞれ異なる方向のラビング処
理を2度行うために均一な配向状態にすることが難し
く、生産性が良くなかった。また、ラビング処理は配向
膜をレーヨンなどの布で擦るため、クリーンルーム内に
粉塵が発生したり、静電気が発生してアクティブマトリ
クスのTFTが破壊される問題があった。
However, in the above-mentioned method, since the rubbing treatments in the different directions are performed twice on the second regions, it is difficult to obtain a uniform alignment state, and the productivity is not good. Further, in the rubbing treatment, since the alignment film is rubbed with a cloth such as rayon, there is a problem that dust is generated in a clean room or static electricity is generated and TFTs of an active matrix are destroyed.

【0004】そこで本発明は、製造工程を簡単にして1
画素内に異なる配向区分を有する液晶表示装置を提供す
ることを目的とする。
Accordingly, the present invention has simplified the manufacturing process and
An object of the present invention is to provide a liquid crystal display device having different alignment sections in a pixel.

【0005】[0005]

【課題を解決するための手段】上記課題を解決するため
に本発明は、各画素毎に画素電極が形成された第一基板
と、対向電極が形成された第二基板と、両基板上に積層
された垂直配向性を有する配向膜と、基板間に封入され
た負の誘電率異方性を有する液晶層とを備え、前記基板
のどちらか一方には各画素に対応して線状の突起又はス
リットが形成され、他方の基板の配向膜には無偏光の紫
外線の照射処理と突起又はスリットの略平行方向に水平
配向処理が施されていることを特徴とする。
According to the present invention, there is provided a first substrate having a pixel electrode formed for each pixel, a second substrate having a counter electrode formed thereon, and An alignment film having a stacked vertical alignment and a liquid crystal layer having a negative dielectric anisotropy sealed between substrates are provided, and one of the substrates has a linear shape corresponding to each pixel. A projection or a slit is formed, and the alignment film of the other substrate is subjected to irradiation treatment with non-polarized ultraviolet light and horizontal alignment processing in a direction substantially parallel to the projection or the slit.

【0006】また、画素電極が形成された基板と対向電
極が形成された基板との間に誘電率異方性が負の液晶を
封入し、両基板に垂直配向性を有する配向膜を積層した
液晶表示装置において、各画素を複数の領域に分割し、
各領域では、一方の基板の配向膜に無偏光の紫外線の照
射処理と水平配向処理を施し、他方の基板の配向膜に水
平配向処理を施し、電圧印加時に無偏光紫外線の照射処
理が施されていない配向膜によって液晶分子の傾斜方向
が規制されると共に隣接する領域の液晶分子の傾斜方向
が異なることを特徴とする。
A liquid crystal having a negative dielectric anisotropy is sealed between a substrate on which a pixel electrode is formed and a substrate on which a counter electrode is formed, and an alignment film having vertical alignment is laminated on both substrates. In a liquid crystal display device, each pixel is divided into a plurality of regions,
In each area, the alignment film of one substrate is subjected to irradiation treatment with non-polarized ultraviolet light and horizontal alignment treatment, the alignment film of the other substrate is subjected to horizontal alignment treatment, and irradiation treatment of non-polarized ultraviolet light is performed when voltage is applied. The tilt direction of the liquid crystal molecules is regulated by the alignment film which is not provided, and the tilt direction of the liquid crystal molecules in the adjacent region is different.

【0007】また、各画素毎に画素電極が形成された第
一基板と、対向電極が形成された第二基板と、前記両基
板上に積層された垂直配向性を有する配向膜と、前記基
板間に封入された負の誘電率異方性を有する液晶層とを
備え、前記基板のどちらか一方には各画素に対応して線
状の突起又はスリットが形成され、他方の基板の配向膜
には直線偏光の紫外線をその振幅方向をずらしながら複
数回照射する処理と前記突起又は前記スリットの略平行
方向に水平配向処理が施されていることを特徴とする。
A first substrate on which a pixel electrode is formed for each pixel; a second substrate on which a counter electrode is formed; an alignment film having vertical alignment laminated on the two substrates; A liquid crystal layer having a negative dielectric anisotropy encapsulated therebetween, and a linear projection or slit is formed on one of the substrates corresponding to each pixel, and an alignment film on the other substrate is provided. Are characterized by being subjected to a process of irradiating linearly polarized ultraviolet light a plurality of times while shifting the amplitude direction thereof, and a horizontal alignment process in a direction substantially parallel to the projection or the slit.

【0008】また、画素電極が形成された基板と対向電
極が形成された基板との間に誘電率異方性が負の液晶を
封入し、両基板に垂直配向性を有する配向膜を積層した
液晶表示装置において、各画素を複数の領域に分割し、
各領域では、一方の基板の配向膜に直線偏光の紫外線を
その振幅方向をずらしながら複数回照射する処理と水平
配向処理を施し、他方の基板の配向膜に水平配向処理を
施し、電圧印加時に直線偏光の紫外線の照射処理が施さ
れていない配向膜によって液晶分子の傾斜方向が規制さ
れると共に隣接する領域の液晶分子と傾斜方向が異なる
ことを特徴とする。
Further, a liquid crystal having a negative dielectric anisotropy is sealed between a substrate on which a pixel electrode is formed and a substrate on which a counter electrode is formed, and an alignment film having vertical alignment is laminated on both substrates. In a liquid crystal display device, each pixel is divided into a plurality of regions,
In each region, the alignment film of one substrate is subjected to a process of irradiating linearly polarized ultraviolet light a plurality of times while shifting its amplitude direction and a horizontal alignment process, and the alignment film of the other substrate is subjected to a horizontal alignment process. The orientation direction of the liquid crystal molecules is regulated by the alignment film that has not been subjected to the irradiation treatment with the linearly polarized ultraviolet rays, and the inclination direction is different from that of the liquid crystal molecules in an adjacent region.

【0009】こうして1画素を複数の領域に分割し、各
領域で液晶分子の傾斜方向を異ならせて視野角を向上さ
せた液晶表示装置を、1基板に対して1度のラビング処
理で実現でき、歩留まりを向上させることができる。
In this manner, a liquid crystal display device in which one pixel is divided into a plurality of regions and the viewing direction is improved by making the tilt direction of liquid crystal molecules different in each region can be realized by one rubbing process for one substrate. , The yield can be improved.

【0010】[0010]

【発明の実施の形態】以下、本発明の第1の実施形態を
図に基づいて説明する。図1は液晶表示装置の概略断面
を示し、図1(a)は電圧無印加時、図1(b)は電圧
印加時の液晶の配列状態を示す。
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows a schematic cross section of a liquid crystal display device. FIG. 1 (a) shows an arrangement state of liquid crystal when no voltage is applied, and FIG.

【0011】1はアレイ基板であり、例えばガラス基板
上に画素電極2とスイッチング素子であるTFTを各画
素に対応してマトリクス状に形成している。TFTのゲ
ート電極には走査線が、ソース電極には信号線が、ドレ
イン電極には画素電極2がそれぞれ接続され、走査線に
ゲート信号を供給してTFTをオンさせ、映像信号をソ
ース電極に信号線を介して供給する。このとき映像信号
に応じた電圧が画素電極2に印加され、TFTがオフに
なっても保持容量によって画素電極2では電圧印加状態
が維持される。画素電極2上には直線状の突起3が形成
され、この突起3によって電圧印加時の液晶分子5の配
列方向を規制している。突起3は画素電極2の中央部分
を通過すると共にほぼ長方形である画素電極2の長辺と
平行に配置され、画素電極2をほぼ均等に2つの領域
(A、B)に分割している。1画素をほぼ均等に分割す
ることで、均一な視野角の補償が行える。この画素電極
2及び突起3には後述する配向膜4が積層されている。
Reference numeral 1 denotes an array substrate on which, for example, a pixel electrode 2 and a TFT as a switching element are formed in a matrix on a glass substrate in correspondence with each pixel. A scanning line is connected to the gate electrode of the TFT, a signal line is connected to the source electrode, and a pixel electrode 2 is connected to the drain electrode. A gate signal is supplied to the scanning line to turn on the TFT, and a video signal is transmitted to the source electrode. Supply via signal line. At this time, a voltage corresponding to the video signal is applied to the pixel electrode 2, and the voltage application state is maintained on the pixel electrode 2 by the storage capacitor even when the TFT is turned off. A linear projection 3 is formed on the pixel electrode 2, and the projection 3 regulates the arrangement direction of the liquid crystal molecules 5 when a voltage is applied. The projection 3 passes through the central portion of the pixel electrode 2 and is arranged in parallel with the long side of the pixel electrode 2 which is substantially rectangular, and divides the pixel electrode 2 into two regions (A, B) substantially evenly. By dividing one pixel substantially evenly, a uniform viewing angle can be compensated. An alignment film 4 to be described later is laminated on the pixel electrode 2 and the projection 3.

【0012】8はアレイ基板1に対向配置されたカラー
フィルタ基板(以下CF基板という)であり、例えばガ
ラス基板上にカラーフィルタが各画素に応じて形成され
ている。CF基板8上には対向電極7が形成され、電圧
印加時に画素電極2との間で電界を発生させる。対向電
極7上には後述する配向膜6が積層されている。
Reference numeral 8 denotes a color filter substrate (hereinafter, referred to as a CF substrate) arranged to face the array substrate 1. For example, a color filter is formed for each pixel on a glass substrate. The counter electrode 7 is formed on the CF substrate 8 and generates an electric field between the CF electrode 8 and the pixel electrode 2 when a voltage is applied. On the counter electrode 7, an orientation film 6 described later is laminated.

【0013】アレイ基板1には表示領域の周囲にシール
材を塗布し、表示領域にスペーサを散布する。CF基板
8をアレイ基板1に位置を合わせて対向配置し、シール
材を硬化させて、アレイ基板1とCF基板8がスペーサ
の大きさ分の間隔を有して貼り合わされる。注入口より
アレイ基板1とCF基板8の間に液晶を注入し、注入口
を塞いで液晶セルを形成する。液晶5には負の誘電率異
方性を有し、カイラル材が添加されたものを用いる。こ
の実施形態ではカイラル材によって基板1、8の法線方
向から観察した際に、アレイ基板1からCF基板8の方
向に対して液晶分子5が時計回りに捩れる。
A seal material is applied to the periphery of the display area on the array substrate 1, and spacers are scattered over the display area. The CF substrate 8 is arranged to face the array substrate 1 so as to face the array substrate 1, the sealing material is cured, and the array substrate 1 and the CF substrate 8 are bonded together with a space corresponding to the size of the spacer. Liquid crystal is injected between the array substrate 1 and the CF substrate 8 from the injection port, and the injection port is closed to form a liquid crystal cell. The liquid crystal 5 has a negative dielectric anisotropy and has a chiral material added thereto. In this embodiment, the liquid crystal molecules 5 are twisted clockwise with respect to the direction from the array substrate 1 to the CF substrate 8 when viewed from the normal direction of the substrates 1 and 8 by the chiral material.

【0014】次に配向膜4、6の配向処理について説明
する。配向膜4は垂直配向性を有し、配向膜6は垂直配
向性と水平配向性を有するものを用いる。つまり配向膜
4には垂直配向性を有する配向膜をそのまま用い、配向
膜6には垂直配向性を有する配向膜に水平配向処理を施
している。図2は配向膜6の配向方向を示す平面図であ
り、図3は配向膜6の配向処理の手順を示す図である。
図2はCF基板8の法線方向から見たときの1画素分に
相当し、突起3で区切られている左側が領域A、右側が
領域Bに該当する。また図3は図2の矢印aから見たと
きの配向膜6を示している。CF基板8に垂直配向性を
有する配向膜6を積層した後、図3(a)に示すように
配向膜6に対してCF基板8の法線方向から無偏光の紫
外線を照射する。無偏光の紫外線を照射すると水平配向
時のチルト角を小さくすることができる。例えば偏光さ
れた紫外線を基板8の法線方向に対して斜めに照射する
と、配向膜6の主鎖や副鎖のうち偏光方向と同一方向の
ものだけ切断され、一方向に配向方向が生じる。しかし
本発明では液晶分子5が水平配列したときに全体的にチ
ルト角が小さくなるようにするため、無偏光の紫外線を
配向膜6表面の垂直方向から照射する。なお、図1及び
図3において配向膜6の斜線部は無偏光の紫外線を照射
した部分を示している。その後、図3(b)に示すよう
に配向膜6にラビング処理を行う。このラビング方向は
図2に示すように突起3と平行方向に設定する。
Next, the alignment treatment of the alignment films 4 and 6 will be described. The alignment film 4 has a vertical alignment, and the alignment film 6 has a vertical alignment and a horizontal alignment. That is, an alignment film having vertical alignment is used as the alignment film 4 as it is, and an alignment film having vertical alignment is subjected to horizontal alignment processing as the alignment film 6. FIG. 2 is a plan view showing the orientation direction of the alignment film 6, and FIG.
FIG. 2 corresponds to one pixel when viewed from the normal direction of the CF substrate 8. The left side divided by the protrusion 3 corresponds to the area A, and the right side corresponds to the area B. FIG. 3 shows the alignment film 6 as viewed from the arrow a in FIG. After laminating the alignment film 6 having a vertical alignment property on the CF substrate 8, the alignment film 6 is irradiated with non-polarized ultraviolet light from the normal direction of the CF substrate 8 as shown in FIG. Irradiation of non-polarized ultraviolet light can reduce the tilt angle during horizontal alignment. For example, when polarized ultraviolet light is irradiated obliquely with respect to the normal direction of the substrate 8, only the main chain and sub-chain of the alignment film 6 which are in the same direction as the polarization direction are cut, and an alignment direction is generated in one direction. However, in the present invention, in order to reduce the tilt angle as a whole when the liquid crystal molecules 5 are horizontally aligned, non-polarized ultraviolet rays are irradiated from the vertical direction on the surface of the alignment film 6. 1 and 3, the hatched portion of the alignment film 6 indicates a portion irradiated with non-polarized ultraviolet light. After that, a rubbing process is performed on the alignment film 6 as shown in FIG. The rubbing direction is set in a direction parallel to the projection 3 as shown in FIG.

【0015】そして電圧無印加時は図1(a)に示すよ
うに、配向膜4、6の垂直配向性に影響されて配向膜
4、6表面に対して液晶分子5が垂直配列し、基板1、
8間の液晶分子5も基板1、8の法線方向に沿って垂直
配列する。このとき突起3付近に位置する液晶分子5だ
けは突起3表面に対して垂直に配列するため、基板1、
8の法線方向に対しては斜め方向に配列する。また電圧
印加時は画素電極2と対向電極7の間に電界が発生し、
その電界方向の垂直方向に液晶分子5が傾斜する。この
ときアレイ基板1側の液晶分子5は突起3によって2つ
の傾斜方向に規制される。つまり図1(b)のように、
領域Aでは液晶分子5が突起3の左側傾斜面の垂直方向
に傾くため左上がりに傾斜し、領域Bでは液晶分子5が
突起3の右側傾斜面の垂直方向に傾くため領域Aとは逆
の右上がりに傾斜する。液晶5にはカイラル材が添加さ
れているためCF基板8側に進むに従って基板1、8の
法線方向における時計回りに捩れながら水平配列する。
このとき配向膜6には突起3と平行に水平配向処理が施
されているため、基板1、8間で液晶分子5は90度捩
れることになる。配向膜4表面の液晶分子5は完全な水
平配列ではなく所定のチルト角で傾斜し、領域A、Bの
液晶分子5は傾斜方向が逆になるため、配向膜6側の液
晶分子5も領域A、Bで傾斜方向が逆になってしまう。
この場合、従来例のように領域A、Bでそれぞれ逆方向
に配向処理しなければ、液晶分子5の配列状態が乱れて
しまう。しかし本発明では配向膜6に無偏光の紫外線を
照射することで水平配向時のチルト角を小さくしている
ため、配向膜6表面の液晶分子5はほぼ水平方向に配列
し、アレイ基板1からCF基板8に対して液晶分子5が
徐々に水平方向に傾斜しながら配列することになる。従
って配向膜6表面では領域Aと領域Bにおける液晶分子
5の傾斜方向がほぼ同じになり、液晶分子5の配列状態
が乱れない。なお、配向膜6のチルト角は0度である方
が好ましいが、電圧印加時の液晶分子5の配列がCF基
板6側で乱れない範囲であれば、小さいチルト角を有し
ても構わない。
When no voltage is applied, as shown in FIG. 1A, the liquid crystal molecules 5 are vertically aligned on the surfaces of the alignment films 4 and 6 due to the influence of the vertical alignment of the alignment films 4 and 6, and 1,
The liquid crystal molecules 5 between 8 are also vertically arranged along the normal direction of the substrates 1 and 8. At this time, only the liquid crystal molecules 5 located in the vicinity of the projections 3 are arranged perpendicular to the surface of the projections 3.
8 are arranged obliquely to the normal direction. When a voltage is applied, an electric field is generated between the pixel electrode 2 and the counter electrode 7,
The liquid crystal molecules 5 tilt in the direction perpendicular to the direction of the electric field. At this time, the liquid crystal molecules 5 on the array substrate 1 side are regulated by the protrusions 3 in two inclination directions. That is, as shown in FIG.
In the region A, the liquid crystal molecules 5 tilt in the vertical direction of the left inclined surface of the protrusion 3 and thus tilt upward. In the region B, the liquid crystal molecules 5 tilt in the vertical direction of the right inclined surface of the protrusion 3 and thus reverse to the region A. Incline to the right. Since the liquid crystal 5 contains a chiral material, the liquid crystal 5 is horizontally arranged while being twisted clockwise in the normal direction of the substrates 1 and 8 toward the CF substrate 8.
At this time, the liquid crystal molecules 5 are twisted by 90 degrees between the substrates 1 and 8 because the alignment film 6 has been subjected to the horizontal alignment processing in parallel with the projections 3. The liquid crystal molecules 5 on the surface of the alignment film 4 are not perfectly aligned horizontally but are tilted at a predetermined tilt angle, and the liquid crystal molecules 5 in the regions A and B have opposite tilt directions. At A and B, the inclination direction is reversed.
In this case, the alignment state of the liquid crystal molecules 5 is disturbed unless the alignment treatment is performed in the regions A and B in the opposite directions as in the conventional example. However, in the present invention, the tilt angle at the time of horizontal alignment is reduced by irradiating the alignment film 6 with unpolarized ultraviolet light. Therefore, the liquid crystal molecules 5 on the surface of the alignment film 6 are arranged in a substantially horizontal direction. The liquid crystal molecules 5 are arranged while being gradually inclined in the horizontal direction with respect to the CF substrate 8. Therefore, on the surface of the alignment film 6, the inclination directions of the liquid crystal molecules 5 in the region A and the region B become substantially the same, and the arrangement state of the liquid crystal molecules 5 is not disturbed. It is preferable that the tilt angle of the alignment film 6 is 0 degree, but the tilt angle may be small as long as the alignment of the liquid crystal molecules 5 when voltage is applied is not disturbed on the CF substrate 6 side. .

【0016】この液晶セルを一対の偏光板で挟み込むと
き、偏光板を直交ニコルにし、偏光板の透過軸を配向膜
4、6表面の液晶分子5の配向方向に設定すると、電圧
無印加時に黒表示、電圧印加時に白表示になるノーマリ
ブラックモードになる。また、偏光板を平行ニコルに
し、一方の偏光板の透過軸を配向膜4、6表面の液晶分
子5の配向方向に設定すると、電圧無印加時に白表示、
電圧印加時に黒表示になるノーマリホワイトモードにな
る。
When the liquid crystal cell is sandwiched between a pair of polarizers, the polarizers are set to cross Nicols, and the transmission axis of the polarizers is set to the alignment direction of the liquid crystal molecules 5 on the surfaces of the alignment films 4 and 6. It becomes a normally black mode in which white display is performed when display and voltage are applied. Further, when the polarizing plate is set to parallel Nicols, and the transmission axis of one of the polarizing plates is set to the alignment direction of the liquid crystal molecules 5 on the surfaces of the alignment films 4 and 6, white display is obtained when no voltage is applied.
It becomes a normally white mode in which black display is performed when a voltage is applied.

【0017】この実施形態では垂直配向膜6に無偏光の
紫外線を照射してからラビング処理を行うため、配向膜
6のラビング処理が一回で済み、ラビング処理による不
具合が低減できる。また、アレイ基板1側は突起3によ
って電圧印加時の液晶分子5の傾斜方向を規制するた
め、静電気などの問題が生じるラビング処理をアレイ基
板1は省略でき、不具合が低減して生産性が向上する。
In this embodiment, since the rubbing treatment is performed after irradiating the vertical alignment film 6 with non-polarized ultraviolet light, the rubbing treatment of the alignment film 6 only needs to be performed once, and the trouble caused by the rubbing treatment can be reduced. Further, since the inclination direction of the liquid crystal molecules 5 at the time of applying a voltage is regulated by the projections 3 on the array substrate 1 side, the rubbing treatment which causes a problem such as static electricity can be omitted for the array substrate 1, and the defects are reduced and the productivity is improved. I do.

【0018】この実施形態では画素電極2に突起3を形
成した場合を説明したが、突起3の代わりにスリットを
形成してもよい。このときスリットの配置や配向方向と
の関係などは突起3を設けた場合と同様の条件にする。
In this embodiment, the case where the projection 3 is formed on the pixel electrode 2 has been described, but a slit may be formed instead of the projection 3. At this time, the arrangement of the slits and the relationship with the orientation direction are set to the same conditions as in the case where the projections 3 are provided.

【0019】次に本発明の第2の実施形態を図に基づい
て説明する。図4は液晶表示装置の概略断面を示し、図
4(a)は電圧無印加時、図4(b)は電圧印加時の液
晶の配列状態を示す。第2の実施形態は第1の実施形態
と突起3及び配向膜の点で異なるが、その他の構成は同
じである。従って第1の実施形態と同じ構成部分には同
一の符号を付け、説明を省略する。また配向膜9、10
の斜線部は無偏光の紫外線を照射した部分を示す。
Next, a second embodiment of the present invention will be described with reference to the drawings. 4A and 4B are schematic cross-sectional views of the liquid crystal display device. FIG. 4A shows the state of the liquid crystal array when no voltage is applied, and FIG. The second embodiment is different from the first embodiment in the points of the protrusion 3 and the alignment film, but the other configurations are the same. Therefore, the same components as those of the first embodiment are denoted by the same reference numerals, and description thereof is omitted. Also, the alignment films 9 and 10
The hatched portion indicates a portion irradiated with non-polarized ultraviolet light.

【0020】この実施形態では画素電極2上に突起3は
ないが、第1の実施形態と同様に1画素をほぼ左右均等
に2分割している。この実施形態では図4に示すよう
に、画素電極2の中央部を境にして左側を領域A、右側
を領域Bとする。アレイ基板1の画素電極2上には配向
膜9を、CF基板8の対向電極7上には配向膜10をそ
れぞれ積層する。この配向膜9、10は垂直配向性を有
する配向膜に無偏光の紫外線を照射し、その後に水平配
向処理を施したものであり、その配向方向を図5に、配
向処理の手順を図6にそれぞれ示す。図5はCF基板8
の法線方向から見たときの1画素分に相当し、点線で仕
切られている左側がA領域、右側が領域Bに該当する。
また図6は図5の矢印aから見たときの配向膜9、10
を示している。図6(a)に示すように基板1、8上に
垂直配向性を有する配向膜9、10を積層した後、所定
のパターンのマスク11を介して基板1、8の法線方向
から無偏光の紫外線を照射する。ここで紫外線が照射さ
れる部分は、配向膜9では領域Bであり、配向膜10で
は領域Aに該当する。その後、図6(b)に示すように
各配向膜9、10にラビング処理を1度だけ施す。図5
の矢印1はアレイ基板1の配向膜9のラビング処理を示
し、矢印2はCF基板8の配向膜10のラビング処理を
示す。この矢印の向きは、液晶分子5が配向膜9、10
表面で所定のチルト角で傾斜した際に、配向膜9、10
に近接する液晶分子5の端部から配向膜9、10と遠ざ
かる液晶分子5の端部の方向を示している。CF基板8
の配向膜10には、アレイ基板1の配向膜9表面の液晶
分子5が時計回りに90度捩れならが水平配列した際の
配向膜10表面に位置する液晶分子の配向方向(矢印
3)と180度ずらした方向(矢印2)にラビング処理
が施されている。ラビング処理は領域A、Bの両方に施
されるが、無偏光の紫外線が照射されていない領域(配
向膜9の領域A、配向膜10の領域B)のみ液晶分子が
所定のチルト角で水平配列するように作用する。
In this embodiment, there is no projection 3 on the pixel electrode 2, but one pixel is divided into two substantially equally to the left and right as in the first embodiment. In this embodiment, as shown in FIG. 4, a region A is on the left and a region B is on the right with respect to the center of the pixel electrode 2. An alignment film 9 is stacked on the pixel electrode 2 of the array substrate 1 and an alignment film 10 is stacked on the counter electrode 7 of the CF substrate 8. The alignment films 9 and 10 are obtained by irradiating an unpolarized ultraviolet ray to an alignment film having a vertical alignment and then performing a horizontal alignment process. The alignment direction is shown in FIG. 5, and the procedure of the alignment process is shown in FIG. Are shown below. FIG. 5 shows the CF substrate 8
, Corresponds to one pixel when viewed from the normal direction, and the left side divided by the dotted line corresponds to the area A, and the right side corresponds to the area B.
6 shows the alignment films 9, 10 as viewed from the arrow a in FIG.
Is shown. As shown in FIG. 6A, after the alignment films 9 and 10 having vertical alignment are laminated on the substrates 1 and 8, non-polarized light is applied from a normal direction of the substrates 1 and 8 through a mask 11 having a predetermined pattern. Irradiation of ultraviolet rays. Here, the portion irradiated with the ultraviolet rays corresponds to the region B in the alignment film 9 and corresponds to the region A in the alignment film 10. Thereafter, as shown in FIG. 6B, a rubbing process is performed only once on each of the alignment films 9 and 10. FIG.
Arrow 1 indicates a rubbing process of the alignment film 9 of the array substrate 1, and an arrow 2 indicates a rubbing process of the alignment film 10 of the CF substrate 8. The direction of the arrow indicates that the liquid crystal molecules 5 are aligned with the alignment films 9 and 10.
When the surface is inclined at a predetermined tilt angle, the alignment films 9, 10
The direction of the edge of the liquid crystal molecule 5 away from the alignment films 9 and 10 from the edge of the liquid crystal molecule 5 that is close to. CF substrate 8
The orientation direction of liquid crystal molecules (arrow 3) positioned on the surface of the alignment film 10 when the liquid crystal molecules 5 on the surface of the alignment film 9 of the array substrate 1 are twisted 90 degrees in a clockwise direction is horizontally aligned. The rubbing process is performed in the direction shifted by 180 degrees (arrow 2). The rubbing treatment is performed on both the regions A and B, but only in the regions where the unpolarized ultraviolet light is not irradiated (the regions A of the alignment film 9 and the region B of the alignment film 10), the liquid crystal molecules are horizontal at a predetermined tilt angle. Acts like an array.

【0021】そして電圧無印加時は配向膜9、10の垂
直配向性に影響されて配向膜9、10表面の液晶分子5
が垂直配列し、基板1、8間の液晶分子5も垂直配列す
る。電圧印加時は画素電極2と対向電極7の間に電界が
発生し、液晶分子5は電界方向の垂直方向に傾斜する。
このとき領域Aの配向膜9表面と領域Bの配向膜10表
面の液晶分子5は強い影響を受けて所定のチルト角で傾
斜するが、無偏光紫外線を照射した領域Bの配向膜9表
面と領域Aの配向膜10表面の液晶分子5はチルト角が
小さくほぼ水平方向に配列する。従って領域Aの液晶分
子5はアレイ基板1からCF基板8に対して徐々に水平
方向に倒れながら時計回りに90度捩れ、領域Bの液晶
分子5はCF基板8からアレイ基板1に対して徐々に水
平方向に倒れながら反時計回りに90度捩れる。領域A
の配向膜10表面と領域Bの配向膜9表面ではラビング
方向が本来の液晶分子5の傾斜方向とは逆方向になる
が、無偏光紫外線の照射処理を行っているためチルト角
が小さくなり、表示不良の原因となるような液晶分子5
の配列の乱れは発生しない。領域Aと領域Bでは液晶分
子5が共に基板1、8の法線方向に対する時計回りに捩
るが、傾斜方向が互いに逆になるため視野角を補償し合
うことになり、広視野角になる。
When no voltage is applied, the liquid crystal molecules 5 on the surfaces of the alignment films 9 and 10 are affected by the vertical alignment of the alignment films 9 and 10.
Are vertically arranged, and the liquid crystal molecules 5 between the substrates 1 and 8 are also vertically arranged. When a voltage is applied, an electric field is generated between the pixel electrode 2 and the counter electrode 7, and the liquid crystal molecules 5 tilt in a direction perpendicular to the direction of the electric field.
At this time, the liquid crystal molecules 5 on the surface of the alignment film 9 in the region A and the surface of the alignment film 10 in the region B are strongly influenced and tilt at a predetermined tilt angle. The liquid crystal molecules 5 on the surface of the alignment film 10 in the region A have a small tilt angle and are arranged in a substantially horizontal direction. Accordingly, the liquid crystal molecules 5 in the region A are twisted 90 degrees clockwise while gradually falling horizontally from the array substrate 1 to the CF substrate 8, and the liquid crystal molecules 5 in the region B are gradually moved from the CF substrate 8 to the array substrate 1. Twist 90 degrees counterclockwise while falling horizontally. Area A
Although the rubbing direction is opposite to the original tilt direction of the liquid crystal molecules 5 on the surface of the alignment film 10 in the region B and the surface of the alignment film 9 in the region B, the tilt angle is reduced due to the irradiation treatment with non-polarized ultraviolet light, Liquid crystal molecules 5 that cause display defects
Does not occur. In the regions A and B, the liquid crystal molecules 5 are both twisted clockwise with respect to the normal direction of the substrates 1 and 8, but the inclination directions are opposite to each other, so that the viewing angles are compensated and the viewing angle is wide.

【0022】この実施形態では垂直配向膜9、10に無
偏光の紫外線を照射してからラビング処理を行うため、
それぞれ配向膜9、10のラビング処理が一回で済み、
ラビング処理による不具合が低減できる。
In this embodiment, the rubbing process is performed after irradiating the vertical alignment films 9 and 10 with unpolarized ultraviolet light.
The rubbing process for each of the alignment films 9 and 10 only needs to be performed once,
Problems due to the rubbing process can be reduced.

【0023】なお本発明は上記の実施形態に限定される
ものではなく、本発明の趣旨を逸脱しない範囲において
種々の変更を加えることが可能である。例えば、1画素
を2つ以上の領域に分割したものにも有効である。
The present invention is not limited to the above embodiment, and various changes can be made without departing from the spirit of the present invention. For example, the present invention is effective for a case where one pixel is divided into two or more regions.

【0024】また予め決まった領域に無偏光の紫外線を
照射することで水平配向したときの液晶分子のチルト角
が小さくなるように設定したが、無偏光の紫外線を照射
する代わりに直線偏光の紫外線をその振幅方向をずらし
ながら複数回に別けて照射してもよい。このとき配向膜
には紫外線の振幅方向と同一方向の主鎖又は副鎖が切断
されるものを用いる。さらに第1及び第2の実施形態に
おける無偏光の紫外線を照射する工程を直線偏光の紫外
線を複数回照射する工程に代えるだけで、液晶表示装置
の構成やその他の工程は同一のものを用いる。
The tilt angle of the liquid crystal molecules when horizontally aligned by irradiating a predetermined region with unpolarized ultraviolet light is set to be small. Instead of irradiating unpolarized ultraviolet light, linearly polarized ultraviolet light is used. May be irradiated a plurality of times while shifting the amplitude direction. At this time, an alignment film whose main chain or sub-chain in the same direction as the amplitude direction of the ultraviolet light is cut is used. Furthermore, the same steps are used for the configuration of the liquid crystal display device and other steps, except that the step of irradiating unpolarized ultraviolet light in the first and second embodiments is replaced with the step of irradiating linearly polarized ultraviolet light a plurality of times.

【0025】[0025]

【発明の効果】本発明によれば、垂直配向性を有する配
向膜に無偏光の紫外線の照射処理と水平配向処理を施す
ので、この配向膜付近の液晶分子は電圧無印加時に垂直
配列し、電圧印加時にほぼチルト角がない状態で水平配
列するため、少ないラビング処理で1画素内に異なる配
向区分を有する液晶表示装置を製造することができる。
According to the present invention, the alignment film having the vertical alignment property is subjected to the irradiation treatment of non-polarized ultraviolet light and the horizontal alignment treatment, so that the liquid crystal molecules near the alignment film are vertically aligned when no voltage is applied, Since the liquid crystal display is horizontally arranged with almost no tilt angle when a voltage is applied, a liquid crystal display device having different alignment sections in one pixel can be manufactured with a small amount of rubbing treatment.

【0026】また、画素電極に線状の突起又はスリット
を設け、対向電極上の配向膜に無偏光紫外線の照射処理
と突起又はスリットとほぼ平行方向にラビング処理を行
うので、画素電極側のラビング処理を省くことができ、
ラビング処理時の静電気によるスイッチング素子の破壊
を防止することができる。
Further, since linear projections or slits are provided on the pixel electrode and the alignment film on the counter electrode is irradiated with unpolarized ultraviolet light and rubbed in a direction substantially parallel to the projection or slit, the rubbing on the pixel electrode side is performed. Processing can be omitted,
The destruction of the switching element due to static electricity during the rubbing process can be prevented.

【0027】また、1画素を複数の領域に分割し、各領
域では、一方の基板の配向膜に無偏光紫外線の照射処理
と水平配向処理を、他方の基板の配向膜に水平配向処理
をそれぞれ施し、電圧印加時に隣接する領域の液晶分子
の傾斜方向が異なるようにしすることで、各基板のラビ
ング処理が1回になり、歩留まりを向上させることがで
きる。
One pixel is divided into a plurality of regions, and in each region, the alignment film of one substrate is subjected to irradiation treatment with non-polarized ultraviolet light and horizontal alignment treatment, and the alignment film of the other substrate is subjected to horizontal alignment treatment. By applying different voltages so that the inclination directions of the liquid crystal molecules in the adjacent regions are different at the time of voltage application, the rubbing treatment of each substrate is performed once, and the yield can be improved.

【図面の簡単な説明】[Brief description of the drawings]

【図1】本発明の第1の実施形態である液晶表示装置の
断面概略図である。
FIG. 1 is a schematic sectional view of a liquid crystal display device according to a first embodiment of the present invention.

【図2】第1の実施形態である液晶表示装置の配向膜の
水平配向方向を示す図である。
FIG. 2 is a diagram illustrating a horizontal alignment direction of an alignment film of the liquid crystal display device according to the first embodiment.

【図3】第1の実施形態の配向膜の配向処理を説明する
図である。
FIG. 3 is a diagram illustrating an alignment process of an alignment film according to the first embodiment.

【図4】本発明の第2の実施形態である液晶表示装置の
断面概略図である。
FIG. 4 is a schematic sectional view of a liquid crystal display device according to a second embodiment of the present invention.

【図5】第2の実施形態である液晶表示装置の配向膜の
水平配向方向を示す図である。
FIG. 5 is a diagram illustrating a horizontal alignment direction of an alignment film of a liquid crystal display device according to a second embodiment.

【図6】第2の実施形態の配向膜の配向処理を説明する
図である。
FIG. 6 is a diagram illustrating an alignment process of an alignment film according to a second embodiment.

【符号の説明】[Explanation of symbols]

1 アレイ基板 2 画素電極 3 突起 4、6、9、10 配向膜 5 液晶 7 対向電極 8 CF基板 DESCRIPTION OF SYMBOLS 1 Array substrate 2 Pixel electrode 3 Projection 4, 6, 9, 10 Alignment film 5 Liquid crystal 7 Counter electrode 8 CF substrate

───────────────────────────────────────────────────── フロントページの続き (72)発明者 賀勢 裕之 鳥取県鳥取市南吉方3丁目201番地 鳥取 三洋電機株式会社内 (72)発明者 森 善隆 鳥取県鳥取市南吉方3丁目201番地 鳥取 三洋電機株式会社内 (72)発明者 田中 慎一郎 鳥取県鳥取市南吉方3丁目201番地 鳥取 三洋電機株式会社内 Fターム(参考) 2H090 HA05 JA03 JC03 KA04 LA01 MA01 MA02 MA11 MA15 MB01 MB14 2H092 GA13 GA17 JB05 NA01 PA02 5C094 AA03 AA31 AA42 AA43 BA03 BA43 CA19 CA24 EA04 EA07 ED02 ED14  ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Hiroyuki Kase 3-201 Minamiyoshikata, Tottori-shi, Tottori Sanyo Electric Co., Ltd. (72) Inventor Yoshitaka Mori 3-201 Minamiyoshikata, Tottori-shi, Tottori Sanyo Tottori Inside Electric Co., Ltd. (72) Inventor Shinichiro Tanaka 3-201 Minamiyoshikata, Tottori City, Tottori Prefecture Tottori Sanyo Electric Co., Ltd. 5C094 AA03 AA31 AA42 AA43 BA03 BA43 CA19 CA24 EA04 EA07 ED02 ED14

Claims (10)

【特許請求の範囲】[Claims] 【請求項1】 各画素毎に画素電極が形成された第一基
板と、対向電極が形成された第二基板と、前記両基板上
に積層された垂直配向性を有する配向膜と、前記基板間
に封入された負の誘電率異方性を有する液晶層とを備
え、前記基板のどちらか一方には各画素に対応して線状
の突起又はスリットが形成され、他方の基板の配向膜に
は無偏光の紫外線の照射処理と前記突起又は前記スリッ
トの略平行方向に水平配向処理が施されていることを特
徴とする液晶表示装置。
A first substrate on which a pixel electrode is formed for each pixel; a second substrate on which a counter electrode is formed; an alignment film having a vertical alignment laminated on the two substrates; A liquid crystal layer having a negative dielectric anisotropy encapsulated therebetween, and a linear projection or slit is formed on one of the substrates corresponding to each pixel, and an alignment film on the other substrate is provided. Wherein a liquid crystal display device is provided with an irradiation treatment with non-polarized ultraviolet light and a horizontal alignment treatment in a direction substantially parallel to the projection or the slit.
【請求項2】 前記液晶層にはカイラル材が添加され、
液晶分子は電圧無印加時に垂直配列し、電圧印加時に前
記基板間で捩れながら水平配列することを特徴とする請
求項1記載の液晶表示装置。
2. A chiral material is added to the liquid crystal layer,
2. The liquid crystal display device according to claim 1, wherein the liquid crystal molecules are vertically arranged when no voltage is applied, and are horizontally arranged while being twisted between the substrates when a voltage is applied.
【請求項3】 前記突起又は前記スリットが前記画素電
極に形成されていることを特徴とする請求項1乃至請求
項2記載の液晶表示装置。
3. The liquid crystal display device according to claim 1, wherein the protrusion or the slit is formed in the pixel electrode.
【請求項4】 前記突起又は前記スリットにより各画素
をほぼ均等に2分割し、分割された領域の液晶分子は電
圧印加時に前記突起又は前記スリットによって傾斜方向
が規制されて他方の領域の液晶分子と異なる方向に傾斜
すると共に前記基板間で90度捩れながら水平配列する
ことを特徴とする請求項1乃至請求項3記載の液晶表示
装置
4. The projection or the slit divides each pixel substantially equally into two, and the liquid crystal molecules in the divided area are restricted in the inclination direction by the projection or the slit when a voltage is applied, and the liquid crystal molecules in the other area are divided. 4. The liquid crystal display device according to claim 1, wherein the liquid crystal display device is horizontally arranged while being inclined in a direction different from that of the substrate and twisted by 90 degrees between the substrates.
【請求項5】 前記水平配向処理がラビング処理である
ことを特徴とする請求項1乃至請求項4記載の液晶表示
装置。
5. The liquid crystal display device according to claim 1, wherein the horizontal alignment process is a rubbing process.
【請求項6】 画素電極が形成された基板と対向電極が
形成された基板との間に誘電率異方性が負の液晶を封入
し、両基板に垂直配向性を有する配向膜を積層した液晶
表示装置において、各画素を複数の領域に分割し、各領
域では、一方の基板の配向膜に無偏光の紫外線の照射処
理と水平配向処理を施し、他方の基板の配向膜に水平配
向処理を施し、電圧印加時に無偏光紫外線の照射処理が
施されていない配向膜によって液晶分子の傾斜方向が規
制されると共に隣接する領域の液晶分子と傾斜方向が異
なることを特徴とする液晶表示装置。
6. A liquid crystal having a negative dielectric anisotropy is sealed between a substrate on which a pixel electrode is formed and a substrate on which a counter electrode is formed, and an alignment film having vertical alignment is laminated on both substrates. In a liquid crystal display device, each pixel is divided into a plurality of regions, and in each region, the alignment film of one substrate is subjected to irradiation treatment with non-polarized ultraviolet light and horizontal alignment treatment, and the alignment film of the other substrate is subjected to horizontal alignment treatment. A liquid crystal display device characterized in that the tilt direction of liquid crystal molecules is regulated by an alignment film that has not been subjected to irradiation treatment with non-polarized ultraviolet light when a voltage is applied, and the tilt direction differs from liquid crystal molecules in an adjacent region.
【請求項7】 前記液晶層にはカイラル材が添加され、
液晶分子は電圧無印加時に垂直配列し、電圧印加時に前
記基板間で90度捩れながら水平配列することを特徴と
する請求項6記載の液晶表示装置。
7. A chiral material is added to the liquid crystal layer,
7. The liquid crystal display device according to claim 6, wherein the liquid crystal molecules are vertically arranged when no voltage is applied, and are horizontally arranged while being twisted by 90 degrees between the substrates when a voltage is applied.
【請求項8】 各画素が2つの領域A、Bに分割され、
一方の基板の領域Aと他方の基板の領域Bには無偏光紫
外線の照射処理が施されると共に両基板には互いに直交
する方向にラビング処理が施され、電圧印加時に一方の
基板界面の液晶分子が他方の基板界面の液晶分子が90
度捩れたときの傾斜方向と逆方向に傾斜するようにラビ
ング方向が設定されていることを特徴とする請求項6乃
至請求項7記載の液晶表示装置。
8. Each pixel is divided into two areas A and B,
A region A of one substrate and a region B of the other substrate are subjected to irradiation treatment with non-polarized ultraviolet light, and both substrates are subjected to rubbing treatment in directions orthogonal to each other. The liquid crystal molecules at the interface of the other substrate are 90
8. The liquid crystal display device according to claim 6, wherein the rubbing direction is set so as to incline in a direction opposite to the inclining direction when twisted.
【請求項9】 各画素毎に画素電極が形成された第一基
板と、対向電極が形成された第二基板と、前記両基板上
に積層された垂直配向性を有する配向膜と、前記基板間
に封入された負の誘電率異方性を有する液晶層とを備
え、前記基板のどちらか一方には各画素に対応して線状
の突起又はスリットが形成され、他方の基板の配向膜に
は直線偏光の紫外線をその振幅方向をずらしながら複数
回照射する処理と前記突起又は前記スリットの略平行方
向に水平配向処理が施されていることを特徴とする液晶
表示装置。
9. A first substrate on which a pixel electrode is formed for each pixel, a second substrate on which a counter electrode is formed, an alignment film having vertical alignment laminated on both substrates, and the substrate A liquid crystal layer having a negative dielectric anisotropy encapsulated therebetween, and a linear projection or slit is formed on one of the substrates corresponding to each pixel, and an alignment film on the other substrate is provided. A liquid crystal display device, wherein a process of irradiating linearly polarized ultraviolet light a plurality of times while shifting its amplitude direction and a horizontal alignment process in a direction substantially parallel to the protrusion or the slit are performed.
【請求項10】 画素電極が形成された基板と対向電極
が形成された基板との間に誘電率異方性が負の液晶を封
入し、両基板に垂直配向性を有する配向膜を積層した液
晶表示装置において、各画素を複数の領域に分割し、各
領域では、一方の基板の配向膜に直線偏光の紫外線をそ
の振幅方向をずらしながら複数回照射する処理と水平配
向処理を施し、他方の基板の配向膜に水平配向処理を施
し、電圧印加時に直線偏光の紫外線の照射処理が施され
ていない配向膜によって液晶分子の傾斜方向が規制され
ると共に隣接する領域の液晶分子と傾斜方向が異なるこ
とを特徴とする液晶表示装置。
10. A liquid crystal having a negative dielectric anisotropy is sealed between a substrate on which a pixel electrode is formed and a substrate on which a counter electrode is formed, and an alignment film having vertical alignment is laminated on both substrates. In the liquid crystal display device, each pixel is divided into a plurality of regions, and in each region, a process of irradiating the alignment film of one substrate with ultraviolet light of linearly polarized light a plurality of times while shifting its amplitude direction and a horizontal alignment process are performed. Horizontal alignment treatment is performed on the alignment film of the substrate, and the tilt direction of the liquid crystal molecules is regulated by the alignment film that has not been subjected to the irradiation of the linearly polarized ultraviolet light when a voltage is applied. A liquid crystal display device characterized by being different.
JP2000392815A 2000-12-25 2000-12-25 Liquid crystal display device Pending JP2002196336A (en)

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US7453536B2 (en) * 2004-05-24 2008-11-18 Samsung Electronics Co., Ltd. Liquid crystal display and manufacturing method thereof
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