KR100459908B1 - Field emission display device - Google Patents

Abstract

The present invention provides a front transparent substrate and a rear substrate disposed to face each other at regular intervals, cathodes arranged in stripes on opposite surfaces of the rear transparent substrate, and an insulating layer applied on the cathodes and the rear transparent substrate. And micro-tips disposed on the cathode exposed by the holes formed on the insulating layer, anodes disposed on the stripe in the direction crossing the cathodes with openings corresponding to the holes, and on the anodes. In the field emission display device having the red, green, and blue phosphors coated, red, green, and blue phosphors corresponding to each pixel arranged in the cathode direction are the phosphors of any one of these phosphors. Arranged in position and arranged on the anode so that the phosphors of the remaining colors are divided into two and symmetrical on both sides with respect to the central phosphor. .

Description

Field emission display device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to field emission display devices, and more particularly, to field emission display devices having an improved arrangement of phosphors and anodes.

Field emission displays (FEDs) are flat panel display devices such as liquid crystal display panels (LCDs), plasma display panels (PDPs), fluorescent display devices (VFDs), and the like. In particular, low power consumption, wide viewing angles, temperature safety and Due to the features such as thin film, it is widely attracting attention as a next generation display device.

1 is a schematic cross-sectional view showing one pixel part of a general field emission display device. As shown, the field emission display device includes a cathode plate 1 having a cathode 12, an insulating layer 13, a gate 14, and a microtip 15 formed on a rear transparent flat plate 11; A positive electrode plate 2 having a positive electrode 22 and a phosphor 23 formed on the front transparent plate 21 is included.

In more detail, the cathodes 12 are formed in a stripe shape on the rear transparent plate 11 of the anode plate 1, and a plurality of microtips 15 are formed in an array form on the cathodes 12. . In particular, these microtips 15 are formed in the holes of the insulating layer 13 formed on the cathode 12. The gate 14 is formed on the insulating layer 13. On the other hand, the anodes 22 are formed in a stripe shape on the front transparent plate 21 of the anode plate 2 so as to intersect the cathode 12, and phosphors 23 for each color are coated on the anodes 22, respectively. It is. The negative electrode plate 1 and the positive electrode plate 2 are spaced at a predetermined distance by a spacer (not shown), and the circumference thereof is sealed to maintain the inside in a high vacuum state.

When the micro tip 15 array of the field emission display device as described above is grounded and a constant voltage is applied between the gate 14 and the anode 12, electrons are released into the vacuum. At this time, the electrons accelerated by the voltage of the anodes 5 collide with the phosphor 23 with a constant kinetic energy. At this time, the kinetic energy of the electrons is transferred to the phosphor 23, and the phosphor 23 is excited by receiving the kinetic energy of the electrons to emit light.

As a driving method for realizing a color image with such a field emission display device, a cathode switching method for switching a cathode to emit a phosphor having a desired color, and an anode for applying a voltage only to the phosphor so that emitted electrons collide with only a desired phosphor The switching method is used. Among these, the cathode switching method is a method of allocating a cathode by phosphor color and switching a voltage applied to the assigned cathodes. Therefore, the microtips 15 need to be distinguished for each color, which makes the fabrication process of the device complicated, and crosstalk is likely to occur since voltage is applied to all the anodes 22. For example, as shown in FIG. 2, some of the electrons emitted from the microtip array 200 assigned to the green phosphor 23G also collide with the adjacent phosphors 23R and 23B so that light of an unwanted color is emitted. Can be generated.

On the other hand, the anode switching method is to implement a color image by colliding the electrons emitted from the microtips only the phosphor to which the voltage is applied, for this purpose switching so that voltage is sequentially applied to the anodes coated with phosphors for each color do. In addition, anodes coated with phosphors of the same color allow voltage to be simultaneously applied. However, in the anode switching method, since an applied voltage is simultaneously applied to anodes coated with phosphors of the same color, some of the electrons that must collide with the phosphors at both ends of the phosphors forming one pixel are adjacent to each other. It collides with the same color phosphor of the pixel. For example, as shown in FIG. 3, when a voltage is applied to the electrode 221r coated with the red phosphor 231R to excite the red phosphor 231R of the first pixel A, the adjacent pixel B The voltage is also applied to the electrode 222r to which the red phosphor 232R of () is coated. Therefore, some of the electrons that must collide with the red phosphor 231R of the first pixel A, in particular, the red phosphor of the adjacent pixel B is greater than the distance from the red phosphor 231R of the first pixel A. A crosstalk phenomenon occurs in which electrons emitted from the microtips closer to the distance 232R collide with the red phosphor 232R of the adjacent pixel B. In addition, since voltages are simultaneously applied to electrodes coated with phosphors of the same color, insulation must be provided between the anodes crossing each other. To this end, as shown in FIG. 4, the resistor layer 40 must be inserted in a portion where the anodes cross each other.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a field emission display device in which the arrangement of the phosphor and the anode is changed so that generation of crosstalk between adjacent pixels is suppressed.

In order to achieve the above object, the present invention, the front transparent substrate and the rear transparent substrate disposed to face each other at a predetermined interval; Cathodes disposed in a stripe shape on opposite surfaces of the rear transparent substrate; An insulating layer applied on the cathodes and the rear transparent substrate; Microtips disposed on the cathode exposed by the holes formed on the insulating layer; Anodes having openings corresponding to the holes and disposed on a stripe in a direction crossing the cathodes; And red, green, and blue phosphors coated on the anodes, wherein red, green, and blue phosphors corresponding to each pixel arranged in the cathode direction are any one of the phosphors. The phosphor of color is arranged at the center position of the pixel, and the phosphors of the remaining colors are each divided into two and arranged on the anode so as to be symmetrical on both sides with respect to the center phosphor.

In the present invention, the length of the center phosphor in the cathode direction is preferably twice the length of each phosphor arranged in symmetry on both sides of the center phosphor. In addition, the anodes to which the red, green, and blue phosphors are respectively applied are preferably arranged so as not to intersect on the same plane.

Hereinafter, the field emission display device according to the present invention will be described with reference to the accompanying drawings.

5 is a schematic cross-sectional view showing two adjacent pixels of the field emission display device according to the present invention. As illustrated, the field emission display device according to the present invention includes a back transparent flat plate 51 having a cathode 52, an insulating layer 53, a gate 54, and a microtip 55, and an anode ( 621r, 621g, 621b, 622r, 622g, 622b) and a front transparent plate 61 on which red, green and blue phosphors 631R, 631G, 631B, 632R, 632G and 632B are formed. The blue phosphors 631R, 631G, 631B, 632R, 632G, 632B and the anodes 621r, 621g, 621b, 622r, 622g, and 622b are arranged in a symmetrical structure.

In more detail, for each pixel, any one of red, green, and blue phosphors, for example, green phosphors 631G and 632G, is arranged at the center of the pixel, and the phosphors of the remaining colors are divided into two, respectively. 631G) and 632G are arranged symmetrically on both sides. That is, two red phosphors 631R and 632R are arranged to be symmetrical with respect to the green phosphors 31G and 632G, and two blue phosphors 631B and 632B are arranged as green phosphors 631G and 632G. The red phosphors 631R and 632R are symmetrically arranged on both sides.

Such a field emission display device implements a color image by an anode switching method. That is, the electrons are emitted from the microtip 55, and the anodes 621r, 621g, 621b, 622r, 622g, and 622b corresponding to the phosphors 631R, 631G, 631B, 632R, 632G, and 632B for each color are removed. Color images are realized by switching and applying voltage sequentially. In this case, voltages are simultaneously applied to anodes corresponding to phosphors of the same color of each pixel.

On the other hand, since each phosphor is coated on the anode, the arrangement of the anode is also the same as that of the phosphor. This will be described in more detail with reference to FIG. 6.

As shown in FIG. 6, the green anode 621g corresponding to the green phosphor is positioned at the center, and the red anode 621r corresponding to the red phosphor is arranged along the circumference thereof. Then, two red anodes 621r are symmetric with each other on both sides of the green anode 621g. The blue anode 621b corresponding to the blue phosphor is also arranged along the circumference of the red anode 621r.

In the field emission display device having the anode array structure as described above, since the anode lines corresponding to the respective colors do not cross on the same plane, an insulator or an insulation circuit for insulating each anode line is unnecessary.

The operation of the field emission display device having such a phosphor and an anode array will be described in detail with reference to FIGS. 7A to 7C.

FIG. 7A is a cross-sectional view showing electron emission when the green anode 621g of the first pixel is switched to be in an on state in order to excite the green phosphor. As shown, when the power applied to the green anode 621g is turned on, electrons emitted from the microtip of the first pixel collide with the green phosphor 631G. At this time, the power applied to the green anode 622g of the adjacent pixel is also turned on at the same time, but because the distance from the microtip of the first pixel is far, some of the electrons emitted from this microtip are the green of the adjacent pixel. The crosstalk phenomenon which collides with the phosphor 632G hardly occurs.

On the other hand, after a predetermined switching time elapses after the green phosphor 631G of the first pixel is excited in this manner, a voltage is applied to the red anode 621g to excite the red phosphor 631G. The electron emission path in this case is shown in FIG. 7B. As shown, in this case, the intensity of the electric field formed between the microtips assigned to the first pixel and the red anode 621r is determined between the microtips assigned to the first pixel and the red anode 622r of the adjacent pixel. It is greater than the strength of the electric field formed in it. Thus, electrons emitted from the microtip are mostly accelerated toward the red phosphors 631R of the first pixel. In addition, since the red phosphor 631R and the red anode 621r are divided into two and symmetrically arranged, electrons emitted from the microtip positioned at the edge of the microtips assigned to the first pixel are also moved to the adjacent pixel. It is not accelerated.

FIG. 7C is a cross-sectional view illustrating an electron emission path when an applied voltage is turned on to the blue anode 621b so that the blue phosphor 631B is excited after the green and red phosphors are excited. Even in this case, the distance between the microtips at the edge and the blue anode 621b among the microtips of the first pixel is shorter than the distance between the microtips at the edge and the blue anode 622b of the adjacent pixel. . Therefore, a phenomenon in which electrons emitted from the microtips positioned at the edge collide with the blue phosphor 622B of the adjacent pixel is hardly generated.

As described above, according to the field emission display device according to the present invention, since phosphors and anodes of each color are arranged in a symmetrical structure for each pixel, crosstalk phenomenon in which electrons collide with the phosphors of adjacent pixels does not occur. In particular, since the anode lines for each color do not cross in the same plane, an insulator or an insulation circuit is not required between the anode lines.

1 is a schematic cross-sectional view of a conventional field emission display device;

2A is a schematic cross-sectional view for describing a cathode switching driving method of a conventional field emission display device;

2B is a schematic cross-sectional view illustrating a method of driving a positive electrode switching of a conventional field emission display device;

3A is a schematic cross-sectional view for explaining crosstalk generated in the method of FIG. 2A;

3B is a schematic cross-sectional view illustrating crosstalk generated in the method of FIG. 2B;

4 is a schematic plan view showing an anode pattern of a conventional field emission display device using a resistor layer;

5 is a schematic cross-sectional view of a field emission display device according to the present invention;

6 is a plan view showing the anode pattern of the field emission display device according to the present invention;

7A to 7C are schematic cross-sectional views illustrating electron emission paths of the field emission display device of FIG. 5 according to phosphors of respective colors.

Claims (2)

A front transparent substrate and a rear transparent substrate disposed to face each other at regular intervals; Cathodes disposed in a stripe shape on opposite surfaces of the rear transparent substrate; An insulating layer applied on the cathodes and the rear transparent substrate; Microtips disposed on the cathode exposed by the holes formed on the insulating layer; Anodes having openings corresponding to the holes and disposed on a stripe in a direction crossing the cathodes; And In the field emission display device having red, green, blue phosphors coated on the anodes, The red, green, and blue phosphors corresponding to the pixels arranged in the cathode direction are arranged in the center of the pixel, and the phosphors of any color are divided into two, respectively, and the phosphors of the remaining colors are divided into two. A field emission display device, characterized in that arranged on the anode so as to be symmetrical to both sides with respect to. The method of claim 1, And the anodes to which the red, green, and blue phosphors are respectively applied are arranged so as not to intersect on the same plane.