JP3995287B2 - Display medium and display device using photochromic material - Google Patents

Description

【００２５】
【化２】

【００２６】
【化３】

【００２７】
【化４】

【００２８】
また、本発明では再結晶法などにより晶出させた上記有機化合物の単結晶を粉砕して得られた微粉末が用いられる。有機化合物の単結晶の微粉末を支持するバインダーとしては、ポリエステル樹脂，ポリスチレン樹脂，ポリビニルブチラール樹脂，ポリ塩化ビニル，ポリ塩化ビニリデン，ポリ酢酸ビニル，酢酸セルロース，ポリメタクリル酸メチル，ポリメタクリル酸ブチル，ポリカーボネイト樹脂，フェノール樹脂，エポキシ樹脂，ポリビニルアルコールなどのように、その内部に有機化合物の単結晶の微粉末を結晶状態を保ったまま分散させて保持できるものであれば良い。
【００２９】
有機化合物の単結晶の微粉末を分散し、バインダーを溶解させる溶媒としては、その溶媒中において有機化合物の単結晶の微粉末は不溶性であるが、バインダーは可溶性であるような溶媒を用いる。
【００３０】
有機化合物の単結晶の微粉末、バインダー、溶媒からなる溶液を塗着する基板としては、板状または箔状のガラス、プラスチック、紙、金属などの、一般的な表示媒体の支持体が用いられる。
【００３１】
以上のような構成により、フォトクロミック性を有する有機化合物の単結晶の微粉末が、この微粉末を支持するバインダー内に分散されていることによって、着色速度が速く、すなわち小さな光照射エネルギーで着色が可能であるとともに、着色状態と消色状態の繰り返し耐久性に優れたフォトクロミック材料およびフォトクロミック材料を用いた表示媒体が得られる。
【００３２】
次に、本発明の（実施の形態１）におけるフォトクロミック材料を用いた表示媒体について、（実施例１）および（比較例）を用いて説明する。
【００３３】
（実施例１）
公知の方法により、ジアリールエテン系化合物である１，２−（２，４−ジメチル−５−フェニルチオフェン−３−イル）−３，３，４，４，５，５−ヘキサフルオロシクロペンテン（以下、化合物１とする。）を合成し、精製した。
【００３４】
この化合物１は、下記の（化５）に示すように紫外光を照射することにより閉環し、着色状態（青紫色）に変化する。また、これに可視光を照射することにより開環して、元の消色状態（無色）に戻る。
【００３５】
【化５】

【００３６】
この化合物１をヘキサンに溶解し、室温にて放置することにより徐々にヘキサンを蒸発させて化合物１の単結晶を析出させ、これを粉砕して微粉末とした。この微粉末をポリビニルアルコール 17.5 重量％を溶解した水溶液中に添加し、撹拌混合して均一に分散させ、不透明なスラリー状の溶液を得た。この時、化合物１は溶液中に 5.3重量％添加した。
【００３７】
尚、ポリビニルアルコールは水に可溶性であり、化合物１が水に溶解しないことはあらかじめ確認しておいた。この溶液を白色ＰＥＴ基板の上に塗布した後、ワイヤーバーを用いて薄膜に成形してから、 80 ℃で８時間乾燥させてフォトクロミック材料からなる表示層を有する表示媒体を作製した。
【００３８】
この表示層の膜厚は 30 μｍであった。この表示媒体に蛍光ブラックライトを用いて紫外線を照射すると青紫色に着色し、着色時の可視領域における極大吸収波長は 618ｎｍであった。
【００３９】
また、着色状態の表示層にハロゲンランプを用いて可視光を照射すると元の無色の状態に戻った。尚、この着色状態、消色状態は繰り返し行うことが可能であった。
【００４０】
（比較例）
公知の方法により得られた下記（化６）で示される１，２−（２，４−ジメチル−５−エトキシフェニルチオフェン−３−イル）−３，３，４，４，５，５−ヘキサフルオロシクロペンテン（以下、化合物２とする。）の精製物 6.0重量％とポリスチレン樹脂 14 重量％をトルエンに完全に溶解させた溶液を用いて、（実施例１）と同様な方法で白色ＰＥＴ基板の上に 30 μｍの膜厚で薄膜形成した表示媒体を作製した。
【００４１】
【化６】

【００４２】
この表示媒体に蛍光ブラックライトを用いて紫外線を照射すると青紫色に着色し、着色時の可視領域における極大吸収波長は 588ｎｍであった。また、着色状態の表示層にハロゲンランプを用いて可視光を照射すると元の無色の状態に戻った。
【００４３】
次に、（実施例１）および（比較例）における表示媒体のそれぞれについて、光照射に対する感度と着色状態、消色状態の繰り返し耐久性を調べた結果を、図１および図２を用いて説明する。
【００４４】
図１は、本発明の（実施例１）および（比較例）における表示媒体の照射エネルギーと可視領域における極大吸収波長での反射濃度の関係図であり、曲線（ａ）は（実施例１）における表示媒体について、また曲線（ｂ）は（比較例）における表示媒体について得られた結果である。尚、各々の表示媒体には、消色状態から蛍光ブラックライトを用いて最大ピーク波長 365ｎｍの紫外光を照射した。
【００４５】
図１より、本発明の（実施例１）における表示媒体は、従来の方法により作製した（比較例）における表示媒体に比べて、同じ反射濃度、すなわち、同程度の着色状態とするために必要な照射エネルギーが非常に少ないことが判る。
【００４６】
通常、フォトクロミック材料を用いる表示媒体において文字や画像などを表示する場合、明瞭なコントラストで表示するためには着色状態における反射濃度が１以上であることが要求されるが、図１から（実施例１）における表示媒体で反射濃度が１となるために必要な照射エネルギーは、（比較例）における表示媒体の１／８以下である。
【００４７】
図２は、本発明の（実施例１）および従来の方法により作製した（比較例）における着色・消色の繰り返し回数と着色状態での可視領域の極大吸収波長の反射濃度の関係図である。図２に示した結果は、（実施例１）および（比較例）における表示媒体のそれぞれに、蛍光ブラックライトを用いてピーク波長 365ｎｍの紫外光を照射して着色状態とした後、ハロゲンランプを用いて消色状態にする操作を１回として、この操作を繰り返した際の繰り返し回数と反射濃度との関係を示しており、曲線（ａ）は（実施例１）における表示媒体について、また、曲線（ｂ）は（比較例）における表示媒体について得られた結果である。
【００４８】
尚、上記着色状態・消色状態の繰り返し操作において、第１回目の蛍光ブラックライトによる照射の際に、照射開始から着色状態での可視領域の極大吸収波長における反射濃度が 1.0となるまでの時間をそれぞれの表示媒体について決定し、第２回目以降については、蛍光ブラックライトによる照射時間が各々第１回目と同じとなるようにした。
【００４９】
また、ハロゲンランプによる照射は、可視領域の極大吸収波長における反射濃度が 0.1となるまで行った。図２より（比較例）における表示媒体では、1,000 回までの繰り返し操作において明らかに反射濃度が低下し、繰り返し回数とともに表示媒体のコントラストが劣化する傾向が認められるのに対して、本発明の（実施例１）における表示媒体は、1,000 回までの繰り返し操作の間、反射濃度の低下が認められないことが判明した。
【００５０】
以上のように、本発明により、従来のフォトクロミック材料および従来の方法により作製されたフォトクロミック材料を用いる表示媒体に比べて、着色速度が速く、すなわち小さな光照射エネルギーで着色が可能であるとともに、着色状態と消色状態の繰り返し耐久性に優れたフォトクロミック材料を表示層とする表示媒体を得ることが可能となる。
【００５１】
（実施の形態２）
以下に、本発明の（実施の形態２）におけるフォトクロミック材料を用いた表示装置の具体例を説明する。
【００５２】
図３は本発明の表示装置を示す。表示装置１は、フォトクロミック材料を用いた表示媒体を有する表示部２とキーパネル３とインターフェイス部４からなる。キーパネル３は、文字または画像などの情報を読み取ることが可能なスキャナー５と、それらの情報を入力し、記憶することが可能なパソコン６から送られる文字または画像などの情報を表示部２に表示する命令を入力するための書き込みキーと表示部２に表示された文字または画像などの情報を消去する命令を入力するための消去キーを有している。スキャナー５およびパソコン６はインターフェイス部４を介して表示装置１と接続されている。
【００５３】
図４は表示装置１の断面図を示す。表示部２はシート状であり、表示部送り機構７によって回動可能となっている。尚、図４の矢印は表示部２の回動方向を示している。表示部２は本発明の表示媒体より構成されるものであるが、この表示媒体のフォトクロミック材料からなる表示層の表面が透明な樹脂などにより保護された構造でもよい。
【００５４】
表示部送り機構７は、表示部送り機構駆動部８により駆動され、表示部送り機構駆動部８はＣＰＵおよびメモリを内蔵する情報表示制御部９によって制御されている。
【００５５】
着色用光源ユニット１０は、蛍光ブラックライト、若しくは光学フィルターにより可視光領域を除いた超高圧水銀ランプ，キセノンランプなどの光源と、光シャッターアレイより構成される。着色用光源ユニット１０は、その長手方向を表示部２の回動方向と垂直にする形で水平方向に配置され、情報表示制御部９によって制御される着色用光源駆動部１１によって、光源の点滅および光シャッターアレイの開閉が制御され、着色用光源からの照射光によって表示部２が着色状態となる。
【００５６】
消色用光源ユニット１２は、ハロゲンランプ、若しくは光学フィルターにより紫外領域を除いた超高圧水銀ランプおよびキセノンランプなどの光源より構成される。消色用光源ユニット１２は、着色用光源ユニット１０と同様に水平方向に配置され、情報表示制御部９によって制御される消色用光源駆動部１３によって光源の点滅が制御され、消色用光源からの照射光によって表示部２が消色状態となる。また、情報表示制御部９は、図３に示したキーパネル３とインターフェイス部４に接続されている。
【００５７】
このような構成を有する表示装置の動作について説明する。キーパネル３内の書き込みキーを操作することにより、インターフェイス部４を介してスキャナー５またはパソコン６から文字または画像などの情報が情報表示制御部９内のメモリーに取り込まれた後、表示部送り機構７により表示部２が回動するとともに、着色用光源ユニット１０内の光源が点灯しながら走査される形となる。
【００５８】
この走査の間に、一定の距離間隔毎に着色用光源ユニット１０内に配設された光シャッターアレイの各セルの開閉が制御され、情報表示制御部９内のメモリーに取り込まれた文字または画像などの情報に対応して、着色用光源ユニット１０内の光源より紫外線が表示部２に照射され着色状態となる。これにより、スキャナー５またはパソコン６から取り込まれた文字または画像などの情報が表示部２に表示される。
【００５９】
また、キーパネル３内の消去キーを操作することにより、表示部送り機構７により表示部２が回動するとともに、消色用光源ユニット１２内の光源が点灯しながら走査される形となる。この走査の間に、文字または画像などの情報が表示された表示部２に消色用光源ユニット１２内の光源より可視光が照射され消色状態となる。これにより、表示部２の文字または画像などの情報が消去される。
【００６０】
（実施例３）
上記構成を有する表示装置について、表示部が（実施例１）および（比較例）における表示媒体を用いた表示装置をそれぞれ作製し、光照射に対する感度と着色状態、消色状態の繰り返し耐久性について調べた結果を下記（表１）を用いて説明する。
【００６１】
【表１】

【００６２】
尚、表示部はいずれもＡ１用紙サイズであり、着色用光源には最大ピーク波長 365ｎｍの蛍光ブラックライトを使用し、消色用光源にはハロゲンランプを用いた。（表１）において、書き込み時間とは表示装置の開口部の面積に相当する表示部を着色させるのに必要な時間である。また、（表１）に示した書き換え回数とは、表示部を着色状態・消色状態にする操作を１回として、この操作を連続的に繰り返しながら着色状態での可視領域の極大吸収波長における反射濃度を測定し、反射濃度が第１回目の操作における反射濃度の 80 ％に減衰するまでの操作回数である。
【００６３】
（表１）より、従来の方法により作製した（比較例）における表示媒体を用いる表示装置に比べて、本発明の（実施例１）における表示媒体を用いた表示装置では、書き込み時間が１／８となり、書き換え回数は２倍以上となったことが判る。
【００６４】
以上のように、本発明により、従来の方法により作製されたフォトクロミック材料を用いた表示媒体を有する表示装置に比べて、書き込み時間を著しく短縮し、かつ、繰り返しの書き換え操作に対して著しく優れた耐久性を有する表示装置を得ることが可能となる。
【００６５】
【発明の効果】
以上のように本発明によれば、本発明のフォトクロミック材料を用いる表示媒体ならびに表示装置は、以下のような優れた効果を有する。
（１）着色速度が速いことから、短時間により多くの文字や画像などの情報を高いコントラストで表示することができるという優れた効果を有する。
（２）着色に必要な照射エネルギーが小さいことから、着色に必要な光源に大型の装置を用いる必要がなく、さらに文字や画像などの情報の表示をより省エネルギーで実施できるという優れた効果を有する。
（３）着色・消色状態の繰り返し耐久性が高いことから、文字や画像などの情報の表示・消去を繰り返しても表示速度やコントラストの低下がなく表示ができるという優れた効果を有する。
【図面の簡単な説明】
【図１】本発明の（実施例１）および（比較例）における表示媒体の照射エネルギーと可視領域における極大吸収波長での反射濃度の関係図
【図２】本発明の（実施例１）および（比較例）における着色・消色の繰り返し回数と着色状態での可視領域の極大吸収波長における反射濃度の関係図
【図３】本発明の一実施の形態による表示装置の斜視図
【図４】本発明の一実施の形態による表示装置の断面図
【符号の説明】
１ 表示装置
２ 表示部
３ キーパネル
４ インターフェイス部
５ スキャナー
６ パソコン
７ 表示部送り機構
８ 表示部送り機構駆動部
９ 情報表示制御部
１０ 着色用光源ユニット
１１ 着色用光源駆動部
１２ 消色用光源ユニット
１３ 消色用光源駆動部[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a display medium using a photochromic material and a display device.
[0002]
[Prior art]
In recent years, various photochromic compounds whose hue changes reversibly by light irradiation have been proposed, and research and development on display devices using photochromic compounds as display media capable of coloring and decoloring have been actively conducted. .
[0003]
Photochromic materials applied to such display media are required to have excellent characteristics in (a) thermal stability, (b) sensitivity, (c) repeated durability, and the like. Various organic compounds and processes for their properties have been proposed.
[0004]
Existing organic photochromic compounds include diazo compounds, benzospiropyrans, naphthoxazines, fulgides or diarylethenes, but these organic photochromic compounds are generally either colored or decolored. It is thermally unstable. Further, some diarylethenes have relatively high thermal stability and repeated durability as disclosed in JP-A-4-360886, but this organic compound also has improved sensitivity to light irradiation such as coloring speed. At present, it is difficult to say that an organic photochromic material that sufficiently satisfies the characteristics as a display medium has been obtained.
[0005]
On the other hand, the characteristics of a display medium using an organic photochromic compound include not only the physical and chemical characteristics of the organic compound used, but also a display layer made of an organic photochromic compound for application as a display medium, usually on a suitable substrate. It also strongly depends on the processing method in forming. As such a processing method,
(1) A method in which an organic photochromic compound is vapor-deposited on a substrate by various vapor deposition methods such as a vacuum vapor deposition method and a sputtering method, or an organic photochromic compound and another compound are co-deposited.
(2) A solution in which an organic photochromic compound is dispersed or dissolved in an appropriate solvent is applied onto a substrate by various coating methods such as a doctor blade method, a cast method, a spinner method, or the like. Dipping the substrate in
(3) A solution in which an organic photochromic compound and a binder are dispersed or dissolved in a suitable solvent is applied onto a substrate by various coating methods such as a doctor blade method, a cast method, a spinner method, or the like. A method of immersing a substrate in a solution.
Etc. are known.
[0006]
Here, examples of the solvent include organic solvents such as benzene, toluene, hexane, cyclohexane, methyl ethyl ketone, acetone, methanol, ethanol, tetrahydrofuran, dioxane, carbon tetrachloride, and chloroform.
[0007]
Examples of the binder include polyester resin, polystyrene resin, polyvinyl butyral resin, polyvinyl chloride, polyvinylidene chloride, polyvinyl acetate, cellulose acetate, polymethyl methacrylate, polybutyl methacrylate, polycarbonate resin, phenol resin, and epoxy resin. Is used.
[0008]
In the processing methods (2) and (3) above, the organic photochromic compound and the binder are often dissolved in the solvent.
Furthermore, instead of forming a display layer on the substrate,
(4) There is also a method of forming a display layer by enclosing a solution in which an organic photochromic compound and a binder are dispersed or dissolved in an appropriate solvent in a glass cell.
[0009]
Among the above-mentioned treatment methods, the method (1) requires heating the organic photochromic compound, so that the deposition conditions are limited so as not to cause structural degradation such as thermal decomposition. Therefore, there is a limit in controlling the thickness of the formed display layer and the adhesion to the substrate, and it is not suitable for forming a display layer having a large surface area.
[0010]
In addition, the method (4) is suitable for short-time use for the purpose of evaluating the characteristics of the organic photochromic compound itself, but for long-term use as a display medium, the change of the solvent due to light irradiation, the cell There are problems in terms of maintaining the sealing property and producing a cell having a high surface area.
[0011]
On the other hand, in the methods (2) and (3), it is estimated that the dissolved state of the organic photochromic compound in the solvent and the dispersion state of the organic photochromic compound in the binder after forming the display layer affect the photochromic properties. However, it is hard to say that sufficient consideration has been made on this point.
[0012]
[Problems to be solved by the invention]
As described above, organic photochromic materials used for display media and display devices have been proposed as organic compounds that have been improved in terms of thermal stability. In view of the repeated durability of the state, development of a utilization form of a photochromic material having further excellent characteristics is required.
[0013]
Further, in order to achieve application as a display medium without impairing the original characteristics of the organic photochromic material, further improvement is required for the processing method when forming the display layer made of the organic photochromic material.
[0014]
The present invention solves the above-mentioned conventional problems, and the display medium has a high coloring speed, that is, can be colored with a smaller light irradiation energy, and is excellent in repeated durability between a colored state and a decolored state, and An object of the present invention is to provide a display device that has a high writing speed and excellent rewrite durability.
[0015]
[Means for Solving the Problems]
The display medium and display device using the photochromic material of the present invention have a configuration in which a single crystal fine powder of an organic compound having photochromic properties is applied on a substrate with a material dispersed in a binder that supports the fine powder. It becomes more.
[0016]
With these configurations, it is possible to provide a display medium and a display device that are fast in coloring speed, that is, can be colored with a small light irradiation energy and are excellent in repeated durability in a colored state and a decolored state.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
In the first aspect of the present invention, a single crystal fine powder of an organic compound having a photochromic property even in a crystalline state is coated on a substrate with a material dispersed in a binder supporting the fine powder. Thus, a display medium having a high coloring rate, that is, capable of being colored with a small light irradiation energy and having excellent repeated durability in a colored state and a decolored state can be obtained.
[0018]
The invention according to claim 2 of the present invention is the method according to claim 1, wherein the organic compound is 1,2-bis (2,4-dimethyl-5-phenylthiophen-3-yl) -3,3,4,4. , 5,5-hexafluorocyclopentene, or 1,2-bis (2,4-dimethyl-5- (4-cyanophenyl) thiophen-3-yl) -3,3,4,4,5,5-hexa Fluorocyclopentene or 1,2-bis (2,4-dimethylthiophen-3-yl) -3,3,4,4,5,5-hexafluorocyclopentene or 1,2-bis (2,4-dimethyl) Thiophen-5-yl) -3,3,4,4,5,5-hexafluorocyclopentene , which has a high coloration speed, that is, it can be colored with small light irradiation energy. With It has an effect that a display medium excellent in repeated durability in a colored state and a decolored state and having excellent thermal stability can be obtained.
[0019]
The invention according to claim 3 of the present invention is the method according to claim 1 or 2, wherein the solvent is water, the binder is polyvinyl alcohol, and the single crystal fine powder of the organic compound is a binder. The display medium uniformly dispersed therein can be obtained.
[0020]
According to a fourth aspect of the present invention, there is provided a display unit having the display medium according to any one of the first, second and third aspects, and input means for inputting information to be displayed on the display unit. And an erasing unit for erasing information displayed on the display unit, and has a function of obtaining a display device having a high writing speed and excellent repetitive durability of rewriting.
[0021]
Next, a specific example of the embodiment of the present invention will be described.
(Embodiment 1)
The display medium using the photochromic material in (Embodiment 1) of the present invention will be described below.
[0022]
The organic compound may be any organic compound having photochromic properties, such as a diazo compound, benzospiropyrans, naphthoxazines, fulgides, or diarylethenes, and that does not lose photochromic properties even in a crystalline state.
[0023]
In particular, it is preferable to use a diarylethene compound which is excellent in terms of repeated durability. Specific examples of such a diarylethene compound include the compounds shown in the following (Chemical Formula 1) to (Chemical Formula 4). Can do.
[0024]
[Chemical 1]

[0025]
[Chemical 2]

[0026]
[Chemical 3]

[0027]
[Formula 4]

[0028]
In the present invention, fine powder obtained by pulverizing a single crystal of the organic compound crystallized by a recrystallization method or the like is used. Binders supporting single crystal fine powders of organic compounds include polyester resin, polystyrene resin, polyvinyl butyral resin, polyvinyl chloride, polyvinylidene chloride, polyvinyl acetate, cellulose acetate, polymethyl methacrylate, polybutyl methacrylate, Any material such as a polycarbonate resin, a phenol resin, an epoxy resin, or polyvinyl alcohol that can disperse and hold a fine powder of a single crystal of an organic compound while maintaining the crystalline state therein may be used.
[0029]
As the solvent in which the fine powder of the single crystal of the organic compound is dispersed and the binder is dissolved, a solvent in which the fine powder of the single crystal of the organic compound is insoluble in the solvent but the binder is soluble is used.
[0030]
A substrate for a general display medium such as plate-like or foil-like glass, plastic, paper, or metal is used as a substrate on which a solution comprising a single crystal fine powder of an organic compound, a binder, and a solvent is applied. .
[0031]
With the above configuration, the single crystal fine powder of the organic compound having photochromic properties is dispersed in the binder supporting the fine powder, so that the coloring speed is high, that is, the coloring can be performed with a small light irradiation energy. It is possible to obtain a photochromic material excellent in repeated durability in a colored state and a decolored state, and a display medium using the photochromic material.
[0032]
Next, display media using the photochromic material in (Embodiment 1) of the present invention will be described with reference to (Example 1) and (Comparative Example).
[0033]
Example 1
By a known method, 1,2- (2,4-dimethyl-5-phenylthiophen-3-yl) -3,3,4,4,5,5-hexafluorocyclopentene (hereinafter referred to as compound) is a diarylethene compound. 1) was synthesized and purified.
[0034]
As shown in the following (Chemical Formula 5), Compound 1 is closed by irradiation with ultraviolet light, and changes to a colored state (blue purple). Moreover, by irradiating this with visible light, the ring is opened and the original decolored state (colorless) is restored.
[0035]
[Chemical formula 5]

[0036]
The compound 1 was dissolved in hexane and allowed to stand at room temperature to gradually evaporate the hexane to precipitate a single crystal of the compound 1, which was pulverized into a fine powder. This fine powder was added to an aqueous solution in which 17.5% by weight of polyvinyl alcohol was dissolved, and the mixture was stirred and dispersed uniformly to obtain an opaque slurry-like solution. At this time, Compound 1 was added in an amount of 5.3% by weight to the solution.
[0037]
Polyvinyl alcohol is soluble in water, and it has been confirmed in advance that Compound 1 does not dissolve in water. After this solution was applied on a white PET substrate, it was formed into a thin film using a wire bar and then dried at 80 ° C. for 8 hours to produce a display medium having a display layer made of a photochromic material.
[0038]
The thickness of this display layer was 30 μm. When this display medium was irradiated with ultraviolet rays using fluorescent black light, it was colored blue-violet, and the maximum absorption wavelength in the visible region at the time of coloring was 618 nm.
[0039]
Further, when the colored display layer was irradiated with visible light using a halogen lamp, it returned to its original colorless state. This colored state and decolored state could be repeated.
[0040]
(Comparative example)
1,2- (2,4-dimethyl-5-ethoxyphenylthiophen-3-yl) -3,3,4,4,5,5-hexa, represented by the following (Chemical Formula 6), obtained by a known method Using a solution obtained by completely dissolving 6.0 wt% of a purified product of fluorocyclopentene (hereinafter referred to as compound 2) and 14 wt% of polystyrene resin in toluene, a white PET substrate was prepared in the same manner as in Example 1. A display medium having a film thickness of 30 μm formed thereon was produced.
[0041]
[Chemical 6]

[0042]
When this display medium was irradiated with ultraviolet light using fluorescent black light, it was colored blue-violet, and the maximum absorption wavelength in the visible region at the time of coloring was 588 nm. Further, when the colored display layer was irradiated with visible light using a halogen lamp, it returned to its original colorless state.
[0043]
Next, for each of the display media in (Example 1) and (Comparative Example), the results of examining the sensitivity to light irradiation and the repeated durability in the colored state and the decolored state will be described with reference to FIGS. 1 and 2. To do.
[0044]
FIG. 1 is a relationship diagram between the irradiation energy of the display medium and the reflection density at the maximum absorption wavelength in the visible region in (Example 1) and (Comparative Example) of the present invention, and the curve (a) is (Example 1). The curve (b) is the result obtained for the display medium in (Comparative Example). Each display medium was irradiated with ultraviolet light having a maximum peak wavelength of 365 nm from a decolored state using a fluorescent black light.
[0045]
From FIG. 1, the display medium in (Example 1) of the present invention is necessary to have the same reflection density, that is, the same colored state as the display medium in (Comparative Example) produced by the conventional method. It can be seen that there is very little irradiation energy.
[0046]
In general, when displaying characters or images on a display medium using a photochromic material, the reflection density in the colored state is required to be 1 or more in order to display with clear contrast. The irradiation energy required for the reflection density to be 1 in the display medium in 1) is 1/8 or less that of the display medium in (Comparative Example).
[0047]
FIG. 2 is a graph showing the relationship between the number of repetitions of coloring / decoloring and the reflection density at the maximum absorption wavelength in the visible region in the colored state in (Example 1) of the present invention and (Comparative Example) produced by the conventional method. . The results shown in FIG. 2 show that each of the display media in (Example 1) and (Comparative Example) is irradiated with ultraviolet light having a peak wavelength of 365 nm using a fluorescent black light to be colored, and then a halogen lamp is used. The relationship between the number of repetitions and the reflection density when this operation is repeated is shown as a single operation to be used for decoloring, and the curve (a) shows the display medium in (Example 1), and Curve (b) is the result obtained for the display medium in (Comparative Example).
[0048]
In the repeated operation of the colored state and the decolored state, during the first irradiation with the fluorescent black light, the time from the start of irradiation until the reflection density at the maximum absorption wavelength in the visible region in the colored state reaches 1.0. Was determined for each display medium, and for the second and subsequent times, the irradiation time with the fluorescent black light was set to be the same as the first time.
[0049]
Irradiation with a halogen lamp was performed until the reflection density at the maximum absorption wavelength in the visible region reached 0.1. In the display medium in FIG. 2 (comparative example), the reflection density clearly decreases after repeated operations up to 1,000 times, and the contrast of the display medium tends to deteriorate with the number of repetitions. The display medium in Example 1) was found to show no reduction in reflection density during repeated operations up to 1,000 times.
[0050]
As described above, according to the present invention, the coloring speed is higher than that of a display medium using a conventional photochromic material and a photochromic material manufactured by a conventional method, that is, coloring is possible with small light irradiation energy. It becomes possible to obtain a display medium having a display layer made of a photochromic material excellent in repeated durability between the state and the decolored state.
[0051]
(Embodiment 2)
A specific example of a display device using a photochromic material in (Embodiment 2) of the present invention will be described below.
[0052]
FIG. 3 shows a display device of the present invention. The display device 1 includes a display unit 2 having a display medium using a photochromic material, a key panel 3, and an interface unit 4. The key panel 3 includes a scanner 5 capable of reading information such as characters or images, and information such as characters or images sent from the personal computer 6 that can input and store the information on the display unit 2. A write key for inputting a command to be displayed and an erase key for inputting a command for erasing information such as characters or images displayed on the display unit 2 are provided. The scanner 5 and the personal computer 6 are connected to the display device 1 via the interface unit 4.
[0053]
FIG. 4 shows a cross-sectional view of the display device 1. The display unit 2 has a sheet shape and can be rotated by a display unit feeding mechanism 7. In addition, the arrow of FIG. 4 has shown the rotation direction of the display part 2. FIG. The display unit 2 is composed of the display medium of the present invention, but may have a structure in which the surface of the display layer made of the photochromic material of the display medium is protected by a transparent resin or the like.
[0054]
The display unit feeding mechanism 7 is driven by a display unit feeding mechanism driving unit 8, and the display unit feeding mechanism driving unit 8 is controlled by an information display control unit 9 incorporating a CPU and a memory.
[0055]
The coloring light source unit 10 includes a light source such as a fluorescent black light or an ultrahigh pressure mercury lamp or a xenon lamp excluding a visible light region by an optical filter, and an optical shutter array. The coloring light source unit 10 is arranged in the horizontal direction so that its longitudinal direction is perpendicular to the rotation direction of the display unit 2, and the light source driving unit 11 for coloring controlled by the information display control unit 9 blinks the light source. The opening and closing of the optical shutter array is controlled, and the display unit 2 is colored by the irradiation light from the coloring light source.
[0056]
The erasing light source unit 12 is composed of a light source such as a halogen lamp or an ultra-high pressure mercury lamp and an xenon lamp excluding the ultraviolet region by an optical filter. The erasing light source unit 12 is arranged in the horizontal direction in the same manner as the coloring light source unit 10, and the blinking of the light source is controlled by the erasing light source driving unit 13 controlled by the information display control unit 9. The display unit 2 is in a decolored state by the irradiation light from. Further, the information display control unit 9 is connected to the key panel 3 and the interface unit 4 shown in FIG.
[0057]
The operation of the display device having such a configuration will be described. By operating a writing key in the key panel 3, information such as characters or images is taken into the memory in the information display control unit 9 from the scanner 5 or the personal computer 6 via the interface unit 4, and then the display unit feeding mechanism. 7, the display unit 2 is rotated, and the light source in the coloring light source unit 10 is scanned while being turned on.
[0058]
During this scanning, the opening or closing of each cell of the optical shutter array disposed in the coloring light source unit 10 is controlled at regular intervals, and the characters or images captured in the memory in the information display control unit 9 are controlled. Corresponding to such information, the display unit 2 is irradiated with ultraviolet rays from the light source in the coloring light source unit 10 to be colored. As a result, information such as characters or images captured from the scanner 5 or the personal computer 6 is displayed on the display unit 2.
[0059]
Further, by operating the erase key in the key panel 3, the display unit 2 is rotated by the display unit feed mechanism 7, and the light source in the erasing light source unit 12 is scanned while being turned on. During this scanning, visible light is emitted from the light source in the decoloring light source unit 12 to the display unit 2 on which information such as characters or images is displayed, and the display unit 2 is in a decoloring state. Thereby, information such as characters or images on the display unit 2 is erased.
[0060]
(Example 3)
About the display apparatus which has the said structure, the display part produces the display apparatus using the display medium in (Example 1) and (comparative example), respectively, About the sensitivity with respect to light irradiation, and the repeated durability of a coloring state and a decoloring state The results of the investigation will be described using the following (Table 1).
[0061]
[Table 1]

[0062]
The display sections were all A1 paper size, a fluorescent black light having a maximum peak wavelength of 365 nm was used as the coloring light source, and a halogen lamp was used as the decoloring light source. In (Table 1), the writing time is a time required for coloring the display portion corresponding to the area of the opening of the display device. In addition, the number of rewrites shown in (Table 1) refers to the maximum absorption wavelength in the visible region in the colored state while repeating this operation once, with the operation of setting the display portion in the colored state / decolored state once. The number of operations until the reflection density is measured and the reflection density attenuates to 80% of the reflection density in the first operation.
[0063]
As shown in Table 1, in the display device using the display medium according to (Example 1) of the present invention, the writing time is 1/0 as compared with the display device using the display medium according to the conventional method (Comparative Example). It can be seen that the number of rewrites is more than doubled.
[0064]
As described above, according to the present invention, writing time is remarkably shortened and repetitive rewriting operations are significantly improved as compared with a display device having a display medium using a photochromic material manufactured by a conventional method. A display device having durability can be obtained.
[0065]
【The invention's effect】
As described above, according to the present invention, the display medium and the display device using the photochromic material of the present invention have the following excellent effects.
(1) Since the coloring speed is high, it has an excellent effect that information such as a large number of characters and images can be displayed with high contrast in a short time.
(2) Since the irradiation energy required for coloring is small, it is not necessary to use a large device as a light source required for coloring, and further, it has an excellent effect that information such as characters and images can be displayed with more energy saving. .
(3) Since the repeated durability in the colored / decolored state is high, there is an excellent effect that even if display / erasure of information such as characters and images is repeated, display can be performed without a decrease in display speed and contrast.
[Brief description of the drawings]
FIG. 1 is a graph showing the relationship between irradiation energy of a display medium and reflection density at a maximum absorption wavelength in the visible region in (Example 1) and (Comparative Example) of the present invention. FIG. 3 is a perspective view of a display device according to an embodiment of the present invention. FIG. 3 is a relationship diagram of the number of repetitions of coloring / decoloring in (Comparative Example) and the reflection density at the maximum absorption wavelength in the visible region in the colored state. Sectional drawing of the display apparatus by one embodiment of this invention
DESCRIPTION OF SYMBOLS 1 Display apparatus 2 Display part 3 Key panel 4 Interface part 5 Scanner 6 Personal computer 7 Display part feed mechanism 8 Display part feed mechanism drive part 9 Information display control part 10 Coloring light source unit 11 Coloring light source drive part 12 Decoloring light source unit 13 Decoloring light source driver

Claims (4)

A display medium in which a fine powder of a single crystal of an organic compound having photochromic properties even in a crystalline state is coated on a substrate with a material dispersed in a binder that supports the fine powder. The organic compound is 1,2-bis (2,4-dimethyl-5-phenylthiophen-3-yl) -3,3,4,4,5,5-hexafluorocyclopentene, or 1,2-bis (2 , 4-Dimethyl-5- (4-cyanophenyl) thiophen-3-yl) -3,3,4,4,5,5-hexafluorocyclopentene, or 1,2-bis (2,4-dimethylthiophene- 3-yl) -3,3,4,4,5,5-hexafluorocyclopentene or 1,2-bis (2,4-dimethylthiophen-5-yl) -3,3,4,4,5 The display medium according to claim 1, wherein the display medium is any one of 5-hexafluorocyclopentene . The display medium according to claim 1 or 2, wherein the binder is polyvinyl alcohol.   A display unit having the display medium according to claim 1, claim 2, input means for inputting information to be displayed on the display unit, and information displayed on the display unit A display device comprising erasing means for erasing.

Images