KR19990065301A - Plasma display panel - Google Patents

Abstract

The present invention relates to a plasma display panel. The plasma display panel according to the present invention does not apply the phosphors applied on the back substrate data electrodes in the boundary section of the unit cells in the vertical scanning direction, thereby preventing overlapping of light emitted from adjacent cells in the scanning direction.

Description

Plasma display panel

The present invention relates to a plasma display panel.

Voice, text, video, etc. are the means of conveying to others the thoughts of human beings. In the multimedia age, this is compounded, converted into electrical or optical physical quantities, recorded, and reproduced. At this time, visual information such as video is the mainstream of the information transmission means. As such, a display is used as an interface for transmitting visual information to a human. Such displays include a CRT, a liquid crystal display, and a plasma display. In particular, the liquid crystal display and the plasma display are frame-shaped flat plates, which are smaller in weight and volume than the CRT, making them easy to install and occupy a small area after installation. Can be. Plasma display during the display, when two electrodes are installed in an enclosed gas space and high voltage is applied, discharge occurs in the plasma state to emit visible light. Plasma display panels are classified into DC type and AC type according to the driving method. The DC type has a structure in which the electrode is directly exposed to the gas discharge space, and is driven by applying a DC pulse. The AC type has at least one electrode not exposed to the gas discharge space and is surrounded by a dielectric material so that the AC voltage is applied to the electrode. Apply and drive. In addition to coating a dielectric layer on the electrode, the AC type display solves the lifespan problem of plasma displays by applying a material having a high secondary electron emission coefficient as a protective film. As a result, the AC type plasma display has a brighter future than the DC type.

1 and 2 are respectively an exploded perspective view and a vertical sectional view of a conventional plasma display panel. As shown in the drawing, the conventional plasma display panel is formed with discharge spaces forming pixels between the rear substrate 1 and the front substrate 9 which are spaced apart from each other at regular intervals and face each other. These discharge spaces are formed by the partition wall 4 formed in stripe shape on the back substrate 1. On the back substrate 1 between these partition walls, stripe-shaped data electrodes 2 are formed in parallel with the partition walls, and dielectric layers 7 'are covered on these data electrodes 2. On the dielectric layer 7 ', fluorescent layers 3 for emitting light corresponding to the data electrodes 2 are formed to contact the partition walls. On the opposite surface of the front substrate 9, sustain discharge electrodes made up of two ITO electrode pairs 5 and 6 for sustain discharge are formed in a stripe shape in a direction crossing the data electrodes 2. These sustain discharge electrodes 5, 6 are covered by the dielectric layer 7, and the MgO protective film 8 having a high secondary electron emission coefficient is formed on the dielectric layer 7.

However, as shown in FIG. 2, when the plasma display panel is viewed in the longitudinal direction of the barrier rib 4, when a discharge occurs between each pair of discharge sustaining electrodes in the PDP discharge cell space, when one unit cell is discharged, No problem occurs, but when adjacent cells are simultaneously discharged in the vertical scanning direction, luminance overlaps between upper and lower adjacent cells. When discharge occurs in the unit cell, ultraviolet rays are emitted. The emitted ultraviolet rays excite the phosphor 3 positioned on the defecation substrate 1 to generate visible light. This visible light is emitted out through the first ITO electrode 5 and the second ITO electrode 6 of the front substrate 9, thereby realizing an image. At this time, ultraviolet rays are generated on the phosphor 3 and the ultraviolet rays are emitted not only in the vertical downward direction but also in the diagonal downward direction to excite the upper and lower adjacent cells to the corresponding fluorescent substance. Since some light is also emitted, a problem of deterioration of image sharpness occurs.

SUMMARY OF THE INVENTION The present invention has been made to improve the above problems, and an object thereof is to provide a plasma display panel in which a sharpness of an image is improved by forming a structure that blocks light emitted to cells other than a desired discharge cell as much as possible.

1 is a schematic exploded perspective view of a conventional plasma display panel;

2 is a vertical cross-sectional view of the plasma display panel of FIG.

3 is a vertical cross-sectional view of the plasma display panel according to the present invention.

Explanation of symbols for main parts of the drawings

1. Back substrate 2. Data electrode

3. phosphor 4. bulkhead

5. Discharge sustaining electrode (first ITO electrode) 6. Discharge sustaining electrode (second ITO electrode)

7,7 '. Dielectric layer 8. MgO protective film

9. Front Board

11.Back substrate 12. Data electrode

13. Phosphor 14. Bulkhead

15. Discharge sustaining electrode (first ITO electrode) 16. Discharge sustaining electrode (second ITO electrode)

17, 17 '. Dielectric layer 18. MgO protective film

19. Front substrate 20. Phosphor non-coating section

21. UV light 22. Visible light

22 '. Adjacent cell interference visible light

In order to achieve the above object, the plasma display panel according to the present invention includes a rear substrate and a front substrate spaced apart at regular intervals to face each other, and stripes in a direction crossing each other on opposite surfaces between the rear substrate and the front substrate. Each of the data electrodes and discharge sustain electrodes formed thereon, and unit cells having a discharge space corresponding to each pixel while maintaining the separation interval, are formed on the rear substrate and parallel to the data electrodes between the data electrodes. A dielectric layer formed to cover the discharge sustaining electrodes formed of a barrier rib formed in a stripe shape in a direction, phosphors coated on data electrodes between the barrier ribs, and a pair of ITO electrodes on the front substrate, respectively; In a plasma display panel having a protective film laminated on the The phosphors are formed so as to correspond to each pixel one-to-one by preventing the phosphors from being applied to a boundary section of the unit cells corresponding to the discharge region boundary in a direction perpendicular to the scanning direction displaying the unit cells. .

Hereinafter, a plasma display panel according to the present invention will be described in detail with reference to the accompanying drawings.

The present invention does not print a phosphor corresponding to a boundary area formed on a rear substrate and corresponding to a boundary area between a unit cell of a front substrate and a unit cell located above or below the vertical scanning direction, so that the unit cell and above or below the vertical scanning direction are not printed. It is characterized by preventing visible light from interfering between the unit cells (pixels) located.

3 is a vertical sectional view of the plasma display panel according to the present invention. As shown, the plasma display panel according to the present invention is basically provided with a rear substrate 11 and a front substrate 19 which are spaced apart from each other at regular intervals, and discharge spaces forming pixels between the opposing surfaces thereof. Are formed. These discharge spaces are formed by the partition wall 14 formed in a stripe shape on the rear substrate 11. The stripe data electrodes 12 are formed on the back substrate 11 between the partition walls 14 in a direction parallel to the partition walls 14, and the dielectric layer 17 ′ is formed on the data electrodes 12. Phosphors 13 for emitting light corresponding to the data electrodes 12 are coated on the dielectric layer 17 'so as to be in contact with the partition wall, and unit cells corresponding to adjacent pixels in the adjacent scanning vertical direction. The present invention is characterized in that the phosphors are not coated on the interface of the phosphors so that the phosphors are not coated so that the phosphors are separated by unit cells so that visible light is not generated at the interface of the unit cells. On the opposite surface of the front substrate 19, sustain discharge electrodes made up of two ITO electrode pairs 15 and 16 for sustain discharge are formed in a stripe shape in a direction crossing the data electrodes 12. The sustain discharge electrodes 15 and 16 are covered by the dielectric layer 17, and the MgO protective film 18 having a high secondary electron emission coefficient is formed on the dielectric layer 17.

The plasma display panel having the above structure operates as follows.

In FIG. 3, when a voltage is applied to the first ITO electrode 15 and the second ITO electrode 16 in the unit cell, sustain discharge occurs, the first ITO electrode 15 and the second ITO electrode 16. Ultraviolet rays are generated in the space between them. This ultraviolet light is radiated up and down and in all directions. In particular, ultraviolet rays radiated toward the rear substrate 11 reach the phosphor 13 coated on the rear substrate 11 and absorption occurs. The phosphor 13 absorbing the ultraviolet rays 21 converts it into visible light 22 and emits the light toward the front substrate 11 again. The emitted visible light 22 is radiated outward through the first ITO electrode 15 and the second ITO electrode 16 or between the first ITO electrode 15 and the second ITO electrode 16. do. However, since the non-coated section 20 of the phosphor exists on the boundary surface of the unit cell corresponding to each pixel, the first ITO electrode 15 of the upper unit cell in the scanning direction adjacent to the second ITO electrode 16 is present. ), There is no visible light 22 which does not reach, and thus no visible light is emitted to the outside. Similarly, the second ITO electrode 16 of the lower unit cell in the scanning direction adjacent to the first ITO electrode 15 is similar. There is no visible light emitted outside because visible light 22 does not reach. As a result, the fluorescent material is not applied to the boundary between adjacent cells in the discharge space, so that luminance overlap does not occur.

As described above, the plasma display panel according to the present invention does not apply the phosphors applied on the back substrate data electrodes in the boundary section of the unit cells in the vertical scanning direction, thereby overlapping light emitted from adjacent cells in the scanning direction. This is prevented and the sharpness of the image is improved.

Claims (1)

The back and front substrates spaced apart from each other at regular intervals, and the data electrodes and the discharge sustain electrodes respectively formed on strips in a direction crossing each other on opposite surfaces between the back and front substrates, While maintaining unit cells having discharge spaces corresponding to each pixel, the barrier ribs are formed on the rear substrate in a stripe shape parallel to the data electrodes between the data electrodes and on the data electrodes between the barrier ribs. A plasma display panel comprising phosphors coated on the substrate, a dielectric layer formed to cover the discharge sustaining electrodes, each of the pair of ITO electrodes on the front substrate, and a protective film stacked on the dielectric layer. Characterized in that the phosphors are formed to correspond to each pixel in a one-to-one manner so that the phosphors are not coated on the boundary section of the unit cells corresponding to the discharge region boundary in a direction perpendicular to the scanning direction displaying the unit cells. Display panel.