KR20130046370A - Electrowetting display - Google Patents

Abstract

PURPOSE: An electrowetting display is provided to constantly control the aggregation location of coloring oil at every pixel. CONSTITUTION: A first transparent electrode is formed on a first substrate(1). A water repellent insulation film is formed on the first transparent electrode. A second substrate is attached on the first substrate by intervening a cell gap. A second transparent electrode is formed to face with the water repellent insulation film on the second substrate. A barrier rib is formed in a grid on the water repellent insulation film to define a pixel region. The coloring oil and water are filled in the pixel region. The water repellent insulation film comprises a first water repellent insulation film(3) and a second water repellent insulation film(4). The pixel region is divided into a forming region of the first water repellent insulation film and a forming region of the second water repellent insulation film. [Reference numerals] (AA) Oil accumulated corner

Description

Electrowetting Display {ELECTROWETTING DISPLAY}

The present invention relates to an electrowetting display using an electrowetting phenomenon.

An electrowetting display includes a first transparent electrode formed on a first substrate, a water repellent (hydrophobic) insulating film formed on the transparent electrode, and a lattice-shaped partition wall formed on the insulating film. The pixel portion surrounded by the partition wall is filled with a coloring oil, and the coloring oil is filled with water and bonded to the second substrate on which the second transparent electrode is formed. When a voltage is applied between the first and second transparent electrodes, the contact angle with respect to water in the water-repellent insulating film is lowered, and the surface of the water-repellent insulating film is changed to hydrophilic, so that contact with water is advantageous. As a result, water pushes out the coloring oil, and the area ratio of the coloring oil and water in the pixel changes to produce the contrast of the pixel, thereby functioning as a display body.

Conventionally, when the electrowetting phenomenon is used as a display device, the place where the colored oils collect in the formed pixels needs to be the same place in each pixel, for example, the place where the colored oils are collected in four square pixels. One of the corners. In order to control the place where the colored oil is collected, a portion of the first transparent electrode under the water repellent insulating film may be cut out and the voltage applied during driving may be uneven to define the place where the colored oil may be collected, but it may not be fully controlled. There is.

There exists a structure which makes a part of insulating film thinner than the whole pixel by the control method different from the above (for example, refer patent document 1). However, since a step occurs in the pixel, the process is complicated and becomes a factor of cost up.

In addition, by forming the electrodes in two regions, there is a structure in which L-shaped electrodes are formed at two sides adjacent to a corner where the colored oil is to be collected and other electrodes are formed in other portions. However, since two drive elements must be formed in one pixel, the process is complicated and the yield of the product decreases, which causes cost up.

Patent Document 1: International Publication No. 03/071346 Patent Document 2: Japanese Patent Application Laid-Open No. 2010-203013

However, the above-described conventional electrowetting display has the following problems.

When a voltage is applied to the pixel, the position where the coloring oil collects in the pixel is a corner, but it cannot be controlled at which position (corner) the coloring oil is collected.

When the position where the colored oil moves is dispersed for each pixel, the display may appear unnatural to the human eye.

For this reason, it is necessary to control to always move to a specific position (corner) when coloring oil moves in a pixel.

An object of the present invention is to provide an electrowetting display capable of controlling the aggregation position of colored oil when a voltage is applied to a pixel.

An electrowetting display according to an embodiment of the present invention includes a first transparent electrode formed on a first substrate, a water repellent insulating film formed on the first transparent electrode, and a second substrate bonded to each other with the cell gap therebetween. And a second transparent electrode formed on the second substrate so as to face the water repellent insulating film, a barrier rib formed on the water repellent insulating film in a lattice shape to define a pixel region, and colored oil and water filled in the pixel region. In the electrowetting display, the water-repellent insulating film includes a first water-repellent insulating film and a second contact angle with respect to the water in the initial state of the applied voltage, but the characteristics of the contact angle varying with the applied voltage are different from each other. And a water repellent insulating film, wherein the pixel region is a region for forming the first water repellent insulating film, and a type of the second water repellent insulating film. Characterized in that the delimited region.

The second water repellent insulating film changes faster than the first water repellent insulating film due to the increase in the applied voltage.

Before the change of the contact angle of the first water repellent insulating film due to the increase in the applied voltage, the contact angle of the second water repellent insulating film so that a difference in contact angle between the first water repellent insulating film and the second water repellent insulating film occurs more than a certain angle. It changes or saturates.

The first water repellent insulating film is formed in a portion of the pixel area that is in contact with an oil collection corner where the colored oil is to be collected, and the second water repellent insulating film is in a portion that is in contact with two sides of the pixel area opposite to the oil collection corner. It is formed in an L shape.

An area of the first water repellent insulating film is set larger than an area of the second water repellent insulating film in the pixel area.

The contact angle change start voltage of the second water repellent insulating film is lower than the contact angle change start voltage of the first water repellent insulating film.

The voltage at which the contact angle of the second water repellent insulating layer is lowered and saturated is lower than the voltage at which the contact angle of the first water repellent insulating film is lowered and saturated.

The saturation contact angle of the second water repellent insulating film according to the increase of the applied voltage is lower than the saturation contact angle of the first water repellent insulating film.

The first water repellent insulating film is formed of an amorphous fluorine resin which is a transparent fluorine resin, and the second water repellent insulating film is formed of a mixture of the amorphous fluorine resin and a high dielectric constant insulating material (for example, BaTiO ₃ ).

According to the electrowetting display according to the present invention, a voltage is applied to a pixel by forming first and second water repellent insulating films having different characteristics in contact angle with water according to an increase in an applied voltage at different positions in each pixel region. At this time, the direction in which the coloring oil is to be collected, that is, the place where the coloring oil is collected can be controlled constantly for each pixel.

1 is a top view (a) and a cross-sectional view (b) illustrating an electrowetting display according to an embodiment of the present invention.
FIG. 2 is an operation characteristic diagram of a contact angle with respect to a voltage between the first water repellent insulating film and the second water repellent insulating film shown in FIG. 1.

The electrowetting display according to the present invention is an electrowetting display using a known electrowetting effect (electric capillary phenomenon), except for the structure of the water repellent insulating film.

For example, an electrowetting display according to the present invention includes a first substrate on which a first transparent electrode (a pixel electrode formed independently of each pixel), a driving element (TFT) for driving the first transparent electrode is formed, and a second And a second substrate having a transparent electrode (common electrode formed in common in all pixels), and colored oil and water filled in the cell gap between the first substrate and the second substrate. A water repellent insulating film is formed on the first transparent electrode, and a partition wall is formed on the water repellent insulating film to divide each pixel in a lattice shape. Coloring oil is located in the lower layer of each pixel enclosed by the partition, and water is located in the upper layer of the coloring oil.

In particular, the present invention uses the first and second water repellent insulating films as the water repellent insulating film. Although these two types of water-repellent insulating films have almost similar contact angles to water in a voltage-free state, the characteristics of the contact angles varying with the increase of the applied voltage are different.

Specifically, as the second water repellent insulating film, the contact angle of the first water repellent insulating film changes before the first water repellent insulating film according to the increase in the applied voltage applied between the first and second transparent electrodes, and the change of the contact angle of the first water repellent insulating film is initiated by the applied voltage. Before this, the contact angle is changed to have a contact angle difference greater than a specific angle with the first water repellent insulating film, or a water repellent insulating film whose contact angle change is saturated is used.

Then, a first water repellent insulating film is formed at a portion in contact with the corner where the colored oil is to be collected in each pixel, and a second water repellent insulating film is formed at an L-shape at a portion in contact with two sides opposite to the corner. The area of the first water repellent insulating film in each pixel is larger than the area of the second water repellent insulating film.

1 is a top view (a) and a cross-sectional view (b) illustrating an electrowetting display according to an embodiment of the present invention.

An ITO electrode 2, which is a first transparent electrode, is formed on the first substrate 1, and a first water repellent insulating film 3 is formed on a portion of the ITO electrode 2 that is in contact with an oil collection corner where the colored oil is to be collected. The L-shaped second water-repellent insulating film 4 is formed at the portion in contact with the two sides opposite to the oil collection corner. A lattice-shaped partition rib 5 is formed on the first water repellent insulating film 3 and the first water repellent insulating film 4.

For example, the first water repellent insulating film 3 is formed in a quadrangle at a portion including one oil collection corner among the quadrangular pixel regions surrounded by the rib rib 5, and is formed at the remaining portion including the remaining three corners. The water repellent insulating film 4 is formed in an L shape.

The first water-repellent insulating film 3 is formed of CYTOP (a non-crystalline fluorine resin obtained by cyclization polymerization of fluorine fluorine (4-vinyloxy-1-butene) (BVE), which is a transparent fluorine resin, trade name of Asahi Glass), The second water repellent insulating film 4 is formed of a mixture of a high dielectric constant film (for example, BaTiO ₃ ) and CYTOP.

As shown in FIG. 1, the 1st water-repellent insulating film 3 is formed in the part which contact | connects the corner which wants to collect colored oil, and the L-shaped 2nd water-repellent insulating film 4 is in the part which contact | connects two sides opposing the corner. To form. When a voltage is applied between the first and second transparent electrodes and the voltage is gradually raised, the contact angle of the second water repellent insulating film 4 falls earlier than the contact angle of the first water repellent insulating film 3. Thereby, directionality can be provided so that a coloring oil may move from the two sides by which the 2nd water repellent insulating film 4 was formed. When the applied voltage is further increased to reach a voltage at which the contact angle of the first water repellent insulating film 3 changes, the retraction of the coloring oil occurs from the two sides on which the second water repellent insulating film 4 is formed to be colored toward the desired oil collection corner. Oil collects.

2 shows a characteristic diagram of voltage vs. contact angle between the first water repellent insulating film 3 and the second water repellent insulating film 4.

As shown in FIG. 2, the characteristic A of the voltage vs. contact angle of the second water repellent insulating film 4 is compared with the characteristic B of the voltage vs. contact angle of the first water repellent insulating film 3 in accordance with the increase in the applied voltage. It can be seen that this change is relatively quick.

For example, when the applied voltage is 40 V, the characteristic (B) of the voltage versus contact angle of the first water repellent insulating film 3 is around 106 ° without changing the contact angle, but the voltage vs. contact angle of the second water repellent insulating film 4 is It can be seen that the contact angle of the characteristic (A) decreases to 92 °, and the difference between the contact angles of the first and second water repellent insulating films 3 and 4 is about 14 °. As a result, the contact angle of the second water-repellent insulating film 4 formed on the two sides opposite to the corner where the colored oil is to be collected is lowered first, so that the color oil moves from the two sides on which the second water-repellent insulating film 4 is formed. It can be given. When the applied voltage rises further and the contact angle of the first water repellent insulating film 3 reaches a voltage that changes, for example, 70 V, retraction of the coloring oil occurs from two sides on which the second water repellent insulating film 4 is formed. The coloring oil is collected toward the desired corner.

Therefore, according to the present invention, the first water-repellent insulating film 3 and the second water-repellent insulating film (3) having the same contact angle with respect to water in the state where no voltage is applied to the water repellent insulating film, but having different contact angle characteristics with the increase of the applied voltage. 4), the first water repellent insulating film 3 is formed at a portion in contact with the corner where the coloring oil is to be collected, and the second water repellent insulating film 4 is formed in an L shape at the portion in contact with the two sides opposite to the corner. By forming, it is possible to control the direction in which the coloring oil will collect when voltage is applied.

In addition, referring to FIG. 2, when the applied voltage reaches 10 V, the initial contact angle between 105 ° and 106 ° begins to change (decrease), and the contact angle continues to decrease with the increase in the applied voltage. When the applied voltage rises above 30V, it can be seen that the temperature drops to around 92 ° and is saturated. When the applied voltage exceeds 40 V, the first water-repellent insulating film 3 begins to change (decrease) in the vicinity of 106 °, and the contact angle continues to decrease as the applied voltage increases, and when the applied voltage rises above 70 V, the 98 It can be seen that the temperature is lowered to near and saturated. Further, it can be seen that the saturation contact angle (92 °) of the second water repellent insulating film 4 saturated by the increase in the applied voltage is also lower than the saturation contact angle (98 °) of the first water repellent insulating film 3. In addition, when the applied voltage is lower than 10V, that is, when the applied voltage is lower than the contact angle change start voltage of the second water repellent insulating film 4, the contact angles of the first and second water repellent insulating films 3 and 4 are 105 ° to ~. It can be seen that they are similar to each other within the range of 106 °.

1: substrate 2: ITO electrode
3: first water repellent insulating film 4: second water repellent insulating film
5: bulkhead rib

Claims (9)

A first transparent electrode formed on the first substrate,
A water repellent insulating film formed on the first transparent electrode;
A second substrate bonded to the first substrate with a cell gap interposed therebetween;
A second transparent electrode formed on the second substrate so as to face the water repellent insulating film;
Barrier ribs formed in a lattice shape on the water repellent insulating film to define pixel regions;
An electrowetting display comprising colored oil and water filled in the pixel region,
The water repellent insulating film,
A first water-repellent insulating film and a second water-repellent insulating film having a contact angle with respect to the water in the initial state of the applied voltage being similar to each other, but having different characteristics of the contact angle varying with the applied voltage;
And the pixel area is divided into a formation area of the first water repellent insulating film and a formation area of the second water repellent insulating film. The method according to claim 1,
The second water repellent insulating film,
The electrowetting display, which changes faster than the first water repellent insulating film due to the increase in the applied voltage. The method according to claim 1 or 2,
Before the change of the contact angle of the first water repellent insulating film due to the increase in the applied voltage, the contact angle of the second water repellent insulating film so that a difference in contact angle between the first water repellent insulating film and the second water repellent insulating film occurs more than a certain angle. Electrowetting display, characterized in that this change or saturation. The method according to claim 3,
The first water repellent insulating film is formed in a portion of the pixel area that is in contact with an oil collecting corner where the colored oil is to be collected.
And the second water repellent insulating film is formed in an L shape at a portion of the pixel area that is in contact with two sides of the oil collection corner. The method of claim 4,
And an area of the first water repellent insulating film in the pixel area is larger than an area of the second water repellent insulating film. The method according to claim 3,
The contact angle change start voltage of the second water repellent insulating film is lower than the contact angle change start voltage of the first water repellent insulating film. The method according to claim 3,
And a voltage at which the contact angle of the second water repellent insulating layer is lowered and saturated is lower than a voltage at which the contact angle of the second water repellent insulating film is lowered and saturated. The method according to claim 3,
And the saturation contact angle of the second water repellent insulating film is lower than the saturation contact angle of the first water repellent insulating film according to the increase of the applied voltage. The method according to claim 3,
An electrowetting display, wherein the first water repellent insulating film is formed of an amorphous fluorine resin which is a transparent fluorine resin, and the second water repellent insulating film is formed of a mixture of the amorphous fluorine resin and a high dielectric constant insulating material.

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