JP4338152B2 - Display media - Google Patents

Description

【００３９】
式（１）において、εは絶縁性液体の誘電率、ηは絶縁性液体の粘度、ζは電気泳動子のζ電位、ｄは横断距離、Ｅは電界、Ｖは印加電圧を示す。式（１）より、応答速度は電気泳動子の粒径によらずζ電位で決まることがわかる。
【００４０】
次に本発明の表示媒体の作製方法の一例について説明する。
図６は本発明の表示媒体の製造方法を示す工程図である。同図において、先ず、記録媒体の絶縁性支持体を形成するための材料には不溶でかつキャビティ内に充填する絶縁性液体に可溶性の材料、たとえばワックス６１と、帯電粒子３とを混合してなる被覆材料６２を適当な色を有する直径５〜１００μｍ程度の微小球４の表面に被覆する（図６（ａ）参照）。ワックス６１に混合する帯電粒子３の分量は各キャビティ内に封入したい分量とする。また微小球４の色は、それ自身の有する色でもまた適当な着色層で表面を被覆してもどちらでもよい。微小球の材料としては、例えばガラス、ジルコニア、窒化シリコン、シリコン、アルミナを挙げることができる。該微小球の帯電を防止するために適当な導電性を有する材料、例えばｎまたはｐ型にドープされたシリコンを用いて微小球を作成したり、或いは微小球表面に帯電防止膜を堆積させてもよい。勿論先に述べたように該微小球が帯電性を有する場合であっても、帯電粒子との帯電状態に差があって、適当な条件下で駆動可能であれば構わない。
【００４１】
帯電粒子３は微小球４とは異なる色を有することと、その径が微小球よりも小さい必要があり、例えば黒色の場合、複写機等に用いられるトナーを利用することができる。
【００４２】
次に前記被覆層６２で被覆した微小球４と、絶縁性支持体１を形成するための硬化性を有する高分子支持材料６３、例えばシリコンゴムとを混合し、表面が平滑な基板６４、例えばガラス基板上に塗布し、適当なカバーフィルム６５、例えばＰＥＴフィルムを用いて圧延により高分子材料６３と被覆された微小球との混合物をシート化する（図６（ｂ）参照）。或いはドクターブレード法や印刷手法によリシート化してもよい。或いは、特開昭５８−１２２５１９号公報に開示されるように、被覆された微小球を適当な液中に分散・沈降させて被覆された微小球を一様に単層または多層に堆積された堆積膜を基板上に形成した後、係る分散媒に可溶である絶縁性支持体を形成する硬化性の高分子支持材料を注入し、被覆された微小球を包み込むようにして流延させ、引き続き前記分散媒を除去して、被覆された微小球と硬化性高分子支持材料からなるシートを作製してもよい。
【００４３】
次に、係る高分子支持材料６３を硬化させた後、シートをガラス基板６４から剥離し、膨潤液６６中に浸漬する（図６（ｃ）参照）。係る膨潤液６６は本発明の表示媒体に含まれる絶縁性液体として利用されるものでもよく、例えばシリコンオイルを挙げることができる。係る膨潤液への浸漬により、硬化された高分子支持材料６３が膨潤し、また同時に微小球４に被覆したワックス６１が溶解し、微小球４と絶縁性支持体１との間に隙間ができ、キャビティ２が形成される。このキャビティ２内には、膨潤液６６が充填されており、係る膨潤液６６が透明性であり、帯電粒子を電気泳動させるのに好適な粘度及び十分に高い電気抵抗を有している場合には、そのまま絶縁性液体５として利用できる。絶縁性液体として利用し得ない場合には、適当な絶縁性液体と置換すればよい。帯電粒子３は膨潤液６６および絶縁性液体５には不溶であるので、キャビティ２内に閉じ込められる。
【００４４】
以上の工程により、本発明の表示媒体を形成する帯電粒子３と微小球４と絶縁性液体５を保持してなるキャビティ２を複数個含む絶縁性支持体１が形成される（図６（ｄ）参照）。
【００４５】
引き続き、係る帯電粒子３と微小球４と絶縁性液体５を保持してなるキャビティ２を複数個含む絶縁性支持体１に導電層または電極を形成する。導電層または電極は従来公知の薄膜形成方法により、直接絶縁性支持体１上に直接堆積させてもよいが、図６（ｅ）に示すように他の適当な基板２１上に導電層６を堆積させたものと貼り合わせて作製してもよい。絶縁性支持体１表面上、導電層６と反対側にあるカバーフィルム６５はあっても剥離してもどちらでも構わないが、絶縁性支持体１から絶縁性液体５が沁み出し沁み出すことを防ぐために何らかの表面保護層２２を設けることが好ましい。カバーフィルム６５を剥離することなく、そのま表面保護層２２として利用しても構わない。また絶縁性支持体１の端面からの絶縁性液体５の沁み出しを防止するために、端面を接着剤等を用いて封止しておくことが好ましい。
【００４６】
図６（ｅ）では、本発明の第一の構成を有する表示媒体の構成となっているが、図６（ｄ）の工程の後、絶縁性支持体１表面上に導電層を形成する代わりに、カバーフィルム６５を剥離した後、一対の電極で帯電粒子３、微小球４、絶縁性液体５を保持してなるキャビティ２を複数個含む絶縁性支持層１を挟持させれば、本発明の第二の構成を有する表示媒体とすることができる（図６（ｆ）参照）。
【００４７】
図６（ｆ）では、適切な形状にパターニングされた第１電極３１を有する第１基板６７と、第２電極３２を有する第２基板６８との間に、絶縁性支持体１を挟持させている。観察者に近い側に配置される、第１基板６７及び第１電極は光学的に透明であることが要求され、透明電極材料としては、例えば酸化インジウムすず（ＩＴＯ）がある。なお絶縁性支持体１の端面からの絶縁性液体５の沁みだしを防止するために、端面を接着剤等を用いて封止しておくことが好ましい。
【００４８】
これら第１および第２の構成を有する表示媒体において、基板２１、６７、６８の材料としては、ポリエチレンテレフタレート（ＰＥＴ）、ポリエーテルサルフォン（ＰＥＳ）等のポリマーフィルム或いはガラス、石英等の無機材料を使用することができる。ポリマーフィルムを使用すれば、表示媒体をフレキシブルシート状に形成することもできる。
【００４９】
【実施例】
以下本発明を実施例を用いて説明する。
【００５０】
実施例１
本実施例では、図６に示す方法で本発明の表示媒体を作製した。
微小球４として、５０μｍジルコニアボールを用いた。該ジルコニアボールに、帯電粒子２とワックス６１を混ぜ合わせたものをスプレーコートして厚さ１０μｍ程度の被覆６２を形成した。帯電粒子２としては、ポリスチレンとカーボンの混合物で、粒子の大きさがｌμｍ〜２μｍ位のものを使用した（図６（ａ））。
【００５１】
次に、２液型シリコーンゴム（ダウコーニング社製、シルポット１８４）中に前記被覆付きジルコニアボールを分散させ、ガラス基板６４上で厚さ１００μｍのＰＥＴフィルム６５を用いて、この分散系を厚さ約１００μｍの膜状に圧延した後、該シリコーンゴムを１００℃、１時間の条件で加熱硬化させた（図６（ｂ））。
【００５２】
次に上記微小ボール分散硬化ゴムシートをガラス基板６４より剥離し、粘度ｌｃｓのシリコーンオイル（東芝シリコーン社製）６６中に２４時間浸漬して該ゴムシートを膨潤させ（図６（ｃ））、微小球の周囲にキャビティ（隙間５〜１０μｍ）２を形成させると同時に、係るキャビティ２内に保持されたシリコーンオイル６６をそのまま絶縁液５として利用することにした（図６（ｄ））。
【００５３】
次に上記ゴムシートとＩＴＯ電極６付きＰＥＳフィルム２１（厚さ１００μｍ）とを貼り合わせて、表示媒体を作製した（図６（ｅ））。ＰＥＴフィルム６５はそのま表面保護層２２として利用することにした。
【００５４】
かかるフレキシブルシート状表示媒体に対して、ＰＥＴフィルム２２面側から、コロナワイヤ（直径６０μｍの金めっきタングステン線）に正または負の３〜１０ｋＶ程度の電圧を印加する事により発生するイオンを用いてＰＥＴフィルム２２上を選択的に帯電させて静電潜像を形成すると、正に帯電させた部分では帯電粒子３が表面保護層２２側に移動・吸着され、負に帯電された部分では導電層６側に移動・吸着され、所望の白黒表示が行われることを確認した。この際、応答速度は３０ｍｓ以下で、コントラスト比は約５：１であった。また視野角特性は±８５°以上であった。
【００５５】
実施例２
実施例１と同様にして、ＰＥＴフィルム６５上に帯電粒子３、微小球４、シリコーンオイルからなる絶縁液５を保持してなるキャビティ２を複数個含むゴムシートを形成した（図６（ｄ））後、ゴムシートをＰＥＴフィルム６５から剥離し、更に該ゴムシートをＩＴＯ電極膜付きＰＥＳ基板で挟持させて、表示媒体を作製した（図６（ｆ））。
【００５６】
該表示媒体に±１００Ｖの電界を印加すると、電界の極性に応じて観察側に帯電粒子３または微小球４が現れた。
【００５７】
詳しくは、観察側の第１電極３１が陰極になるように電界を印加すると観察側に帯電粒子３が移動・吸着して黒色が観察された。電界を逆極性にすると帯電粒子３は反対側の第２電極３２側へと移動・吸着し、結果として微小球４の白色が観察された。この際、応答速度は３０ｍｓ以下で、コントラスト比は約５：１であった。また視野角特性は±８５°以上であった。
【００５８】
【発明の効果】
以上説明したように、本発明の表示媒体により、２色表示を達成することが可能となった。この表示媒体に用いる微小球は、単色なので安価に入手することが可能な微小球をそのまま使用することができ、また着色、帯電防止などの目的で表面に被覆を行う際にも、２色に塗り分ける必要がないので、工程上形成が容易である。
また、帯電粒子および微小球各々固有の色を用いて表示を行うので、カラー化が容易である。
【図面の簡単な説明】
【図１】本発明の表示媒体の第一の形態の断面図である。
【図２】本発明の表示媒体の第一の形態の断面図である。
【図３】本発明の表示媒体の第二の形態の断面図である。
【図４】本発明の表示媒体の第一の形態における表示方法を示す図である。
【図５】本発明の表示媒体の第二の形態における表示方法を示す図である。
【図６】本発明の表示媒体の製造方法を示す工程図である。
【図７】従来の二色球の回転を利用した表示装置の表示原理を示す図である。
【図８】従来の水平移動型電気泳動型表示装置の表示原理を示す図である。
【符号の説明】
１ 絶緑性支持体
２ キャビティ
３ 帯電粒子
４ 微小球
５ 絶縁性液体
６ 導電層
９ 画素
１０ 電源
２１ 基板
２２ 表面保護層
３１ 第１電極
３２ 第２電極
６１ ワックス
６２ 被覆層
６３ 高分子支持材料
６４ 基板
６５ カバーフィルム
６６ 膨潤液
６７ 第１基板
６８ 第２基板
７１ 第１基板
７２ 第２基板
７３ 第１電極
７４ 第２電極
７５ 支持体
７６ キャビティ
７７ 高抵抗液体
７８ 二色ボール
７９ 駆動用電源
８１ 絶縁性液体
８２ 着色帯電粒子
８３ 第１基板
８４ 第２基板
８５ 第１電極
８６ 第２電極
８７ 隔壁
８８ 駆動用電源[0001]
BACKGROUND OF THE INVENTION
The present invention Display media About.
[0002]
[Prior art]
In recent years, with the development of information equipment, the amount of data of various types of information has been steadily expanding, and information output has been made in various forms. In general, the output of information can be roughly divided into display display using a cathode ray tube or liquid crystal, and hard copy display on paper by a printer or the like. In display display, the need for low power consumption and thin display devices is increasing, and liquid crystal display devices are being actively developed and commercialized as display devices that can meet such needs. However, the current liquid crystal display devices still have a sufficient resolution of the visual burden caused by the angle at which the screen is viewed and the reflected light, making it difficult to see the characters on the screen and the flickering and low brightness of the light source. Not. In contrast, a display using a cathode ray tube has sufficient contrast and brightness as compared with a liquid crystal display device, but cannot be said to have sufficient display quality compared to a hard copy display described later, such as flickering. Moreover, since the apparatus is large and heavy, portability is extremely low.
[0003]
On the other hand, hard copy display is thought to be unnecessary due to the digitization of information, but in reality, a huge amount of hard copy output is still being performed. The reason for this is that when information is displayed on the display, in addition to the above-mentioned problems related to display quality, the resolution is generally about 120 dpi at the maximum, compared to printing out on paper (usually 300 dpi or more). Considerably low. Therefore, the visual burden on the display is greater than that on the hard copy display. As a result, even if it can be confirmed on the display, hard copy output is often performed once. In addition, information that is hard-copied can be arranged in large numbers without limiting the display area to the size of the display, as in the case of a display, or can be rearranged without performing complicated device operations, and can be checked in order. What can be done is also a major reason why hard copy display is used in combination even if display can be displayed. Furthermore, the hard copy display does not require energy for holding the display and has excellent portability that information can be confirmed anytime and anywhere as long as the amount of information is not extremely large.
[0004]
As described above, unless moving image display or frequent rewriting is required, hard copy display has various advantages different from display display, but has a drawback of consuming a large amount of paper. Therefore, in recent years, development of a rewritable recording medium (a recording medium that can perform a high-visibility image recording / erasing cycle many times and does not require energy to maintain display) has been actively promoted. A rewritable third display method that inherits the characteristics of such hard copy is called a paper display.
[0005]
The requirements for the paper display are that it can be rewritten, that it does not require energy to hold the display, or that it is sufficiently small (memory property), that it has good portability, and that it has excellent display quality. . As a display method which can be regarded as a paper display at present, for example, an organic low molecular weight / high molecular resin matrix system for recording / erasing with a thermal printer head (for example, Japanese Patent Laid-Open Nos. 55-154198 and 57-82086). ) Using a reversible display medium. This system is partly used as a display part of a prepaid card, but has a problem that the contrast is not so high and the number of recording / erasing repetitions is relatively small, such as about 150 to 500 times.
[0006]
As a display device applicable to another paper display, N.I. K. Sheridon et al. Have proposed a display device using the rotation of a micro ball by electric field driving (“A Twisting Ball Display”, Proc. Of the SID, Vol. 18 3/4, 289-293, 1997, U.S. Pat. Nos. 4,126,854, 4,143,103, 5,389,945, and JP-A-64-42683).
[0007]
In this display device, as shown in FIG. 7, one hemispherical surface is white and the other hemispherical surface is black, and each hemispherical surface has a minute two color in which the mutual charged state (ζ potential) is different. The balls 78 are arranged in the cavities 76 formed in the support body 75, and high-resistance liquids 77 are filled in the cavities so that the two-color balls 78 can freely rotate in the high-resistance liquids 77. Is. When an external electric field is applied to the pair of electrodes 73 and 74 sandwiching the support 75, the two-color ball is electrostatically charged according to the charged state (ζ potential) of the black and white hemispherical portions of the two-color ball 78. The target display can be achieved by controlling the white or black hemisphere of the ball toward the viewing side.
[0008]
Such a mechanical display method is extremely stable with respect to temperature change and electrical disturbance noise, and does not require electric power during display because it has memory characteristics. Furthermore, the display is an ideal display device that can suppress eye fatigue caused by flickering of a light source such as that seen in a liquid crystal device or a cathode ray tube, in order to display using reflection / scattering of natural light on the ball surface.
[0009]
By the way, as a manufacturing method of a two-color ball used for a display device by ball rotation, the glass ball is made of TiO 2 by the aforementioned Sheridon et al. ₂ Has been proposed in which a glass ball is whitened and an insulating black layer is formed on the hemispherical surface of the white glass ball by vacuum deposition. Saito et al. Also formed a two-color ball by a similar method, and applied a vacuum deposition method to MgF on the hemispherical surface of a whitened glass ball. ₂ And Sb ₂ S _Three Are vapor-deposited and color-coded by forming a black layer ("A Newly Developed Electrical Twisting Display", Proc. Of the SID, Vol. 23, No. 4, pp. 249-253, 1982). When whitening a glass ball, LiO ₂ And TiO ₂ And SiO ₂ Using the glass composed of the three components, heat treatment is performed to separate components so that light scattering occurs, and a surface state composed of different components is formed. Furthermore, after contacting two solidifiable fluids colored in different colors by the aforementioned Sheridon etc., they are blown off as micro droplets using centrifugal force or jet flow, cooled and solidified to form a two-color ball. Mass production methods have been proposed (US Pat. Nos. 5,344,594 and 5,262,098, Japanese Patent Application Laid-Open Nos. 5-279486, 6-226875).
[0010]
As another display method usable as another paper display, an electrophoretic display device whose operation principle is shown in FIG. 8 can be cited. This display device includes a dispersion system in which colored charged particles 82 are dispersed in an insulating liquid 81 and a pair of electrodes 85 and 86 facing each other with the dispersion system interposed therebetween. By applying an electric field to the dispersion system through the electrodes, the colored charged particles are adsorbed by the Coulomb force on the side of the electrode having the opposite polarity to the charge of the particles themselves using the electrophoretic properties of the colored charged particles. is there. The display is performed using the difference between the color of the colored charged particles and the color of the dyed insulating liquid. In other words, when the colored charged particles are adsorbed on the surface of the light transmissive first electrode 85 close to the observer, the color of the colored charged particles is observed and conversely adsorbed on the surface of the second electrode 86 far from the observer. In such a case, the color of the stained insulating liquid is observed.
[0011]
Such an electrophoretic display method has a relatively fast response speed of several tens of ms or less and a rewrite frequency of 10 times. ⁸ More than once. In addition, the colored charged particles deposited on the electrodes by voltage application are stable over a long period of time even when the drive voltage is removed, so that no power is required during display. That is, it has a memory property. Furthermore, since it is a reflective display device. Eye fatigue caused by flickering of the light source can be suppressed.
[0012]
[Problems to be solved by the invention]
However, the display method described above has the following problems. First, in the method of rotating and displaying two-color balls, it is quite troublesome to produce microspheres that are colored in two colors and that have different charged states in the hemisphere corresponding to each color, and The materials that can be used are also limited. As a result, there is a problem that the cost of the display device is increased.
[0013]
On the other hand, the electrophoretic display device uses monochromatic charged particles, and thus has an advantage that it is easy to manufacture. However, in order to achieve sufficient contrast, the insulating liquid may be colored or opaque. It was essential. For this reason, it is difficult to compose the insulating liquid with a single component, and a coloring material such as a dye or ion must be mixed in the insulating liquid. The presence of such a colorant tends to act as an unstable factor in the electrophoretic operation in order to bring in a new charge, and has a drawback that the performance, life and stability as a display device are remarkably lowered. In addition, after the display, in order to prevent the charged particles from moving and diffusing in the surface direction due to pressure, impact, etc., it is necessary to hold the charged particles in a minute compartment isolated from the other, forming such a fine compartment. As a method, for example, a method using a porous spacer (JP-A-5-165064, JP-A-5-307197) or a striped or mesh-shaped partition member (JP-A-5-61075) is disclosed. However, there is a problem that the manufacturing process becomes complicated.
[0014]
The present invention has been made to solve the above-described problems, and has enabled improvement in contrast without deteriorating the life and stability. Display media The purpose is to provide.
[0015]
[Means for Solving the Problems]
That is, the first invention of the present invention has a color. One An insulating support including a plurality of cavities formed by holding microspheres, a plurality of charged particles having a diameter smaller than the microsphere and different colors, and an insulating liquid; and a conductive layer, The microsphere has a sphere diameter of 30 to 100 μm, the charged particles have a particle diameter of 5 μm or less, Between the microspheres in the cavity and the insulating support 5-10 μm There is a gap and the microsphere is held movably in the cavity. The charged particles are adsorbed in the gaps between the microspheres close to and far from the conductive layer and the insulating support, thereby displaying the color of the charged particles and the color of the microspheres. Do This is a display medium characterized by the above.
[0016]
The second invention of the present invention has a color. One An insulating support including a plurality of cavities formed by holding a microsphere and a plurality of charged particles having a diameter smaller than that of the microsphere and different colors and an insulating liquid, and a pair of electrodes each having one or a plurality of electrodes. Sandwiched between the electrodes, The microsphere has a sphere diameter of 30 to 100 μm, the charged particles have a particle diameter of 5 μm or less, Between the microspheres in the cavity and the insulating support 5-10 μm There is a gap, and the microsphere is held movably in the cavity. The charged particles are adsorbed in the gaps between the microspheres on one side and the other side of the pair of electrodes and the insulating support, so that the color of the charged particles and the color of the microspheres are changed. indicate This is a display medium characterized by the above.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail.
The first form of the display medium of the present invention is an insulating material including a plurality of cavities formed by holding a microsphere having a color, a plurality of charged particles having a diameter smaller than the microsphere and a different color, and an insulating liquid. It has a support and a conductive layer.
[0025]
FIG. 1 is a sectional view showing a typical first embodiment of the display medium of the present invention.
As shown in FIG. 1, the first form of the display medium of the present invention is a microsphere 4 having a color, and a plurality of charged particles 3 having a diameter smaller than that of the microsphere 4 and a color different from that of the microsphere 4. An insulating support 1 including a plurality of cavities 2 holding an insulating liquid 5 for dispersing the charged particles 3, and a conductive layer 6 formed on one surface of the insulating support 1. It is composed. Here, the insulating support 1 is transparent.
[0026]
FIG. 2 is a cross-sectional view showing a first embodiment of the display medium of the present invention having a configuration different from the above. The configuration of the first embodiment shown in FIG. 1 shows the minimum necessary configuration. As shown in FIG. 2, a surface protective layer 22 is formed as necessary, or a display medium is appropriately used. You may build on the board | substrate 21. FIG. 1 and 2, the cavity 2 is formed in one stage in the thickness direction in the insulating support 1, but the cavity 2 may be included in a plurality of stages or in a disorderly manner. Further, since the thickness of the insulating support 1 can be about 100 to 300 μm, if the substrate 21 and the conductive layer 6 are formed with appropriate materials and thicknesses, it is easy to form the whole in a flexible sheet shape. .
[0027]
In order to perform display using such a display medium, an electrostatic latent image is formed on the surface of the insulating support 1 opposite to the surface on which the conductive layer 6 is formed according to a desired pattern, and the electrostatic latent image is formed. The charged particles 3 are moved and electrostatically attracted to any surface side in the cavity using the electric field generated by the above. This display process will be described with reference to FIG.
[0028]
FIG. 4 is a diagram showing a display method in the first form of the display medium of the present invention. In the figure, first, it is assumed that the charged particles 3 are randomly present in the cavity 2 in the initial state (see FIG. 4A). The observer 8 observes from the side opposite to the surface on which the conductive layer 6 is formed on the insulating support 1 (this surface is called the observation surface 7). Assuming that the charged particles are black and negatively charged, a positively charged electrostatic latent image is formed on the observation surface 7 of the insulating support 1 using a charging roller (not shown) such as a charging roller or a corona ion generator. By forming an image, the charged particles 3 are electrophoresed in the cavity 2 and are moved and adsorbed to the side close to the electrostatic latent image forming surface, that is, the side close to the observer 8. Mainly black color is observed (see FIG. 4B). Next, when a negatively charged electrostatic latent image is formed on a part or the entire surface of the observation surface 7 in accordance with a desired pattern, the charged particles move only to the conductive layer 6 side far from the observer. The color of the microspheres 4 is mainly observed from the observer (see FIG. 4C). Therefore, for example, if the microsphere 4 is white, monochrome display is possible.
[0029]
In the above description, the entire surface is displayed black at first, but of course, the entire surface may be white first, and a part or the entire surface may be blackened according to a desired pattern later. In addition, the observer may observe from the side of the conductive layer 6 instead of observing from the side where the conductive layer 6 is not formed on the surface of the insulating support 1. However, in this case, the conductive layer 6 needs to be transparent. In either case, the electrostatic latent image must be formed on the surface opposite to the conductive layer. Further, before the step of forming an electrostatic latent image of reverse polarity on the surface of the insulating support 1 in accordance with the pattern in FIG. 4 (FIG. 4C), the entire surface may be once neutralized and then this may be performed.
[0030]
As shown in FIG. 3, the second form of the display medium of the present invention includes a microsphere 4 having a color, and a plurality of charged particles 3 having a diameter smaller than that of the microsphere 4 and a color different from that of the microsphere 4. The insulating support 1 including a plurality of cavities 2 holding an insulating liquid 5 for dispersing the charged particles 3 is sandwiched between a pair of electrodes 31 and 32. Of the insulating support 1 and the pair of electrodes, at least the one disposed on the viewer side is optically transparent. In addition, when it is desired to selectively display, it is necessary to pattern at least one of the electrodes into an appropriate shape.
[0031]
The configuration shown in FIG. 3 shows the minimum necessary configuration, and these may be constructed on an appropriate substrate, or the insulating support may be sandwiched between members having electrodes formed on the substrate. . Moreover, you may provide a surface preservation layer, a colored layer, a light reflection layer, etc. as needed. Further, in FIG. 3, the cavity 2 is formed in one stage in the thickness direction in the insulating support 1, but a plurality of cavities 2 may be included in a plurality of stages or randomly. Moreover, since the thickness of the insulating support 1 can be set to about 100 to 300 μm, if it is formed with an appropriate material and thickness, it is easy to form the whole in a flexible sheet shape.
[0032]
In order to perform display using such a display medium, a voltage for driving charged particles is applied between a pair of electrodes, and the charged particles 3 are moved or electrostatically moved to any surface side in the cavity using the electric field. Adsorb. This display process will be described with reference to FIG.
[0033]
FIG. 5 is a diagram showing a display method in the second mode of the display medium of the present invention. In the figure, first, it is assumed that the charged particles 3 are randomly present in the cavity 2 in the initial state (see FIG. 5A). The observer 8 is optically transparent and observes from the side of the first electrode 31 patterned into an appropriate shape for display. Now, assuming that the charged particles are black and negatively charged, by applying a voltage pulse with the first electrode 31 as an anode, the charged particles 3 are electrophoresed in the cavity 2 to the side of the first electrode. That is, since it is moved / adsorbed to the side closer to the observer, black color is mainly observed from the observer (see FIG. 5B). Next, when a voltage pulse is applied using a part or all of the first electrode 31 as a cathode in accordance with a desired pattern, the charged particles are moved and adsorbed to the second electrode 32 side far from the observer only in that region. The color of the microsphere 4 is mainly observed (see FIG. 5C). Therefore, for example, if the microsphere 4 is white, monochrome display is possible.
[0034]
In the above description, the entire surface is displayed black at first, but of course, the entire surface may be white first, and a part or the entire surface may be blackened according to a desired pattern later. Moreover, you may use the 2nd electrode 32 instead of the 1st electrode 31, or patterning both. Since the peak value, pulse shape, pulse width, etc. of the voltage pulse vary depending on the configuration of the display medium, an appropriate one is appropriately selected, but is not particularly limited. As an example, a rectangular wave having a peak value of 50 to 100 V and a pulse width of 100 ms.
[0035]
The electrical properties of the microspheres 4 used in the two display media described above are non-chargeable, that is, at least the surface is preferably semiconductive or conductive, but is charged. However, any of the following can be used.
[0036]
The first is that the microspheres are charged with the opposite polarity to the charged particles. In this case, since the charged particles are electrostatically adsorbed on the surface of the microsphere, the conditions for forming the electrostatic latent image or applying the drive voltage are strong enough to overcome the adsorption force of the charged particles to the microsphere. It is necessary to do it. The microsphere is moved and adsorbed on the side opposite to the electrostatic adsorption of the charged particles.
[0037]
The second case is when the microsphere is charged to the same polarity as the charged particle and the ζ potential of the microsphere is smaller than that of the charged particle. In this case, both the charged particles and the microspheres are moved and adsorbed to the same side by forming an electrostatic latent image or applying a drive voltage. However, since the ζ potentials of the two are different, the charged particles have a faster response speed. First, after the charged particles move, the microspheres move and are adsorbed. That is, the response speed t is according to the formula (1) (Fumio Kitahara, Masaru Watanabe: “Interfacial Electrical Phenomenon” Kyoritsu Shuppan (1972)).
[0038]
[Expression 1]

[0039]
In equation (1), ε is the dielectric constant of the insulating liquid, η is the viscosity of the insulating liquid, ζ is the ζ potential of the electrophore, d is the transverse distance, E is the electric field, and V is the applied voltage. From the equation (1), it can be seen that the response speed is determined by the ζ potential regardless of the particle size of the electrophoresis.
[0040]
Next, an example of a method for manufacturing a display medium of the present invention will be described.
FIG. 6 is a process diagram showing a method for manufacturing a display medium of the present invention. In the figure, first, a material that is insoluble in the material for forming the insulating support of the recording medium and soluble in the insulating liquid that fills the cavity, for example, wax 61 and the charged particles 3 are mixed. The coating material 62 to be formed is coated on the surface of the microsphere 4 having an appropriate color and having a diameter of about 5 to 100 μm (see FIG. 6A). The amount of the charged particles 3 mixed with the wax 61 is set to be an amount desired to be sealed in each cavity. Further, the color of the microsphere 4 may be either its own color or the surface of the microsphere 4 may be covered with an appropriate colored layer. Examples of the microsphere material include glass, zirconia, silicon nitride, silicon, and alumina. In order to prevent charging of the microsphere, a microsphere is formed using a material having appropriate conductivity, for example, silicon doped in n or p type, or an antistatic film is deposited on the surface of the microsphere. Also good. Of course, as described above, even if the microspheres have a charging property, there is a difference in the charged state with the charged particles, so long as they can be driven under appropriate conditions.
[0041]
The charged particles 3 must have a color different from that of the microspheres 4 and have a diameter smaller than that of the microspheres. For example, in the case of black, toner used in a copying machine or the like can be used.
[0042]
Next, the microspheres 4 coated with the coating layer 62 and a polymer support material 63 having a curing property for forming the insulating support 1, such as silicon rubber, are mixed, and a substrate 64 having a smooth surface, for example, The mixture is applied onto a glass substrate, and a mixture of the polymer material 63 and the coated microspheres is formed into a sheet by rolling using a suitable cover film 65, for example, a PET film (see FIG. 6B). Alternatively, it may be re-sheeted by a doctor blade method or a printing method. Alternatively, as disclosed in JP-A-58-122519, the coated microspheres are uniformly deposited in a single layer or multiple layers by dispersing and sedimenting the coated microspheres in an appropriate liquid. After the deposited film is formed on the substrate, a curable polymer support material that forms an insulating support that is soluble in the dispersion medium is injected, and the coated microspheres are encased and cast. Subsequently, the dispersion medium may be removed to produce a sheet made of coated microspheres and a curable polymer support material.
[0043]
Next, after the polymer supporting material 63 is cured, the sheet is peeled off from the glass substrate 64 and immersed in the swelling liquid 66 (see FIG. 6C). The swelling liquid 66 may be used as an insulating liquid contained in the display medium of the present invention, and examples thereof include silicon oil. By immersing in the swelling liquid, the cured polymer support material 63 swells, and at the same time, the wax 61 coated on the microspheres 4 dissolves, and a gap is formed between the microspheres 4 and the insulating support 1. A cavity 2 is formed. The cavity 2 is filled with a swelling liquid 66, and the swelling liquid 66 is transparent and has a viscosity suitable for causing electrophoresis of charged particles and a sufficiently high electric resistance. Can be used as the insulating liquid 5 as it is. If it cannot be used as an insulating liquid, it may be replaced with a suitable insulating liquid. Since the charged particles 3 are insoluble in the swelling liquid 66 and the insulating liquid 5, they are confined in the cavity 2.
[0044]
Through the above steps, the insulating support 1 including a plurality of cavities 2 formed by holding the charged particles 3, the microspheres 4 and the insulating liquid 5 forming the display medium of the present invention is formed (FIG. 6D). )reference).
[0045]
Subsequently, a conductive layer or an electrode is formed on the insulating support 1 including a plurality of cavities 2 that hold the charged particles 3, the microspheres 4, and the insulating liquid 5. The conductive layer or the electrode may be directly deposited on the insulating support 1 by a conventionally known thin film forming method. However, as shown in FIG. 6 (e), the conductive layer 6 is formed on another suitable substrate 21. You may produce by sticking together what was deposited. The cover film 65 on the surface of the insulating support 1 on the side opposite to the conductive layer 6 may be either peeled off or peeled off, but the insulating liquid 5 spills out of the insulating support 1 and spills out. In order to prevent this, it is preferable to provide some surface protective layer 22. The cover film 65 may be used as the surface protective layer 22 without peeling off. Further, in order to prevent the insulating liquid 5 from oozing out from the end surface of the insulating support 1, it is preferable to seal the end surface with an adhesive or the like.
[0046]
FIG. 6E shows the configuration of the display medium having the first configuration of the present invention. Instead of forming a conductive layer on the surface of the insulating support 1 after the step of FIG. If the insulating support layer 1 including a plurality of cavities 2 formed by holding the charged particles 3, the microspheres 4, and the insulating liquid 5 is sandwiched between a pair of electrodes after the cover film 65 is peeled off, A display medium having the second configuration (see FIG. 6F).
[0047]
In FIG. 6F, the insulating support 1 is sandwiched between the first substrate 67 having the first electrode 31 patterned into an appropriate shape and the second substrate 68 having the second electrode 32. Yes. The first substrate 67 and the first electrode disposed on the side close to the observer are required to be optically transparent, and the transparent electrode material includes, for example, indium tin oxide (ITO). In order to prevent the insulating liquid 5 from squeezing out from the end face of the insulating support 1, it is preferable to seal the end face with an adhesive or the like.
[0048]
In the display media having these first and second configurations, the materials of the substrates 21, 67, 68 are polymer films such as polyethylene terephthalate (PET) and polyethersulfone (PES), or inorganic materials such as glass and quartz. Can be used. If a polymer film is used, a display medium can also be formed in a flexible sheet form.
[0049]
【Example】
The present invention will be described below with reference to examples.
[0050]
Example 1
In this example, the display medium of the present invention was manufactured by the method shown in FIG.
A 50 μm zirconia ball was used as the microsphere 4. The zirconia balls were spray coated with a mixture of the charged particles 2 and the wax 61 to form a coating 62 having a thickness of about 10 μm. As the charged particles 2, a mixture of polystyrene and carbon having a particle size of about 1 μm to 2 μm was used (FIG. 6A).
[0051]
Next, the coated zirconia balls are dispersed in a two-pack type silicone rubber (manufactured by Dow Corning Co., Ltd., Sylpot 184), and this dispersion is thickened using a PET film 65 having a thickness of 100 μm on a glass substrate 64. After rolling into a film of about 100 μm, the silicone rubber was heat-cured at 100 ° C. for 1 hour (FIG. 6B).
[0052]
Next, the fine ball-dispersed cured rubber sheet is peeled off from the glass substrate 64 and immersed in a silicone oil (made by Toshiba Silicone) 66 having a viscosity of 1 cs for 24 hours to swell the rubber sheet (FIG. 6 (c)). The cavity (gap 5 to 10 μm) 2 was formed around the microsphere, and at the same time, the silicone oil 66 held in the cavity 2 was used as the insulating liquid 5 as it is (FIG. 6D).
[0053]
Next, the rubber sheet and the PES film 21 with an ITO electrode 6 (thickness: 100 μm) were bonded together to produce a display medium (FIG. 6E). The PET film 65 is used as the surface protective layer 22 as it is.
[0054]
Using such a flexible sheet-like display medium, ions generated by applying a positive or negative voltage of about 3 to 10 kV to a corona wire (a gold-plated tungsten wire having a diameter of 60 μm) from the surface of the PET film 22 are used. When an electrostatic latent image is formed by selectively charging the PET film 22, the charged particles 3 are moved and adsorbed to the surface protective layer 22 in the positively charged portion, and the conductive layer in the negatively charged portion. It was confirmed that the desired black and white display was performed by moving and adsorbing to the 6th side. At this time, the response speed was 30 ms or less, and the contrast ratio was about 5: 1. The viewing angle characteristic was ± 85 ° or more.
[0055]
Example 2
In the same manner as in Example 1, a rubber sheet including a plurality of cavities 2 formed by holding charged particles 3, microspheres 4, and an insulating liquid 5 made of silicone oil was formed on a PET film 65 (FIG. 6D). After that, the rubber sheet was peeled off from the PET film 65, and the rubber sheet was further sandwiched between PES substrates with ITO electrode films to produce a display medium (FIG. 6 (f)).
[0056]
When an electric field of ± 100 V was applied to the display medium, charged particles 3 or microspheres 4 appeared on the observation side according to the polarity of the electric field.
[0057]
Specifically, when an electric field was applied so that the first electrode 31 on the observation side became a cathode, the charged particles 3 moved and adsorbed on the observation side, and black was observed. When the electric field was reversed, the charged particles 3 moved and adsorbed toward the second electrode 32 on the opposite side, and as a result, the white color of the microspheres 4 was observed. At this time, the response speed was 30 ms or less, and the contrast ratio was about 5: 1. The viewing angle characteristic was ± 85 ° or more.
[0058]
【The invention's effect】
As described above, the display medium of the present invention can achieve two-color display. Since the microspheres used in this display medium are monochromatic, the microspheres that can be obtained at low cost can be used as they are. Also, when the surface is coated for the purpose of coloring, antistatic, etc., two colors are used. Since it is not necessary to coat them separately, they can be easily formed in the process.
Further, since the display is performed using the unique colors of the charged particles and the microspheres, colorization is easy.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a first embodiment of a display medium of the present invention.
FIG. 2 is a cross-sectional view of a first embodiment of the display medium of the present invention.
FIG. 3 is a cross-sectional view of a second embodiment of the display medium of the present invention.
FIG. 4 is a diagram showing a display method in the first embodiment of the display medium of the present invention.
FIG. 5 is a diagram showing a display method in a second form of the display medium of the present invention.
FIG. 6 is a process diagram showing a method for manufacturing a display medium of the present invention.
FIG. 7 is a diagram illustrating a display principle of a display device using rotation of a conventional dichroic sphere.
FIG. 8 is a diagram showing a display principle of a conventional horizontal movement type electrophoretic display device.
[Explanation of symbols]
1 Green support
2 cavity
3 charged particles
4 microspheres
5 Insulating liquid
6 Conductive layer
9 pixels
10 Power supply
21 Substrate
22 Surface protective layer
31 First electrode
32 Second electrode
61 wax
62 Coating layer
63 Polymer support material
64 substrates
65 cover film
66 Swelling liquid
67 First board
68 Second substrate
71 First substrate
72 Second substrate
73 First electrode
74 Second electrode
75 Support
76 cavities
77 High resistance liquid
78 Two-color ball
79 Power supply for driving
81 Insulating liquid
82 colored charged particles
83 First substrate
84 Second substrate
85 1st electrode
86 Second electrode
87 Bulkhead
88 Power supply for driving

Claims (6)

An insulating support including a plurality of cavities formed by holding a single microsphere having a color, a plurality of charged particles having a diameter smaller than that of the microsphere and different colors, and an insulating liquid; and a conductive layer. The spherical diameter of the microsphere is 30 to 100 μm, the particle diameter of the charged particle is 5 μm or less, and there is a gap of 5 to 10 μm between the microsphere in the cavity and the insulating support. The microspheres are held movably in the cavity, and the charged particles are adsorbed in a gap between the microspheres on the side close to and far from the conductive layer and the insulating support. A display medium displaying a color of charged particles and a color of the microsphere .   The display medium according to claim 1, wherein the display medium has a flexible sheet shape. The display medium according to claim 1 , wherein a surface of the microsphere is non-chargeable. The display medium according to claim 1 , wherein the microspheres are charged with a polarity opposite to that of the charged particles. The display medium according to claim 1 , wherein the microsphere is charged with the same polarity as the charged particle, and the ζ potential of the microsphere is smaller than that of the charged particle. Each electrode has an insulating support including a single microsphere having a color and a plurality of cavities formed by holding a plurality of charged particles having a diameter smaller than the microsphere and different colors and an insulating liquid. Alternatively, the microsphere is sandwiched between a plurality of electrodes, the spherical diameter of the microsphere is 30 to 100 μm, the particle size of the charged particle is 5 μm or less, and the microsphere in the cavity and the insulating support a gap of 5~10μm between the movable is held, the charged particles, insulating support with one side and the other side said microspheres of said pair of electrodes said microspheres in said cavity A display medium that displays the color of the charged particles and the color of the microspheres by being adsorbed in a gap between the body and the body .

Images