Manufacturing method of plasma display panel that includes adielectric glass layer having small particle sizes

Description

This application is based on an application Nos. 10-127989, 10-153323, 10-157295, 10-252548, and 11-5016 filed in Japan, the contents of which are hereby incorporated by reference.

BACKGROUND OF THE INVENTION

(1) Field of the Invention

The present invention relates to a plasma display panel used for a display device, and especially relates to a plasma display panel including an improved dielectric glass layer.

(2) Description of the Prior Art

Recently, expectations for a high-definition TV and a large-screen TV have been raised. For such a TV, a CRT display, a liquid crystal display, or a plasma display panel has been conventionally used as a display device. A CRT display is superior to a plasma display panel and a liquid crystal display in resolution and image quality. A CRT display, however, is not suitable for a large screen that measures more than 40 inches because the depth. dimension and the weight are too large. A liquid crystal display is superior in consuming a relatively low power and requiring a relatively low voltage. A liquid crystal display, however, has disadvantages of a limited screen size and viewing angle. On the other hand, a plasma display panel realizes a large screen. Screens that measure in the 40 inches have been developed using plasma display panels (described in “Kino Zairyo (Functional Materials)” (Vol. 16, No. 2, February issue, 1996, p7), for instance).

FIG. 13

is a perspective view of the essential part of a conventional ac plasma display panel. In

FIG. 13

, a reference number

131

refers to a front glass substrate made of borosilicate sodium glass. On the surface of the front glass substrate, display electrodes

132

are formed. The display electrodes

132

are covered by a dielectric glass layer

133

. The surface of the dielectric glass layer

133

is covered by a magnesium oxide (MgO) dielectric protective layer

134

. The dielectric glass layer is formed using a glass powder the particle diameter of which ranges from 2 to 15 μm on average.

A reference number

135

refers to a back glass substrate. On the surface of the back glass substrate

135

, address electrodes

136

are formed. The address electrodes

135

are covered by a dielectric glass layer

137

. On the surface of the dielectric glass layer

137

, walls

138

and phosphor layers

139

are formed. Between the walls

138

, discharge spaces

140

are formed. The discharge spaces

140

are filled with discharge gas.

A full-specification, high-definition TV is expected to realize the pixel level given below. The number of pixels is 1920×1125. The dot pitch is 0.15 mm ×0.48 mm for a screen that measures around 42 inches. The area of one cell is as small as 0.072 mm

2

. The area is {fraction (1/7+L )} to {fraction (1/8+L )} compared with a 42-inch, high-definition TV according to a conventional NTSC (National Television System Committee) (the number of pixels is 640×480, the dot pitch is 0.43 mm×1.29 mm, and the area of one cell is 0.55 mm

2

).

As a result, the intensity of the panel decreases for the full-specification, high-definition TV (described in “Disupurei Ando Imeijingu (Display and Imaging)” Vol. 6, 1992, p70, for example).

In addition, not only the distance between the discharge electrodes is shorter, but also the discharge space is smaller for the full-specification, high-definition TV. As a result, when the plasma display panel gains the same capacity as a capacitor, it is necessary to set the thickness of the dielectric glass layers

133

and

137

to be smaller than in a conventional one.

Here, the explanation of three methods of forming a dielectric glass layer will be given below.

In the first method, a glass paste is made of a glass powder the particle diameter and the softening point of which ranges from 2 to 15 μm on average and from 550 to 600° C., and a solvent such as terpineol including ethyl cellulose and butyl carbitol acetate using a trifurcated roll. The glass paste is printed on the front glass substrate according to a screen printing method (the glass paste is adjusted so that the viscosity is 50,000 to 100,000 cp, which is suitable for the screen printing method). The printed glass paste is dried, and undergoes sintering at a temperature around the softening point of the glass powder (550 to 600° C.), forming a dielectric glass layer.

In the first method, the melted glass rarely reacts to the electrode made of Ag, ITO, Cr-Cu-Cr, or the like since the glass paste undergoes sintering at a temperature around the glass powder softening point and the glass is inert, i.e., the glass does not flow well. As a result, the resistance of the electrode does not increase, the electrode ingredients do not dispersed in or not color the glass, and a dielectric glass layer is formed with one firing. On the other hand, the glass paste does not flow well since the particle diameter of the glass powder ranges from 2 to 15 μm on average and the glass paste is fired at a temperature around the softening point of the glass powder, and the mesh pattern of the screen remains in this method. As a result, the surface of the formed dielectric glass layer is rough (the surface roughness is 4 to 6 μm), and visible light is scattered on the coarse surface. In other words, the dielectric glass layer is a ground glass and the transmittance is relatively low. In addition, bubbles and pinholes appear in the formed dielectric glass layer, so that the voltage endurance of the dielectric glass layer is decreased. Here, the voltage endurance means the limitation of the insulation effect of a dielectric glass layer when a voltage is applied to the dielectric glass layer.

In the second method, a glass paste (the viscosity is 35,000 to 50,000 cp (centipoise)) is made using a low-melting lead glass powder (the proportion of PbO is about 75%) the particle diameter and the softening point of which ranges from 2 to 15 μm on average and from 450 to 500° C. The glass paste is printed on the front glass substrate according to a screen printing method and dried. The dried glass paste undergoes sintering at a temperature about 100° C. higher than the softening point of the glass powder, i.e., at 550 to 600° C., forming a dielectric glass layer. In the second method, the surface of the formed dielectric glass layer is smooth (surface roughness is about 2 μm) since the sintering temperature is considerably higher than the softening point and the glass paste flows well. In addition, a dielectric glass layer is formed with one sintering.

On the other hand, the melted glass reacts to the electrode made of Ag, ITO, Cr-Cu-Cr, or the like since the glass paste is activated and flows well. As a result, the resistance of the electrode increases and the dielectric glass layer is colored. In addition, large bubbles are likely to appear in the dielectric glass layer as a result of the reaction to the electrode.

The third method is the combination of the first and second methods (refers to Japanese Laid-Open Patent Application Nos. 7-105855 and 9-50769). In the third method, a glass paste is made of a glass powder the particle diameter and the softening point of which ranges from 2 to 15 μm on average and from 550 to 600° C. The glass paste is printed on the front glass substrate according to the screen printing method. The printed glass paste is dried, and undergoes sintering at a temperature around the softening point, forming a dielectric glass layer. On the formed dielectric glass layer, another dielectric glass layer is further formed. A glass paste is made of a glass powder the particle diameter and the softening point of which ranges from 2 to 15 μm on average and from 450 to 500° C. The second glass paste is printed on the previously formed dielectric glass layer according to the screen printing method. The printed second glass paste is dried, and undergoes sintering at a temperature about 100° C. higher than the softening point, i.e., at 550 to 600° C., forming the second dielectric glass layer.

Due to the bilevel structure, the melted glass rarely reacts to the electrode and the surface of the dielectric glass layer is smooth, resulting in an improved transmittance of visible light and endurance to voltage. At the same time, however, the method of forming the dielectric glass layer is complicated and a thinner dielectric glass layer, which is necessary to improve the intensity, is difficult to form. In addition, the visible light transmittance is not improved so much since bubbles appear in the first formed dielectric glass layer.

SUMMARY OF THE INVENTION

It is accordingly an object of the present invention to provide a reliable, high-intensity plasma display panel in which the visible light transmittance is high even when the plasma display has a fine cell structure since the problems of low visible light transmittance and low voltage endurance are solved. The above-mentioned object may be achieved by the manufacturing method of plasma display given below.

In the manufacturing method of plasma display, a glass paste including a glass powder the average particle of which is 0.1 to 1.5 μm and the maximum particle diameter of which is equal to or smaller than three times the average particle diameter is printed on the front glass substrate or the back glass substrate on which electrodes have been formed according to a screen printing method, a die coating method, a spray coating method, a spin coating method, and a blade coating method. Then, the glass powder in the printed glass paste undergoes sintering, forming a dielectric protective layer.

The object of the present invention may be realized since a dielectric glass layer having a relatively smooth surface and including a minimum amount of bubbles is formed using the glass powder that has been described.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other objects, advantages and features of the invention will become apparent from the following description thereof taken in conjunction with the accompanying drawings which illustrate a specific embodiment of the invention. In the Drawings:

FIG. 1

is a perspective view of the main structure of an ac discharge plasma display panel;

FIG. 2

is a vertical sectional view taken on line X—X of

FIG. 1

;

FIG. 3

is a vertical sectional view taken on line Y—Y of

FIG. 1

;

FIGS. 4A

to

4

E show the process of forming a discharge electrode according to a photolithographic method;

FIGS. 4A

to

4

D show the process of forming an ITO transparent electrode;

FIG. 4E

shows the process of forming a bus line;

FIG. 5

is a schematic diagram of a CVD (Chemical Vapor Deposition) device used in forming a protective layer;

FIG. 6

is a schematic diagram of an ink coating device used in forming a phosphor layer;

FIG. 7

is a schematic diagram of a die coater used in forming a dielectric glass layer;

FIG. 8

is a schematic diagram of a spray coater used in forming a dielectric glass layer;

FIG. 9

is a schematic diagram of a spin coater used in forming a dielectric glass layer;

FIG. 10

is a schematic diagram of a blade coater used in forming a dielectric glass layer;

FIG. 11

is a table showing the relations between the melting speeds and the average particle diameters of glass materials;

FIG. 12

shows the relations between thickness and voltage endurance of dielectric glass layer; and

FIG. 13

is a perspective view of the essential part of a conventional ac plasma display panel.

DESCRIPTION OF THE PREFERRED EMBODIMENT

First of all, the explanation of the structure of a plasma display panel (referred to as a “PDP” in this specification) according to the preferred embodiment of the present invention will be given with reference to figures.

FIG. 1

is a perspective view of the essential part of an ac discharge PDP according to the present embodiment.

FIG. 2

is a vertical sectional view taken on line X—X of FIG.

1

.

FIG. 3

is a vertical sectional view taken on line Y—Y of FIG.

1

. Although the number of cells is three in

FIGS. 1

to

3

for convenience in explanation, a large number of cells each of which emits light of red (R), green (G), or blue (B) are arranged on the PDP.

FIGS. 1

to

3

shows the structure of the PDP. A front panel

10

is stuck to a back panel

20

. The front panel

10

is formed by placing discharge electrodes (display electrodes)

12

, a dielectric glass layer

13

, and a protective layer

14

on a front glass substrate

11

. The back panel

20

is formed by placing address electrodes

22

, a dielectric glass layer

23

, walls

24

, and phosphor layers

25

, each of which has a different color “R (red)”, “G (Green)”, and “B (blue)”, on a back glass substrate

21

. In discharge spaces

30

between the front panel

10

and the back panel

20

, discharge gas is filled. In the discharge electrode, a metal electrode made of Ag, or Cr-Cu-Cr is placed as a bus line on a transparent electrode made of ITO or SnO

2

(not illustrated).

Here, suppose that the area of the plane facing the discharge electrode is “S”, the thickness of the dielectric glass layers

13

and

23

is “d”, the permittivity of the dielectric glass layers

13

and

23

is “ε”, and the amount of the electric charge on the dielectric glass layers

13

and

23

is “Q”, capacitance “C” between the discharge electrode

12

and the address electrode

22

is represented by an Equation (1) given below.

C=εS/d

Equation (1)

Suppose that the voltage applied between the discharge electrodes

12

and the address electrode

22

is “V”, the relation between the voltage “V” and the electric charge amount “Q” is represented by an Equation (2) below.

V=dQ/εS

Equation (2)

Note that the discharge spaces are in plasma condition at the time of discharge, so that the discharge spaces are conductive elements. In the Equations (1) and (2), when the dielectric glass layer thickness “d” is decreased, the capacitance “C” as a capacitor is increased and the discharge voltage at the time of addressing and display is decreased.

More specifically, even when the same level of the voltage “V” is applied, a larger amount of the electric charge “Q” is built up by decreasing the thickness of the dielectric glass layers

13

and

23

, so that the capacitance may be increased and the discharge voltage may be decreased.

When only the thickness of the dielectric glass layers

13

and

23

is decreased, however, the voltage endurance is decreased. As a result, when an address pulse and a display pulse are applied, the dielectric glass layers are easy to break.

In the present invention, the approach to the improvement of the voltage endurance and the visible light transmittance is the determination of the average and maximum particle diameter of the glass powder in the dielectric glass layers

13

and

23

.

The specific explanation of the manufacturing method of the PDP that has been described will be given below.

First, the explanation of how the front panel

10

is formed is given below.

On the surface of the front glass substrate

11

, the discharge electrodes are formed in parallel according to the photolithographic method, which is well known in the art. Then, the dielectric glass layer is formed using a glass material to cover the discharge electrodes

12

, which will be explained later in detail. On the surface of the dielectric glass layer

13

, the protective layer

14

made of magnesium oxide (MgO) is formed.

The photolithographic method, in which the discharge electrode

12

is formed, will be briefly explained below.

FIGS. 4A

to

4

E show the process of forming the discharge electrode

12

according to the photolithographic method. First, a predetermined thickness (for instance, 0.12 μm) of ITO layer

41

, is formed by sputtering on the front glass substrate

11

as shown in FIG.

4

A. Then, a photoregister layer

42

is formed as shown in FIG.

4

B. As shown in

FIG. 4C

, light beams

44

are applied using masks

43

, and a predetermined width (for instance, 150 μm) of ITO electrodes

45

are formed in parallel after development (the interval between the ITO electrodes

45

is, for instance, 50 μm) as shown in FIG.

4

D. After that, a light-sensitive silver paste is applied across the surface as shown in

FIG. 4E

, and a predetermined width (for instance, 30 μm) of Ag bus lines

46

(metal electrodes) are formed on the ITO electrodes

45

(transparent electrodes) according to the photolithographic method. After a firing at a predetermined temperature, the discharge electrodes

12

are formed. When three-tier metal layers made of Cr-Cu-Cr are used as the bus lines (metal electrodes), the metal electrodes are formed in the manner given below. Each of the metal layers is vaporized in the sputtering on the transparent electrodes that have been formed by patterning as has been described. Resists are applied on the surface of the vaporized layers, and metal electrodes are formed by patterning according to the photolithographic method.

The explanation of how the protective layer

14

is formed by a CVD (Chemical Vapor Deposition) will be given below with reference to FIG.

5

.

FIG. 5

is a schematic diagram of a CVD device

50

used in forming a protective layer

14

.

The CVD device

50

performs a heat CVD and a plasma CVD. In a CVD device body

55

, a heater

56

for heating a glass substrate

57

(the front glass substrate

11

on which the discharge electrode and the dielectric glass layer

13

are formed in

FIG. 1

) is included. The pressure in the CVD device body

55

is reduced by an exhaust device

59

. A high-frequency power supply

58

for generating plasma in the CVD device body

55

is included in the CVD device

50

.

Ar gas cylinders

51

a

and

51

b

provide the CVD device body

55

with argon [Ar] gas that is a carrier via vaporizers (bubblers)

52

and

53

.

In each of the vaporizers

52

and

53

, a magnesium compound is stored for forming the protective layer

14

. More specifically, a metal chelate such as acetylacetone magnesium [Mg(C

5

H

7

O

2

)

2

], a cyclopentadienyl compound such as cyclopentadienyl magnesium [Mg(C

5

H

5

)

2

], and an alkoxide compound is stored in the vaporizers

52

and

53

.

An oxygen cylinder

54

provides the CVD device body

55

with oxygen [O

2

] that is a reactant gas.

When the protective layer

14

is formed in the heat CVD, the glass substrate

57

is placed on the heater

56

with the side on which the electrodes have been formed up, and is heated at a predetermined temperature (about 30° C.). Meanwhile, the pressure in the CVD device body

55

is reduced (to about a several tens of Torr) by the exhaust device

59

.

In the vaporizers

52

and

53

, Ar gas is put from the Ar gas cylinder

51

a

and

51

b

while a source is heated to a predetermined vaporization temperature. Meanwhile, oxygen is provided by the oxygen cylinder

54

into the CVD device body

55

.

The metal chelate, the cyclopentadienyl compound, or the alkoxide compound put into the CVD device body

55

is reacted to the oxygen that is also put into the CVD device body

55

. As a result, on the surface of the glass substrate

57

, on which electrodes have been formed, the protective layer

14

is formed.

In the plasma CVD, the protective layer

14

is formed in almost the same procedure using the CVD device. The plasma CVD differs from the heat CVD

58

in the points that the high-frequency power is driven and a high-frequency electric field (13.56 MHz) is applied. In the plasma CVD, the protective layer

14

is formed while plasma is caused in the CVD device body

55

.

The back panel

20

is formed in the manner given below.

First, the address electrodes

22

are formed on the surface of the back glass substrate

21

according to the photolithographic method. Note that the address electrodes

22

are made of metal electrodes.

Then, the dielectric glass layer

23

is formed in the same manner as the front panel

10

so that the dielectric glass layer

23

covers the address electrodes

22

. The forming of the dielectric glass layer

23

will be explained later in detail.

On the dielectric glass layer

23

, walls

24

made of glass are placed at a predetermined interval.

In each of the spaces between the walls

24

, differently colored phosphors of a red (“R”) phosphor, a green (“G”) phosphor, and a blue (“B”) phosphor are arranged to form phosphor layers

25

. Although the phosphor that is generally used for a PDP may be used, another kind of phosphor is used for the “R”, “G”, and “B” phosphors.

Red phosphor:

(Y

x

Gd

1−x

) BO

3

:EU

3+

Green phosphor:

Zn

2

SiO

4

:Mn

Blue phosphor:

BaMgAl

10

O

17

:Eu

2+

or

BaMgAl

14

O

23

:Eu

2+

An example of the method of forming the phosphors that are placed between the walls

24

will be given below with reference to FIG.

6

.

FIG. 6

is a schematic diagram of an ink coating device

60

used in forming a phosphor layer. First, a phosphor mixture of a red phosphor Y

2

O

3

: Eu

3+

powder, ethyl cellulose, and a solvent (α-terpineol) (the mixture ratio is 50 wt. %:1.0 wt. %:49 wt. %) having a predetermined particle diameter (for instance, the average particle diameter is 2.0 μm) is stirred using a sand mill in the server

61

. Then, coating liquid having a predetermined viscosity (for instance, 15 cp) is added, and red-phosphor-forming liquid

64

is injected from the nozzle unit

63

(the diameter is 60 μm) of an injector at the pressure of a pump

62

into an interval between walls

24

, which has forms of stripes. At that time, the substrate is moved straightly to form a red phosphor line

25

. In the same manner a blue phosphor line (BaMgAl

10

O

17

: Eu

2+

) and a green phosphor line (Zn

2

SiO

4

: Mn) are formed. Then, the red, blue, and green phosphor lines are fired at a predetermined temperature (for instance, at 500° C.) for a predetermined period of time (for instance, for 10 minutes) to form the phosphor layers

25

.

The explanation of how forming the PDP by sticking the front panel

10

to the back panel

20

will be given below.

The front panel

10

is stuck to the back panel

20

using an attaching glass, the inside of the discharge spaces

30

divided by the walls

24

are exhausted to a high degree of vacuum (8×10

−7

Torr). After that a predetermined composition of discharge gas is filled at a predetermined pressure to form a PDP.

Note that the cell size of the PDP in the present embodiment is set so that the cell size is suitable for a high-definition TV whose screen measures in the 40 inches. More specifically, the interval of the walls

24

is set to be equal to or smaller than 0.2 mm and the distance between the discharge electrodes

12

is set to be equal to or smaller than 0.1 mm.

Meanwhile, the discharge gas filled into the discharge spaces

30

is a He-Xe or a Ne-Xe gas that has been used. The composition, however, is set so that the content of Xe is equal to or more than 5 vol % and the infusion pressure is 500 to 760 Torr.

The explanation of how forming the dielectric glass layer

13

will be given below.

The dielectric glass layer

13

is formed on the surface of the front glass substrate

11

on which the discharge electrodes

12

have been formed according to the screen printing method, the die coating method, the spin coating method, the spray coating method, or the blade coating method using a glass powder the average particle diameter of which is 0.1 to 1.5 μm and the maximum particle diameter of which is equal to or smaller than three times the average particle diameter.

By using such a glass powder, a dielectric glass layer that is a solid sintered metal oxide that include a relatively small number of bubbles and has a relatively smooth surface may be obtained. Note that the particle diameters are measured using a Coulter counter grading analyzer (a particle size measuring instrument of Coulter K.K.), by which the number of particles are counted for each particle diameter (the Coulter Counter is also used in the examples given below).

The particle diameters are adjusted by crushing the glass raw material so that a predetermined particle diameter would be obtained using a crusher such as a ball mill and a jet mill (for instance, HJP300-02 of Sugino Machine Limited). When using the glass including the components G

1

, G

2

, G

3

, . . . , GN, as the glass raw material, the components G

1

, G

2

, G

3

, . . . , GN are weighed according to the component ratio, melted in a furnace at 1300° C., and put into water. The glass material is a PbO-B

2

O

3

-SiO

2

-CaO glass, a PbO-B

2

O

3

-SiO

2

-MgO glass, a PbO-B

2

O

3

-SiO

2

-BaO glass, a PbO—B

2

O

3

—SiO

2

—MgO—Al

2

O

3

glass, a PbO—B

2

O

3

—SiO

2

—BaO—Al

2

O

3

glass, a PbO—B

2

O

3

—SiO

2

—CaO—Al

2

O

3

glass, a PbO—B

2

O

3

—ZnO—B

2

O

3

—SiO

2

—CaO glass, a ZnO—B

2

O

3

—SiO

2

—Al

2

O

3

—CaO glass, a P

2

O

5

—ZnO—Al

2

O

3

—CaO glass, an Nb

2

O

5

—ZnO—B

2

O

3

—SiO

2

—CaO glass, or the mixture of any of these glasses. Note that any glass that is generally used for a dielectric element may be also used.

As has been described, a predetermined particle diameter of glass powder is mixed well with a binder and a binder dissolution solvent in a ball mill, a dispersion mill, or a jet mill to form a mixed glass paste. Here, the binder is an acrylic resin, ethyl cellulose, ethylene oxide, or the mixture of any of them. The binder dissolution solvent is terpineol, butyl carbitol acetate, pentanediol, or the mixture of any of them. The viscosity of the mixed paste is set to be suitable for an adopted coating method by adjusting the amount of the binder dissolution solvent in the mixed paste.

To the mixed glass paste, a plasticizer or a surface active agent (dispersant) is favorably added as necessary. A plasticizer makes the dried glass coating, i.e., the dried printed glass paste pliant, reducing the frequency of the occurrence of cracks in the glass coating at the time of sintering. A surface active agent sticks around the particles and improves the degree of dispersion of the glass powder, resulting a smooth surface of a glass coating. As a result, adding of a surface active agent is effective especially to the die coating method, the spray coating method, the spin coating method, and the blade coating method, in which a glass paste with a relatively low viscosity is used.

Here, the favorable composition of the mixed glass paste is a 35 to 70 wt. % of glass powder and a 30 to 65 wt. % of binder ingredient including a 5 to 15 wt. % of binder. The amount of plasticizer and the surface active agent (dispersant) is favorably 0.1 to 3.0 wt. % of the binder ingredient.

The surface active agent (dispersant) is an anion surface active agent such as polycarboxylic acid, alkyl diphenyl ether sulfonic acid sodium salt, alkyl phosphate, phosphate salt of a high-grade alcohol, carboxylic acid of polyoxyethylene ethlene diglycerolboric acid ester, polyoxyethylene alkylsulfuric acid ester salt, naphthalenesulfonic acid formalin condensate, glycerol monooleate, sorbitan sesquioleate, and homogenol. The plasticizer is dibutyl phthalate, dioctyl phthalate, glycerol, or the mixture of any of them.

The mixed glass paste is printed according to the screen printing method, the die coating method, the spin coating method, the spray coating method, or the blade coating method on the front glass substrate

11

on the surface of which the discharge electrodes have been formed. The printed mixed glass paste is dried and the glass powder in the mixed glass paste undergoes sintering at a predetermined temperature (550 to 590° C.). The temperature of the sintering is as close as possible to the softening point of the glass. When the mixed glass paste undergoes sintering at a temperature too much higher than the softening point of the glass, the melted glass flows so well that the glass reacts to the discharge electrodes, resulting the frequent occurrence of bubbles in the dielectric glass layer.

As the dielectric glass layer is thinner, the intensity of the PDP is more improved and the discharge voltage is more reduced. As a result, the thickness of the dielectric glass layer is set as small as possible as long as the voltage endurance is kept. In the present embodiment, the thickness of dielectric glass layer

13

is set at a predetermined value smaller than 20 μm that is the thickness of a conventional dielectric glass layer.

The explanation of the printing of the mixed glass paste using the screen printing method, the die coating method, the spin coating method, the spray coating method, and the blade coating method will be given below.

First, the screen printing method will be explained. In the screen printing method, the mixed glass paste that has been described (the viscosity of which is about 50,000 cp) is placed on a stainless mesh of a predetermined mesh size (for instance, 325 mesh), and is printed using a squeegee so that the thickness of the printed mixed glass paste is a desired thickness.

Then, the die coating method will be explained.

FIG. 7

is a schematic diagram of a die coater used in forming a dielectric glass layer. A front glass substrate

71

on which discharge electrodes have been formed is placed on a table

72

. A glass paste

73

the viscosity of which has been adjusted to be equal to or smaller than 50,000 cp is put in a tank

74

. The glass paste

73

is guided by a pump

75

to a slot die

76

and is delivered from a head nozzle

77

, coating the substrate. The distance between the head nozzle

77

, the viscosity of the glass paste

73

, the number of coating (the thickness of a glass paste layer formed by one coating is 5 to 100 μm), and the like are adjusted so that a desired thickness of glass paste layer is obtained.

The spray coating method will be explained.

FIG. 8

is a schematic diagram of a spray coater used in forming a dielectric glass layer. A front glass substrate

81

on which discharge electrodes have been formed in placed on a table

82

. A glass paste

83

the viscosity of which has been adjusted to be equal to or lower than 10,000 cp is put in a tank

84

. The glass paste

83

is guided by a pump

85

to a spray gun

86

and is spouted from a nozzle

87

(the insider diameter of which is 100 μm), coating the front panel

81

so that the thickness of a glass paste layer is a desired thickness. The thickness of the glass powder layer is controlled by adjusting the viscosity of the glass paste

83

, the spray pressure, the number of coating (the thickness of the glass paste layer formed by one coating is 0.1 to 5 μm), and the like.

Note that while a glass paste changes into a slurry as the viscosity is decreased, a glass paste is referred to as a paste even when the viscosity is decreased in this specification.

Then, the spin coating method will be explained.

FIG. 9

is a schematic diagram of a spin coater used in forming a dielectric glass layer. A front glass substrate

91

on which discharge electrodes have been formed is placed on a table

92

, which rotates about a vertical axis. A glass paste

93

the viscosity of which has been adjusted to be equal to or lower than 10,000 cp is put in a tank

94

. The glass paste

93

is guided by a pump

95

to a spin coat gun

96

and is delivered from a nozzle

97

, coating the front panel

91

so that the thickness of a glass paste layer is a desired thickness. The thickness of the glass paste layer is controlled by adjusting the viscosity of the glass paste

93

, the rotation speed of the table

92

, the number of coating (the thickness of the glass paste layer formed by one coating is 0.1 to 5 μm), and the like.

Next, the blade coating method will be explained.

FIG. 10

is a schematic diagram of a blade coater used in forming a dielectric glass layer. A front glass substrate

101

on which discharge electrodes have been formed is placed on a table

102

. A glass paste

103

the viscosity of which has been adjusted to be equal to or lower than 15,000 cp is put in a tank

105

, which is equipped with a blade

104

. The tank

105

is drawn in the direction of an arrow

106

and a certain amount of the glass paste

103

is delivered from the blade

104

on the glass substrate so that a predetermined thickness of glass paste layer is applied on the glass substrate. The thickness of the glass paste layer is controlled by adjusting the viscosity of the glass paste

103

, the distance between the blade and the glass substrate, the number of glass paste layer application, and the like.

Here, the screen printing method, the die coating method, the spin coating method, the spray coating method, and the blade coating method are compared with each other. In the screen printing method, a paste (ink) the viscosity of which is relatively high is used, i.e., an ink that is easy to flow is used. As a result, the mesh pattern is left on the surface of a printed dielectric element at the time of drying after the printing, generating an uneven dielectric glass layer surface (refer to “

Saishin Purazuma Disupurei Seizo

-

Gijutsu, Gekkan FPD Interijensu

(Latest Plasma Display Manufacturing Method, Monthly FPD Intelligence)” December issue, 1997, p105). In the present embodiment, the glass material in which the average particle diameter of the glass powder is 0.1 to 1.5 μm and the maximum particle diameter is equal to or smaller than three times the average particle diameter is used in the screen printing method. As a result, the unevenness on the surface of the dielectric glass layer appears less frequently and the visible light transmittance is improved compared with when using a conventional glass material in which the average particle diameter is equal to or larger than 2 μm. Even so, however, the mesh pattern is still left, so that the screen printing method is susceptible to improvement.

On the other hand, the glass paste has a relatively low viscosity, i.e., the glass paste is easy to flow, and no mesh is used in the die coating method, the spin coating method, the spray coating method, and the blade coating method. As a result, no mesh pattern is left on the surface of the dielectric element, resulting smoother surface and the more improved visible light transmittance compared with in the screen printing method. Consequently, the die coating method, and the blade coating method is more suitable as a method of forming a dielectric glass layer.

The explanation of how the dielectric glass layer

23

is formed will be given below.

The dielectric glass layer

23

in the same manner as the dielectric glass layer

13

using a glass powder in which 5 to 30 wt. % of TiO

2

is added to the glass powder that has been used in forming the dielectric glass layer

13

. By adding the TiO

2

, the dielectric glass layer

23

on the back glass substrate

21

reflects the light emitted from a phosphor toward the front panel

10

.

The more the TiO

2

is included in a glass powder, the higher the reflectivity. On the other hand, the more the TiO

2

is included, the more the voltage endurance decreases. As a result, the maximum amount of the TiO

2

is 30 wt % of the dielectric glass material.

In addition, a greater amount of TiO

2

effects the appearance of bubbles in the dielectric glass layer, so that it is favorable to use a glass powder in which the average particle diameter is 0.1 to 1.5 μm and the maximum particle diameter is equal to or smaller than three times the average particle diameter. It is more favorable to use a glass powder in which the average particle diameter is 0.1 to 0.5 μm.

The reason why the frequency of the bubble appearance in a dielectric glass layer is decreased when the particle diameter of the glass material is decreased will be given below.

First, the reason why the frequency of the bubble appearance depends on the diameter of the glass material will be explained.

In a glass material, glass particles with relatively small diameters melt earlier than those with relatively large diameters. When an applied glass layer includes glass particles with different diameters, by the end of the sintering, glass particles with relatively small diameters melt and flocculate due to the fluidity, having no gap which gas passes through. At this time, when larger diameter particles do not melt, gas is left in the interstices among these larger diameter particles. As a result, because of the melting speed difference between the glass particles, the interstices among relatively large diameter particles are left as bubbles after sintering. As has been descirbed, bubble appearance depends on the particle diameter of a glass powder, i.e., there is a high correlation between the particle diameters of a glass powder and the diameters of the bubbles appearing in a glass layer. As a result, the frequency of the bubble appearance in the glass layer is decreased by setting the glass powder average particle diameter at 0.1 to 1.5 μm and the maximum particle diameter to be equal to or smaller than three times the average particle diameter as in the present embodiment. Note that even when the particle diameter is set as has been described, glass particles with relatively small diameters melt earlier than those with relatively large diameters, so that the glass particles that melt earlier flocculate earlier due to the fluidity by the end of the sintering. In this case, however, the melting speed difference is small. As a result, the frequency of bubble appearance is decreased. The phenomena is confirmed by the experiences given later.

In addition, the surface of the front and back glass substrates

11

and

21

after the forming of the discharge electrodes

12

and the address electrodes

22

is uneven anyway. Especially when the discharge electrodes

12

and the address electrodes

22

are formed according to the photolithographic method, large projections are formed on the surface. Since dielectric glass layers are formed on the surface, on which the projections of the discharge electrodes

12

and the address electrodes

22

have been formed, bubbles remain in depressions. This is also a cause of bubble appearance in a dielectric glass layer. In the present embodiment, the average particle diameter of the glass material is 0.1 to 1.5 μm. The average diameter is smaller than that of a conventional glass material, i.e., 2 to 15 μm. In other words, the glass material in the present embodiment includes a greater amount of small diameter glass particles. As a result, the probability is higher that small diameter particles fill the depressions to decrease the frequency of bubble appearance in the depressions.

The explanation of how different the melting speed of glass materials with different particle diameters will be given below according to a specific data.

FIG. 11

is a table showing the relations between the melting speeds and the average particle diameters of glass materials. Glass materials with the average diameter of 0.85 μm and 3.17 μm are formed into a predetermined size of circular cylinders by the application of pressure. These circular cylinders are heated at a rate of heating 10° C./min and the photographs of the circular cylinders are taken every time the temperature increases 20° C. from 400 to 800° C. using a heating microscope. The black pictures represent the circular cylinders. As clearly shown in

FIG. 11

, the melting speed of the circular cylinder of the glass material of smaller diameter particles is larger than that of the larger diameter particles at the same temperature. The experiment is described in detail in “

Denki Kagaku

(Electrochemical)” (Vol. 56, No.1, 1998, pp23-24).

As has been descirbed, the frequency of bubble appearance is decreased, a certain level of voltage endurance is secured even when the dielectric glass layers

12

and

23

are set thinner in the present embodiment. More specifically, even when the thickness of the dielectric glass layers

13

and

23

are set to be equal to or smaller than 20 μm to increase the intensity, the decrease of the voltage endurance due to a thinner thickness is prevented. As a result, the effects of improving the panel intensity and decreasing the discharge electrode are obtained at the same time.

In addition, when the dielectric glass layers

13

and

23

are set thinner, the voltage endurance is sufficiently secured. As a result, an outstanding initial performance such as higher panel intensity and a lower discharge voltage may be maintained for a relatively long period of time even when the PDP is used frequently, making the PDP a reliable, superior one.

Furthermore, formed using relatively small glass particles, the dielectric glass layers

13

and

23

have highly smooth surfaces. As a result, the dielectric glass layers

13

and

23

have a relatively high visible light transmittance.

Note that while a relatively fine glass powder is used in forming a dielectric glass layer for both of the front and back panels

10

and

20

in the present embodiment, the relatively fine glass powder may be used only for one of the front and back panels

10

and

20

. In addition, when a dielectric glass layer is formed only on the side of the front panel

10

in a PDP, the relatively fine glass powder may be used only for the front panel

10

.

The explanation of specific experiments shown as examples (1) and (2) will be given below.

EXAMPLE (1)

(Table 1)

(Table 2)

(Table 3)

(Table 4)

Tables 1 and 2 show the conditions concerning the forming of the dielectric glass layer

13

on the side of the front panel

10

(glass composition, average particle diameter, glass paste composition, firing temperature, and the like). Tables 3 and 4 show the conditions concerning the forming of the dielectric glass layer

23

on the side of the back panel

20

(glass composition, average particle diameter, glass paste composition, firing temperature, and the like).

In the example (1), dielectric glass layers are formed using the test samples Nos. 1 to 14 on Tables 1 to 4 according to the screen printing method.

In the PDPs corresponding to the test samples Nos. 1 to 6, and 9 to 12, the surfaces of the discharge electrodes

12

and the address electrodes

22

are covered by the dielectric glass layers

13

and

23

formed using the glass powder in which the average particle diameter is 0.1 to 1.5 μm and the maximum particle diameter is equal to or smaller than three times the average particle diameter according to the foregoing embodiment. The thickness of the dielectric glass layers

13

and

23

is 10 to 15 μm (on average).

Here, the cell size of the PDP will be given below. For a high-definition TV having a screen that measures 42 inches, the height of the walls

24

is set to be 0.15 mm, the interval between the walls

24

, i.e., the cell pitch is set to be 0.15 mm, and the interval between the discharge electrodes

12

is set to be 0.05 mm. An Ne—Xe mixed gas including 5 vol % of Xe is filled into the discharge spaces

30

at the infusion pressure of 600 Torr.

The protective layer

14

is formed according to the plasma CVD method. In the plasma CVD method, acetylacetone magnesium [Mg(C

5

H

2

O

2

)

2

] or magnesium dipivaloylmethane [Mg(C

11

H

19

O

2

)

2

] is used as the source.

The conditions in the plasma CVD method are given below. The temperature of the vaporizers is set to be 125° C. and the temperature to heat the glass substrate is set to be 250° C. One liter of Ar gas and two liters of oxygen are applied on a glass substrate per minute. The pressure is decreased to 10 Torr, and 13.56 MHz high-frequency electric field at 300 W is applied from a high-frequency power for 20 seconds. The MgO protective

14

is formed so that the thickness is to be 1.0 μm. The speed in forming the protective layer

14

is 1.0 μm/minute.

An X-ray analysis shows that the crystal face of the protective layer

14

orientates to (100) face for all of the test samples when using either of Mg(C

5

H

7

O

2

)

2

and Mg(C

11

H

19

O

2

)

2

as the source. Note that the protective layer

14

is formed according to the plasma CVD method. The characteristics of the PDPs are almost the same when the material gas used in the plasma CVD method is acetylacetone magnesium or magnesium dipivaloylmethane.

For the dielectric glass layer

13

on the side of the front panel

10

, while a PbO—B

2

O

3

—SiO

2

—CaO—Al

2

O

3

dielectric glass is used in the PDPs corresponding to the test samples Nos. 1 to 8, a PbO—B

2

O

3

—SiO

2

—CaO—Al

2

O

3

dielectric glass is used in the PDPs corresponding to the test samples Nos. 9 to 14.

For the dielectric glass layer

23

on the side of the back panel

20

, a glass material in which titanium oxide is added to a PbO—B

2

O

3

—SiO

2

—CaO dielectric glass as the filler.

The PDPs corresponding to the test samples Nos. 7, 8, 13, 14 are comparative examples. In the test samples Nos. 7, 8, 13, 14, the dielectric glass powders used for forming the dielectric glass layers

13

and

23

have the characteristics given below. On the side of the front panel

10

, the average particle diameter is 3.0 μm and the maximum particle diameter is 6.0 μm in the test sample No. 7, the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm (four times the average particle diameter) in the test sample No. 8, the average particle diameter is 3.0 μm and the maximum particle diameter is 9.0 μm in the test sample No. 13, and the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm (four times the average particle diameter) in the test sample No. 14. On the side of the back panel

20

, the average particle diameter is 3.0 μm and the maximum particle diameter is 9.0 μm in the test sample No. 7, the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm (four times the average particle diameter) in the test sample No. 8, the average particle diameter is 3.0 μm and the maximum particle diameter is 9.0 μm in the test sample No. 13, and the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm (four times the average particle diameter) in the test sample No. 14.

Experiment 1

For each of the PDPs corresponding to the test samples Nos. 1 to 14, the sizes of the bubbles in the dielectric layers on the discharge electrodes and the address electrodes are examined by an electron microscope (the magnification is 1000 times), and the average bubble diameter is obtained from the measurement of the diameters of a predetermined number of bubbles. The diameter of one bubble is the average of the measurements of two axes.

Experiment 2

A withstand voltage test is performed for each of the PDPs corresponding to the test samples Nos. 1 to 14 in the manner given below. Before the sealing of the panel, the front panel

10

(the back panel

20

) is removed, and the discharge electrodes

12

(the address electrodes

22

) is set to be the anode. A silver paste is printed on the dielectric glass layer

13

(the dielectric glass layer

23

), and the printer silver paste is set to be the cathode after being dried. A voltage is placed between the anode and the cathode, and the voltage when the electrical breakdown occurs is determined as the withstand voltage.

In addition, the panel intensity (cd/cm

2

) is obtained for each of the PDPs from the measurement when the PDP is discharged with a discharge maintaining voltage of about 150 V and at a frequency of 30 kHz.

Experiment 3

20 PDPs are manufactured for each of the PDPs corresponding to the test samples Nos. 1 to 14, and a acceleration life test is performed for each of the manufactured PDPs. The acceleration life test is performed under a significantly severe condition, i.e., the PDPs are discharged with a discharge maintaining voltage 200 V at a frequency of 50 kHz for four consecutive hours. After the discharge, the breaking conditions of the dielectric glass layers and the like in the PDPs (voltage endurance defects of the PDPs) are checked.

The results of the experiments 1 to 3 are shown on Tables 5 and 6 given below.

(Table 5)

(Table 6)

Experiment 4

In the experiment 4, the voltage endurance of dielectric glass layers are measured. The dielectric glass layers have different thickness equal to or smaller than 30 μm and have been formed using the glass materials in which the average particle diameters of the glass powders are 3.5 μm, 1.1 μm, and 0.8 μm. The relation between the thickness of dielectric glass layer and the voltage endurance is shown in

FIG. 12

according to the experimental results.

Study

The experimental results on Tables 5 and 6 show that the PDPs corresponding to the test samples Nos. 1 to 6, and 9 to 12 have superior panel intensities compared with a conventional PDP, the panel intensity of which is about 400 cd/m

2

(described in “Flat-Panel Display” 1997, p198).

The observation of the bubble sizes, and the results of the withstand voltage test of the dielectric glass layers and the acceleration life test of the PDPs show that the PDPs corresponding to the test samples Nos. 1 to 6, and 9 to 12 including the dielectric glass layers that have been formed using the glass materials in which the average particle diameter of the glass powder is 0.1 to 1.5 μm and the maximum particle diameter is smaller than three times the average particle diameter are superior in voltage endurance compared with the PDPs corresponding to the test samples 7, 8, 13, and 14 including the dielectric glass layers that have been formed using the glass materials in which the average particle diameter of the glass powder is equal to or larger than 1.5 μm or the glass materials in which the average particle diameter of the glass powder is equal to or smaller than 1.5 μm and the maximum particle diameter is more than three times the average particle diameter.

As a result, coating of the discharge electrodes and the address electrodes by the dielectric glass layer that has been formed using a glass powder in which the average particle diameter is 0.1 to 1.5 μm and the maximum particle diameter is smaller than three times the average particle diameter may improve the voltage endurance even when the thickness of the dielectric glass layer is set to be smaller than 20 μm, i.e., even if the dielectric glass layer is thinner than a conventional one so that an improved intensity is obtained.

Note that the dielectric glass layers formed using the glass powder the average particle diameter of which is set to be equal to or larger than 3 μm for the PDPs corresponding to the test samples Nos. 7 and 13, and the dielectric glass layers formed using the glass powder the average particle diameter of which is set to be 1.5 μm and the maximum particle diameter of which is set to be larger than three times the average particle diameter are easy to have electrical breakdown even though these dielectric layers on the discharge electrodes and the address electrodes are thicker than those in the PDPs corresponding to the test samples Nos. 1 to 6, and 9 to 12.

As has been described,

FIG. 12

shows that the voltage endurance increases as the size of the average particle diameter of the glass material decreases when the thickness of dielectric glass layer is the same.

In other words, when the voltage endurance is the same, the thickness of dielectric layer decreases as the size of the average particle diameter decreases. As a result, a smaller glass material average diameter realizes a higher intensity with the same voltage endurance.

EXAMPLE (2)

(Table 7)

(Table 8)

(Table 9)

(Table 10)

(Table 11)

(Table 12)

(Table 13)

(Table 14)

(Table 15)

(Table 16)

In the PDPs corresponding to the test samples Nos. 1 to 6, 9 to 12, 15 to 20, 23 to 28, and 31 to 34 on Tables 7 to 16, the discharge electrodes and the address electrodes are covered by dielectric glass layers. The dielectric glass layers are formed by applying a glass paste on the glass substrates according to the die coating method, the spray coating method, the spin coating method, or the blade coating method and by firing the applied glass paste. The glass paste includes a binder component including a plasticizer and a surface active agent, and the glass powder the average particle diameter of which is 0.1 to 1.5 μm and the maximum particle diameter of which is equal to or smaller than three times the average particle diameter. The thickness of the dielectric glass layers is set to be 10 to 15 μm (on average).

The cell size of the PDPs is set for the high-definition TV display that measures 42 inches. The height of the walls

24

is set to be 0.15 mm, the interval between the walls

24

, i.e., the cell pitch is set to be 0.15 mm, and the interval between the discharge electrodes

12

is set to be 0.05 mm. An Ne—Xe mixed gas including 5 vol % of Xe is filled into the discharge spaces

30

at the infusion pressure of 600 Torr.

The protective layer

14

is formed using acetylacetone magnesium [Mg(C

5

H

7

O

2

)

2

] or magnesium dipivaloylmethane [Mg(C

11

H

19

O

2

)

2

] as the source according to the plasma CVD method that has been described.

An X-ray analysis shows that the crystal face of the protective layer

14

orientates to (100) face for all of the test samples when either of Mg(C

5

H

7

O

2

)

2

and Mg(C

11

H

19

O

2

)

2

is used as the source.

In each of the PDPs corresponding to the test samples Nos. 1 to 8, the dielectric glass layer on the side of the front panel is formed using a PbO—B

2

O

3

—SiO

2

-CaO—Al

2

O

3

dielectric glass. In the PDPs corresponding to the test samples Nos. 9 to 14, the dielectric glass layer is formed using a Bi

2

O

3

—ZnO—B

2

O

3

—SiO

2

—CaO dielectric glass. In the PDPs corresponding to the test samples Nos. 15 to 22, a ZnO—B

2

O

3

—SiO

2

—Al

2

O

3

—CaO dielectric glass is used. In the PDPs corresponding to the test samples Nos. 23 to 30, a P

2

O

5

—ZnO—Al

2

O

3

—CaO dielectric glass is used. In the PDPs corresponding to the test samples Nos. 31 to 36, an Nb

2

O

5

—ZnO—B

2

O

3

—SiO

2

—CaO dielectric glass is used. In each of the PDPs, the dielectric glass layer on the side of the back panel is formed using the mixture of titanium oxide and the dielectric glass that is almost the same as used for the dielectric glass layer on the side of the front panel.

In each of the PDPs corresponding to the test samples Nos. 1 to 3, 9, 10, 15 to 17, 23 to 25, 31, and 32, the dielectric glass layer is formed according to the die coating method, and the glass paste is adjusted so that the viscosity is 20,000 to 50,000 cp.

In the PDPs corresponding to the test samples Nos. 4, 12, 19, 27, 28 and 34, the dielectric glass layer is formed according to the spray coating method, and the glass paste is adjusted so that the viscosity is 500 to 20,000 cp.

In the PDPs corresponding to the test samples Nos. 5, 11, 18, 26, and 33, the spin coating method is used, and the glass paste is adjusted so that the viscosity is 100 to 3,000 cp.

In the PDPs corresponding to the test samples Nos. 6 and 20, the blade coating method is used, and the glass paste is adjusted so that the viscosity is 2,000 to 10,000 cp.

The dielectric glass layers on the address electrodes are all formed according to the die coating method.

The PDPs corresponding to the test samples Nos. 7, 8, 13, 14, 21, 22, 29, 30, 35, and 36 are comparative examples. In these PDPs, the dielectric glass layers are formed according to the screen printing method, and the particle diameters of the dielectric glass powders used for the dielectric layers are set to be as given below. On the side of the front panel, the average particle diameter is 3.0 μm and the maximum particle diameter is 6.0 μm in the PDP corresponding to the test samples No. 7, the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm (four times the average particle diameter) in the No.8 PDP, the average particle diameter is 3.0 μm and the maximum particle diameter is 9.0 μm in the No. 13. PDP, the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm (four times the average particle diameter) in the No. 14 PDP, the average particle diameter is 3.0 μm and the maximum particle diameter is 6.0 μm in the No. 21 PDP, the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm (four times the average particle diameter) in the No. 22 PDP, the average particle diameter is 3.0 μm and the maximum particle diameter is 6.0 μm in the No. 29 PDP, the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm in the No. 30 PDP, the average particle diameter is 3.0 μm and the maximum particle diameter is 9.0 μm in the No. 35 PDP, and the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm (four times the average particle diameter) in the No. 36 PDP. On the side of the back panel, the average particle diameter is 3.0 μm and the maximum particle diameter is 6.0 μm in the No. 7 PDP, the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm (four times the average particle diameter) in the No. 8 PDP, the average particle diameter is 3.0 μm and the maximum particle diameter is 9.0 μm in the No. 13 PDP, the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm (four times the average particle diameter) in the No. 14 PDP, the average particle diameter is 3.0 μm and the maximum particle diameter is 6.0 μm in the No. 21 PDP, the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm (four times the average particle diameter) in the No. 22 PDP, the average particle diameter is 3.0 μm and the maximum particle diameter is 7.0 μm in the No. 29 PDP, the average particle diameter is 1.5 μm and the maximum particle diameter is 6.5 μm in the No. 30 PDP, the average particle diameter is 3.0 μm and the maximum particle diameter is 9.0 μm in the No. 35 PDP, and the average particle diameter is 1.5 μm and the maximum particle diameter is 6.0 μm (four times the average particle diameter) in the No. 36 PDP.

Experiment 1

For each of the PDPs corresponding to the test samples Nos. 1 to 14, the sizes of the bubbles in the dielectric layers on the discharge electrodes and the address electrodes are examined by an electronic microscope (the magnification is 1000 times), and the average bubble diameter is obtained from the measurement of the diameters of a predetermined number of bubbles. The diameter of one bubble is the average of the measurements of two axes.

Experiment 2

A withstand voltage is performed for each of the PDPs corresponding to the test samples Nos. 1 to 14 in the manner given below. Before the sealing of the panel, the front panel

10

(the back panel

20

) is removed, and the discharge electrodes

12

(the address electrodes

22

) is set to be the anode. A silver paste is printed on the dielectric glass layer

13

(the dielectric glass layer

23

), and the printed silver paste is set to be the cathode after being dried. A voltage is placed between the anode and the cathode, and the voltage when the electrical breakdown occurs is determined as the withstand voltage. The panel intensity (cd/cm

2

) is obtained for each of the PDPs from the measurement when the PDP is discharged with a discharge maintaining voltage of about 150 V and at a frequency of 30 kHz.

Experiment 3

20 PDPs are manufactured for each of the PDPs corresponding to the test samples Nos. 1 to 36, and a acceleration life test is performed for each of the manufactured PDPs. The acceleration life test is performed under a condition significantly severer than a usual condition, i.e., the PDPs are discharged with a discharge maintaining voltage 200 V at a frequency of 50 kHz for four consecutive hours. After the discharge, the breaking conditions of the dielectric glass layers and the like in the PDPs (voltage endurance defects of the PDPs) are checked. The results of the experiments 1 to 3 are shown in Tables 17 to 21 given below.

(Table 17)

(Table 18)

(Table 19)

(Table 20)

(Table 21)

Study

The experimental results on Tables 17 to 21 show that the PDPs corresponding to the test samples Nos. 1 to 6, 9, to 12, 15 to 20, 23 to 28, and 31 to 34 have superior panel intensities compared with a conventional PDP, the panel intensity of which is about 400 cd/m

2

.

The observation of the bubble sizes, and the results of the withstand voltage test of the dielectric glass layers and the acceleration life test of the PDPs show that the PDPs corresponding to the test samples Nos. 1 to 6, 9 to 12, 15 to 20, 23 to 28, and 31 to 34 including the dielectric glass layers that have been formed using the glass materials in which the average particle diameter of the glass powder is 0.1 to 1.5 μm and the maximum particle diameter is equal to or smaller than three times the average particle diameter are superior in the voltage endurance and the surface smoothness (refer to the surface roughness data in the far-right column on Tables 7 to 11, the surface roughness means the center line average roughness) compared with the PDPs corresponding to the test samples 7, 8, 13, 14, 21, 22, 20, 30, 35, and 36 including the dielectric glass layers that have been formed using the glass materials in which the average particle diameter of the glass powder is equal to or larger than 1.5 μm or the glass materials in which the average particle diameter of the glass powder is equal to or smaller than 1.5 μm and the maximum particle diameter is more than three times the average particle diameter.

As a result, coating of the Ag electrodes by the dielectric glass layer that has been formed using a glass powder in which the average particle diameter of the glass powder is 0.1 to 1.5 μm and the maximum particle diameter is smaller than three times the average particle diameter may improve the voltage endurance even when the thickness of the dielectric glass layer is set to be smaller than 20 μm, i.e., even when the dielectric glass layer is thinner than a conventional one so that an improved intensity is obtained.

Note that the dielectric glass layers formed using the glass powder the average particle diameter of which is set to be equal to or larger than 3 μm for the PDPs corresponding to the test samples Nos. 7, 13, 21, 29, and 35, and the dielectric glass layers formed using the glass powder the average particle diameter of which is set to be 1.5 μm and the maximum particle diameter is set to be larger than three times the average particle diameter for the PDPs corresponding to the test samples Nos 8, 14, 22, 30, and 36 are easy to have electrical breakdown even though these dielectric glass layers are thicker than those in the PDPs corresponding to the test samples Nos. 1 to 6, 9 to 12, 15 to 20, 23 to 28, and 31 to 34.

Although the present invention has been fully described by way of examples with reference to the accompanying drawings, it is to be noted that various changes and modifications will be apparent to those skilled in the art. Therefore, unless such changes and modifications depart from the scope of the present invention, they should be construed as being included therein.

TABLE 1

conditions of dielectric glass layer on front panel

glass powder

glass paste

average

maximum

glass

surface

test

composition of glass layer

particle

particle

glass

powder

component of

firing

layer

rough-

sample

on discharge electrodes

diameter

diameter

softening

component

binder including

temper-

thickness

ness

No.

PbO

B

2

O

3

SiO

2

CaO

Al

2

O

3

(μm)

(μ)

point

(wt %)

solvent (wt %)

ture(° C.)

(μm)

(μm)

1

50

25

15

10

0

0.1

0.3

560

55

45

580

10

±0.1

2

65

10

22

1

2

0.5

1.5

550

65

35

560

15

±0.5

3

45

30

20

5

0

0.8

2.4

570

70

30

590

13

±0.9

4

55

10

30

5

0

1.0

3.0

575

70

30

590

14

±1.0

5

62

20

10

5

3

1.5

4.5

550

70

30

560

14

±1.5

6

59

10

25

5

1

0.7

2.0

555

65

35

570

15

±0.7

7*

″

″

″

″

″

3.0

6.0

″

″

″

″

″

±3.0

8*

″

″

″

″

″

1.5

6.0

″

″

″

″

″

±2.5

*test samples Nos. 7, 8 are comparative examples

TABLE 2

conditions of dielectric glass layer on front panel(continued)

glass powder

glass paste

average

maximum

glass

surface

test

composition of glass layer

particle

particle

glass

powder

component of

firing

layer

rough-

sample

on discharge electrodes

diameter

diameter

softening

component

binder including

temper-

thickness

ness

No.

PbO

B

2

O

3

SiO

2

CaO

Al

2

O

3

(μm)

(μ)

point

(wt %)

solvent (wt %)

ture (° C.)

(μm)

(μm)

9

35

25

25

10

5

0.1

0.3

580

55

45

590

14

±0.1

10

45

30

15

7

3

0.5

1.5

550

60

40

575

″

±0.5

11

37

28

20

5

10

1.5

4.5

570

″

″

″

″

±1.0

12

35

30

17

10

8

0.8

2.4

575

″

″

″

″

±0.7

13*

″

″

″

″

″

3.0

9.0

″

″

″

″

15

±3.0

14*

″

″

″

″

″

1.5

6.0

″

″

″

″

″

±2.0

*test samples Nos. 13, 14 are comparative examples

TABLE 3

conditions of dielectric glass layer on back panel

glass powder

average

maximum

TiO

2

filler

binder component

glass paste

surface

test

composition of glass layer

particle

particle

particle

glass/

resin/

glass or

firing

rough-

sample

on discharge electrodes

diameter

diameter

diameter

TiO

2

solvent

filler

binder

tempera-

ness

No.

PbO

B

2

O

3

SiO

2

CaO

(μm)

(μm)

(μm)

(wt %)

resin

solvent

(wt %)

(wt %)

(wt %)

ture (° C.)

(μm)

1

70

10

20

0

0.1

0.3

0.1

100/20

A

B

2/98

65

35

550

13

2

65

20

10

5

0.5

1.5

0.2

100/30

″

″

″

″

″

″

″

3

60

15

15

10

0.5

1.5

0.2

″

″

″

″

″

″

560

″

4

68

20

10

2

1.0

3.0

0.3

″

″

″

″

″

″

570

″

5

65

20

10

5

1.5

4.5

0.5

″

″

″

″

″

″

590

″

6

″

″

″

″

1.0

3.0

0.2

″

″

″

″

″

″

560

″

7*

″

″

″

″

3.0

9.0

″

″

″

″

″

″

″

″

15

8*

″

″

″

″

1.5

6.0

″

″

″

″

″

″

″

″

15

*test samples Nos. 7, 8 are comparative examples

A: ethyl cellulose

B: terpineol

TABLE 4

conditions of dielectric glass layer on back panel(continued)

glass powder

average

maximum

TiO

2

filler

binder component

glass paste

surface

test

composition of glass layer

particle

particle

particle

glass/

resin/

glass or

firing

rough-

sample

on discharge electrodes

diameter

diameter

diameter

TiO

2

solvent

filler

binder

tempera-

ness

No.

PbO

B

2

O

3

SiO

2

CaO

(μm)

(μm)

(μm)

(wt %)

resin

solvent

(wt %)

(wt %)

(wt %)

ture (° C.)

(μm)

9

70

10

20

0

0.1

0.3

0.1

100/20

A

B

2/98

65

35

550

13

10

65

20

10

5

0.5

1.5

0.2

100/30

″

″

″

″

″

″

11

″

20

10

5

1.5

4.5

0.2

″

″

″

″

″

″

″

12

″

″

″

″

0.8

2.1

0.3

″

″

″

″

″

″

″

″

13*

″

″

″

″

3.0

9.0

″

″

″

″

″

″

″

″

15

14*

″

″

″

″

1.5

6.0

″

″

″

″

″

″

″

″

″

*test samples Nos. 7, 8 are comparative examples

A: ethyl cellulose

B: terpineol

TABLE 5

characteristics of PDP panel

size of bubble in dielec-

dielectric glass layer

dielectric glass

test

tric glass layer (μm)

dielectric strength (DC, KV)

layer

voltage endurance

sample

on discharge

on address

on discharge

on address

transmittance

defect after aging

panel intensity

No.

electrodes

electrodes

electrodes

electrodes

(%)

(per 20)

(cd/m

2

)

1

none

none

3.0

2.9

95

0

560

2

none

none

3.5

3.0

95

0

555

3

0.1

0.1

2.9

2.7

94

0

548

4

0.1

0.1

2.9

2.7

94

0

543

5

0.2

0.2

2.8

2.5

93

0

541

6

0.1

0.1

3.0

2.8

94

0

553

7*

3.0

3.1

1.5

1.0

83

4

520

8*

3.5

3.8

1.0

0.8

84

5

518

*test samples Nos. 7, 8 are comparative examples

TABLE 6

characteristics of PDP panel(continued)

size of bubble in dielec-

dielectric glass layer

dielectric glass

test

tric glass layer (μm)

dielectric strength (DC, KV)

layer

voltage endurance

sample

on discharge

on address

on discharge

on address

transmittance

defect after aging

panel intensity

No.

electrodes

electrodes

electrodes

electrodes

(%)

(per 20)

(cd/m

2

)

9

none

none

3.2

3.0

95

0

539

10

none

none

3.2

3.1

94

0

564

11

0.2

0.2

2.9

2.7

93

0

558

12

0.1

0.1

3.0

2.8

92

0

557

13*

3.5

4.0

1.0

0.8

81

9

518

14*

3.0

3.0

1.1

0.9

82

10

515

*test samples Nos. 13, 14 are comparative examples

TABLE 7

conditions of dielectric glass layer on front panel

average particle

component

component

test

composition of glass

diameter of gladd

of glass

of binder

sam-

layer on discharge

powder (μm)

glass

powder

including

ple

electrodes (wt %)

maximum particle

softening

in glass

solvent

No.

PbO

B

2

O

3

SiO

2

CaO

Al

2

O

3

diameter (μm)

point(° C.)

paste (wt %)

(wt %)

1

50

25

15

10

0

0.1

560

55

ethyl

maximum 0.30

cellulose 45

2

65

10

22

1

2

0.5

550

65

acrylyl

maximum 1.4

35

3

45

30

20

5

0

0.8

570

70

ethyl

maximum 2.3

cellulose 30

4

55

10

30

5

0

1.0

575

35

ethyl

maximum 3.0

cellulose 65

5

62

20

10

5

3

1.5

550

35

ethyl

maximum 4.0

cellulose 65

6

59

10

25

5

1

0.7

555

50

ethyl

maximum 2.0

cellulose 50

7*

59

10

25

5

1

3.0

555

55

ethyl

maximum 6.0

cellulose 45

8*

59

10

25

5

1

1.5

555

55

ethyl

maximum 6.00

cellulose 45

dielectric

dielectric

dielectric

glass

test

paste

glass

glass

layer

sam-

separator

plasticizer

visco-

firing

layer

surface

ple

in binder

in binder

sity

coating

tempera-

thickness

roughness

No.

(wt %)

(wt %)

(cp)

method

ture (° C.)

(μm)

(μm)

1

sorbitan

dioctyl

3.075

die

580

10

±0.00

sesquioleate

phthalate

coating

0.2

2.0

method

2

glycerol

dibutyl

4.075

die

560

15

±0.0

monooleate

phthalate

coating

0.2

1.0

method

3

glycerol

dibutyl

5.075

die

590

13

±0.7

monooleate

phthalate

coating

0.2

1.0

method

4

glycerol

dibutyl

500

spray

590

14

±0.8

monooleate

phthalate

coating

0.2

2.0

method

5

glycerol

dibutyl

100

spin

560

14

±1.0

monooleate

phthalate

coating

0.2

2.0

method

6

glycerol

dibutyl

175

blade

570

15

±0.5

monooleate

phthalate

coating

0.2

2.0

method

7*

glycerol

dibutyl

3.075

screen

570

15

±5.0

monooleate

phthalate

printing

0.2

2.0

method

8*

glycerol

dibutyl

3.075

screen

570

15

±5.0

monooleate

phthalate

printing

0.2

2.0

method

*test samples Nos. 7, 8 are comparative examples

TABLE 8

conditions of dielectric glass layer on front panel

average particle

component

component

test

composition of glass

diameter of gladd

of glass

of binder

sam-

layer on discharge

powder (μm)

glass

powder

including

ple

electrodes (wt %)

maximum particle

softening

in glass

solvent

No.

B

2

O

3

ZnO

BrO

2

SiO

2

CaO

diameter (μm)

point(° C.)

paste (wt %)

(wt %)

9

35

25

15

10

5

0.1

580

55

acrylyl

maximum 0.30

45

10

45

30

15

7

3

0.5

550

60

ethyl

maximum 0.6

cellulose 40

11

37

28

20

5

10

1.5

570

35

ethyl

maximum 4.0

cellulose 65

12

35

30

17

10

8

0.8

575

40

ethyl

maximum 2.4

cellulose 60

13*

35

30

17

10

8

3.0

575

60

ethyl

maximum 9.0

cellulose 40

14*

35

30

17

10

8

1.5

575

60

ethyl

maximum 6.0

cellulose 40

dielectric

dielectric

dielectric

glass

test

paste

glass

glass

layer

sam-

separator

plasticizer

visco-

firing

layer

surface

ple

in binder

in binder

sity

coating

tempera-

thickness

roughness

No.

(wt %)

(wt %)

(cp)

method

ture (° C.)

(μm)

(μm)

9

homogenol

dibutyl

2.575

die

580

14

±0.07

0.2

phthalate

coating

2.0

method

10

homogenol

dibutyl

3.575

die

575

14

±0.3

0.4

phthalate

coating

2.0

method

11

sorbitan

dibutyl

300

spin

575

14

±0.7

sesquioleate

phthalate

coating

0.2

2.0

method

12

sorbitan

dibutyl

1000

spray

575

14

±0.5

sesquioleate

phthalate

coating

0.2

2.0

method

13*

sorbitan

dibutyl

3.575

screen

575

15

±6.0

sesquioleate

phthalate

printing

0.2

2.0

method

14*

sorbitan

dibutyl

3.575

screen

575

15

±5.5

sesquioleate

phthalate

printing

0.2

2.0

method

*test samples Nos. 13, 14 are comparative examples

TABLE 9

conditions of dielectric glass layer on front panel

average particle

component

component

test

composition of glass

diameter of gladd

of glass

of binder

sam-

layer on discharge

powder (μm)

glass

powder

including

ple

electrodes (wt %)

maximum particle

softening

in glass

solvent

No.

ZnO

B

2

O

3

SiO

2

Al

2

O

3

CaO

diameter (μm)

point(° C.)

paste (wt %)

(wt %)

15

44

30

10.5

5.5

10

0.1

552

55

acrylyl

maximum 0.30

45

16

60

19

10

1

10

0.5

559

65

acrylyl

maximum 1.5

35

17

60

30

1

5

4

0.8

553

70

ethyl

maximum 2.0

cellulose 30

18

50

30

5

1

4

1.0

550

35

ethyl

maximum 2.0

cellulose 65

19

50

25

10

10

5

1.5

558

45

ethyl

maximum 4.0

cellulose 56

20

50

25

10

10

5

0.7

558

45

ethyl

maximum 2.0

cellulose 55

21*

50

25

10

10

5

3.0

558

45

ethyl

maximum 6.00

cellulose 55

22*

50

25

10

10

5

1.5

558

45

ethyl

maximum 6.00

cellulose 55

dielectric

dielectric

dielectric

glass

test

paste

glass

glass

layer

sam-

separator

plasticizer

visco-

firing

layer

surface

ple

in binder

in binder

sity

coating

tempera-

thickness

roughness

No.

(wt %)

(wt %)

(cp)

method

ture (° C.)

(μm)

(μm)

15

homogenol

dioctyl

3.075

die

570

10

±0.06

0.2

phthalate

coating

2.0

method

16

glycerol

dibutyl

4.075

die

560

15

±0.3

monooleate

phthalate

coating

2.0

3.0

method

17

sorbitan

dibutyl

4.875

die

580

13

±0.7

sesquioleate

phthalate

coating

0.2

4.0

method

18

homogenol

dibutyl

500

spin

580

14

±0.8

0.2

phthalate

coating

4.0

method

19

homogenol

dibutyl

1000

spray

560

14

±0.8

0.2

phthalate

coating

4.0

method

20

homogenol

dibutyl

2000

blade

560

15

±1.2

0.2

phthalate

coating

4.0

method

21*

homogenol

dibutyl

4.175

screen

560

15

±5.0

0.2

phthalate

printing

4.0

method

22*

homogenol

dibutyl

4.175

screen

560

15

±5.0

0.2

phthalate

printing

4.0

method

*test samples Nos. 21, 22 are comparative examples

TABLE 10

conditions of dielectric glass layer on front panel

average particle

component

component

test

composition of glass

diameter of gladd

of glass

of binder

sam-

layer on discharge

powder (μm)

glass

powder

including

ple

electrodes (wt %)

maximum particle

softening

in glass

solvent

No.

BrO

2

B

2

O

3

Al

2

O

3

CaO

diameter (μm)

point(° C.)

paste (wt %)

(wt %)

23

42

43

13

13

0.1

525

55

acrylyl

maximum 0.30

45

24

63

19

9

9

0.5

505

65

acrylyl

maximum 1.5

35

25

45

50

5

0

0.8

556

70

ethylene

maximum 2.4

oxide

30

26

50

35

7

8

1.0

508

35

ethyl

maximum 3.0

cellulose 65

27

50

35

14

1

1.5

502

40

ethyl

maximum 4.5

cellulose 60

28

50

35

14

1

0.7

502

50

acrylyl

maximum 2.0

50

29*

50

35

14

1

3.0

502

65

acrylyl

maximum 6.00

35

30*

50

35

14

1

1.5

502

65

acrylyl

maximum 6.00

35

dielectric

dielectric

dielectric

glass

test

paste

glass

glass

layer

sam-

separator

plasticizer

visco-

firing

layer

surface

ple

in binder

in binder

sity

coating

tempera-

thickness

roughness

No.

(wt %)

(wt %)

(cp)

method

ture (° C.)

(μm)

(μm)

23

homogenol

dibutyl

2.575

die

580

10

±0.07

0.2

phthalate

coating

2.5

method

24

glycerol

dibutyl

3.075

die

510

15

±0.3

monooleate

phthalate

coating

0.2

2.5

method

25

sorbitan

dioctyl

4.075

die

570

13

±0.5

sesquioleate

phthalate

4.075

coating

0.1

3.0

method

26

homogenol

dibutyl

1500

spin

515

14

±0.7

0.2

phthalate

coating

3.0

method

27

homogenol

glycerol

15000

spray

510

14

±1.0

0.2

2.0

coating

method

28

glycerol

dioctyl

275

spray

510

15

±0.5

monooleate

phthalate

coating

0.2

1.5

method

29*

homogenol

none

3.875

screen

510

15

±4.0

0.1

printing

method

30*

homogenol

none

4.075

screen

510

15

±3.5

0.1

printing

method

*test samples Nos. 29, 30 are comparative examples

TABLE 11

conditions of dielectric glass layer on front panel

average particle

component

component

test

composition of glass

diameter of gladd

of glass

of binder

sam-

layer on discharge

powder (μm)

glass

powder

including

ple

electrodes (wt %)

maximum particle

softening

in glass

solvent

No.

Nb

2

O

5

ZnO

B

2

O

3

SiO

2

CaO

diameter (μm)

point(° C.)

paste (wt %)

(wt %)

31

19

44

30

7

0

0.1

550

55

acrylyl

maximum 0.30

45

32

9

60

25

1

5

0.5

556

60

ethyl

maximum 1.5

cellulose 40

33

14.5

54

19

10.5

2

1.5

560

40

ethyl

maximum 4.5

cellulose 60

34

15

50

20

10

5

0.8

566

40

ethyl

maximum 2.4

cellulose 60

35*

15

50

20

10

5

3.0

566

70

ethyl

maximum 9.0

cellulose 30

36*

15

50

20

10

5

1.5

566

70

ethyl

maximum 6.0

cellulose 30

dielectric

dielectric

dielectric

glass

test

paste

glass

glass

layer

sam-

separator

plasticizer

visco-

firing

layer

surface

ple

in binder

in binder

sity

coating

tempera-

thickness

roughness

No.

(wt %)

(wt %)

(cp)

method

ture (° C.)

(μm)

(μm)

31

homogenol

dibutyl

3.175

die

570

14

±0.05

0.3

phthalate

coating

2.0

method

32

glycerol

dioctyl

3.375

die

575

14

±0.3

monooleate

phthalate

coating

0.2

2.0

method

33

glycerol

dioctyl

3000

spin

575

14

±0.6

sesquioleate

phthalate

coating

0.2

2.0

method

34

homogenol

dioctyl

5000

spray

575

14

±0.4

0.2

phthalate

coating

2.0

method

35*

homogenol

dioctyl

4.075

screen

575

15

±5.6

0.2

phthalate

printing

2.0

method

36*

homogenol

dioctyl

2.075

screen

575

15

±4.5

0.2

phthalate

printing

2.0

method

*test samples Nos. 35, 36 are comparative examples

TABLE 12

average

particle

diameter

filler

of gladd

particle

proportion

pow-

di-

of binder

glass paste

der (μm)

ameter

resin and sol-

glass

firing

sur-

test

composition of glass

maximum

tita-

glass/

vent (binder

or

bin-

tem-

face

sam-

layer on second

particle

nium

TiO

2

component)

filler

der

separator

plasticizer

pera-

rough-

ple

electrodes (wt %)

diameter

oxide

(wt

resin/

(wt

(wt

(wt

in binder

in binder

coating

ture

ness

No.

PbO

B

2

O

3

SiO

2

CaO

(μm)

(μm)

%)

solvent

%)

%)

%)

(wt %)

(wt %)

method

(° C.)

(μm)

1

70

10

20

0

0.1

0.1

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

550

13

maximum

20

cellulose

98)

monooleate

phthalate

coating

0.30

terpineol

0.2

2.0

method

2

65

20

10

5

0.5

0.2

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

550

13

maximum

30

cellulose

98)

monooleate

phthalate

coating

1.4

terpineol

0.2

2.0

method

3

60

15

15

10

0.5

0.2

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

560

13

maximum

30

cellulose

98)

monooleate

phthalate

coating

1.4

terpineol

0.2

2.0

method

4

68

20

10

2

0.1

0.3

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

570

13

maximum

30

cellulose

98)

monooleate

phthalate

coating

3.0

terpineol

0.2

2.0

method

5

65

20

10

5

1.5

0.5

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

590

13

maximum

30

cellulose

98)

monooleate

phthalate

coating

4.0

terpineol

0.2

2.0

method

6

65

20

10

5

1.0

0.2

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

560

13

maximum

30

cellulose

98)

monooleate

phthalate

coating

2.5

terpineol

0.2

2.0

method

7*

65

20

10

5

3.0

0.2

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

560

15

maximum

30

cellulose

98)

monooleate

phthalate

coating

6.00

terpineol

0.2

2.0

method

8*

65

20

10

5

0.5

0.2

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

560

15

maximum

30

cellulose

98)

monooleate

phthalate

coating

6.00

terpineol

0.2

2.0

method

*test samples Nos. 7, 8 are comparative examples

TABLE 13

conditions of dielectric glass layer on back panel

average

particle

diameter

filler

of gladd

di-

proportion

powder

ameter

of binder

glass paste

fir-

(μm)

particle

resin and

glass

ing

test

composition of glass

maximum

tita-

glass/

solvent bind-

or

tem-

surface

sam-

layer on second

particle

nium

TiO

2

er component)

filler

bin-

separator

plasticizer

pera-

rough-

ple

electrodes (wt %)

diameter

oxide

(wt

resin/

(wt

(wt

der

in binder

in binder

coating

ture

ness

No.

PbO

B

2

O

3

SiO

2

CaO

(μm)

(μm)

%)

solvent

%)

%)

%)

(wt %)

(wt %)

method

(° C.)

(μm)

9

70

10

20

0

0.1

0.1

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

550

13

maximum

20

cellulose

98)

mono-

phthalate

coating

0.30

terpineol

oleate 0.2

2.0

method

10

65

20

10

5

0.5

0.2

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

550

13

maximum

30

cellulose

98)

mono-

phthalate

coating

0.6

terpineol

oleate 0.2

2.0

method

11

65

20

10

5

1.5

0.2

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

560

13

maximum

30

cellulose

98)

mono-

phthalate

coating

4.0

terpineol

oleate 0.2

2.0

method

12

65

20

10

5

0.8

0.3

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

560

13

maximum

30

cellulose

98)

mono-

phthalate

coating

2.4

terpineol

oleate 0.2

2.0

method

13*

65

20

10

5

3.0

0.3

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

560

15

maximum

30

cellulose

98)

mono-

phthalate

coating

9.0

terpineol

oleate 0.2

2.0

method

14*

65

20

10

5

1.5

0.3

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

560

15

maximum

30

cellulose

98)

mono-

phthalate

coating

6.0

terpineol

oleate 0.2

2.0

method

*test samples Nos. 13, 14 are comparative examples

TABLE 14

conditions of dielectric glass layer on back panel

average

particle

filler

diameter

parti-

proportion

of gladd

cle

of bind-

pow-

dia-

er resin and

glass paste

fir-

composition

der (μm)

meter

solvent (bind-

glass

sepa-

plasti-

ing

sur-

test

of glass

maximum

tita-

er component)

or

bin-

rator

cizer

coat-

tem-

face

sam-

layer on second

particle

nium

glass/

resin/

filler

der

in

in

ing

pera-

rough-

ple

electrodes (wt %)

diameter

oxide

TiO

2

sol-

(wt

(wt

(wt

binder

binder

meth-

ture

ness

No.

ZnO

B

2

O

3

SiO

2

Al

2

O

3

CaO

(μm)

(μm)

(wt %)

vent

%)

%)

%)

(wt %)

(wt %)

od

(° C.)

(μm)

15

60

30

5

1

4

0.1

0.1

100/

ethyl

(2/

65

35

sorbitan

dioctyl

die

580

13

maximum

20

cellu-

98)

sesqui-

phtha-

coat-

0.30

lose

oleare

late 2.0

ing

ter-

0.2

meth-

pineol

od

16

60

30

5

1

4

0.5

0.2

100/

ethyl

(2/

65

35

glycerol

dioctyl

die

″

13

maximum

30

cellu-

98)

mono-

phtha-

coat-

1.5

lose

oleate

late 2.0

ing

ter-

0.2

meth-

pineol

od

17

50

25

5

10

10

0.5

0.2

100/

ethyl

(2/

65

35

glycerol

dioctyl

die

565

″

maximum

30

cellu-

98)

mono-

phtha-

coat-

1.5

lose

oleate

late 2.0

ing

ter-

0.2

meth-

pineol

od

18

50

25

5

10

10

1.0

0.3

100/

ethyl

(2/

65

35

glycerol

dioctyl

spray

565

″

maximum

30

cellu-

98)

mono-

phtha-

coat-

2.0

lose

oleate

late 2.0

ing

ter-

0.2

meth-

pineol

od

19

50

25

5

10

10

1.5

0.5

100/

ethyl

(2/

65

35

glycerol

dioctyl

screen

585

″

maximum

30

cellu-

98)

mono-

phtha-

print-

4.0

lose

oleate

late 2.0

ing

ter-

0.2

meth-

pineol

od

20

50

25

10

10

5

1.0

0.2

100/

ethyl

(2/

65

35

glycerol

dioctyl

screen

585

″

maximum

30

cellu-

98)

mono-

phtha-

print-

2.0

lose

oleate

late 2.0

ing

ter-

0.2

meth-

pineol

od

21*

50

25

10

10

5

3.0

0.2

100/

ethyl

(2/

65

35

glycerol

dioctyl

screen

585

15

maximum

30

cellu-

98)

mono-

phtha-

print-

6.0

lose

oleate

late 2.0

ing

ter-

0.2

meth-

pineol

od

22*

50

25

10

10

5

1.5

0.2

100/

ethyl

(2/

65

35

glycerol

dioctyl

screen

585

15

maximum

30

cellu-

98)

mono-

phtha-

print-

6.0

lose

oleate

late 2.0

ing

ter-

0.2

meth-

pineol

od

*test samples Nos. 21, 22 are comparative examples

TABLE 15

conditions of dielectric glass layer on back panel

average

particle

diameter

filler

of gladd

di-

proportion

powder

ameter

of binder

glass paste

fir-

(μm)

particle

resin and

glass

ing

test

composition of glass

maximum

tita-

glass/

solvent bind-

or

tem-

surface

sam-

layer on second

particle

nium

TiO

2

er component)

filler

bin-

separator

plasticizer

pera-

rough-

ple

electrodes (wt %)

diameter

oxide

(wt

resin/

(wt

(wt

der

in binder

in binder

coating

ture

ness

No.

P

2

O

5

B

2

O

3

SiO

2

CaO

(μm)

(μm)

%)

solvent

%)

%)

%)

(wt %)

(wt %)

method

(° C.)

(μm)

23

63

19

9

9

0.1

0.1

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

540

13

maximum

20

cellulose

98)

monooleate

phthalate

coating

0.3

terpineol

0.2

2.0

method

24

63

19

9

9

0.5

0.2

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

540

13

maximum

30

cellulose

98)

monooleate

phthalate

coating

1.5

terpineol

0.2

2.0

method

25

50

35

7

8

0.5

0.2

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

545

13

maximum

30

cellulose

98)

monooleate

phthalate

coating

1.5

terpineol

0.2

2.0

method

26

50

35

7

8

1.0

0.3

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

545

13

maximum

30

cellulose

98)

monooleate

phthalate

coating

0.3

terpineol

0.2

2.0

method

27

50

35

7

8

1.5

0.5

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

545

13

maximum

30

cellulose

98)

monooleate

phthalate

coating

4.5

terpineol

0.2

2.0

method

28

50

35

7

8

1.0

0.2

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

545

13

maximum

30

cellulose

98)

monooleate

phthalate

coating

0.3

terpineol

0.2

2.0

method

29*

50

35

7

8

3.0

0.2

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

545

15

maximum

30

cellulose

98)

monooleate

phthalate

coating

7.0

terpineol

0.2

2.0

method

30*

50

35

7

8

1.5

0.2

100/

ethyl

(2/

65

35

glycerol

dibutyl

die

545

15

maximum

30

cellulose

98)

monooleate

phthalate

coating

6.5

terpineol

0.2

2.0

method

*test samples Nos. 29, 30 are comparative examples

TABLE 16

conditions of dielectric glass layer on back panel

average

particle

filler

diameter

parti-

proportion

of gladd

cle

of bind-

pow-

dia-

er resin and

glass paste

fir-

composition

der (μm)

meter

solvent (bind-

glass

sepa-

plasti-

ing

sur-

test

of glass

maximum

tita-

er component)

or

bin-

rator

cizer

coat-

tem-

face

sam-

layer on second

particle

nium

glass/

resin/

filler

der

in

in

ing

pera-

rough-

ple

electrodes (wt %)

diameter

oxide

TiO

2

sol-

(wt

(wt

(wt

binder

binder

meth-

ture

ness

No.

Nb

2

O

5

ZnO

B

2

O

2

SiO

2

CaO

(μm)

(μm)

(wt %)

vent

%)

%)

%)

(wt %)

(wt %)

od

(° C.)

(μm)

31

13

50

24

8

5

0.1

0.1

100/

ethyl

(2/

65

35

sorbitan

dioctyl

die

570

13

maximum

20

cellu-

98)

sesqui-

phtha-

coat-

0.30

lose

oleare

late 2.0

ing

ter-

0.2

meth-

pineol

od

32

13

50

24

8

5

0.5

0.2

100/

ethyl

(2/

65

35

glycerol

dioctyl

die

570

13

maximum

30

cellu-

98)

mono-

phtha-

coat-

1.5

lose

oleate

late 2.0

ing

ter-

0.2

meth-

pineol

od

33

13

50

24

8

5

1.5

0.2

100/

ethyl

(2/

65

35

glycerol

dioctyl

die

570

13

maximum

30

cellu-

98)

mono-

phtha-

coat-

14.0

lose

oleate

late 2.0

ing

ter-

0.2

meth-

pineol

od

34

13

50

24

8

5

0.8

0.3

100/

ethyl

(2/

65

35

glycerol

dioctyl

die

570

13

maximum

30

cellu-

98)

mono-

phtha-

coat-

2.4

lose

oleate

late 2.0

ing

ter-

0.2

meth-

pineol

od

35*

13

50

24

8

5

3.0

0.3

100/

ethyl

(2/

65

35

glycerol

dioctyl

die

570

15

maximum

30

cellu-

98)

mono-

phtha-

coat-

9.0

lose

oleate

late 2.0

ing

ter-

0.2

meth-

pineol

od

36*

13

50

24

8

5

1.5

0.3

100/

ethyl

(2/

65

35

glycerol

dioctyl

die

570

15

maximum

30

cellu-

98)

mono-

phtha-

coat-

6.0

lose

oleate

late 2.0

ing

ter-

0.2

meth-

pineol

od

*test samples Nos. 35, 36 are comparative examples

TABLE 17

characteristics of panel

size of bubble in dielec-

dielectric glasslayer vol-

dielectric glass

voltage endurance

test

tric glass layer (μm)

tage endurance (DC, KV)

layer

defect after with

sample

on discharge

on address

on discharge

on address

transmittance

200V at 50 kHz

panel intensity

No.

electrodes

electrodes

electrodes

electrodes

(%)

(per 20)

(cd/m

2

)

1

none

none

3.6

3.2

97

0

564

2

none

none

3.8

3.3

97

0

560

3

none

none

3.4

3.0

96

0

550

4

0.1

0.1

3.2

2.9

95

0

547

5

0.1

0.1

3.1

2.8

95

0

548

6

0.1

0.1

3.4

3.1

95

0

555

7*

3.0

3.1

1.5

1.0

84

4

522

8*

3.5

3.8

1.0

0.8

85

5

521

*test samples Nos. 7, 8 are comparative examples

TABLE 18

characteristics of panel

size of bubble in dielec-

dielectric glasslayer vol-

dielectric glass

voltage endurance

test

tric glass layer (μm)

tage endurance (DC, KV)

layer

defect after with

sample

on discharge

on address

on discharge

on address

transmittance

200V at 50 kHz

panel intensity

No.

electrodes

electrodes

electrodes

electrodes

(%)

(per 20)

(cd/m

2

)

9

none

none

3.5

3.4

96

0

544

10

none

none

3.5

3.3

96

0

568

11

0.1

0.1

3.4

3.1

94

0

562

12

0.1

0.1

3.3

3.0

94

0

564

13*

3.5

4.0

1.0

0.8

82

9

520

14*

3.0

3.0

1.1

0.9

83

10

517

*test samples Nos. 13, 14 are comparative examples

TABLE 19

characteristics of panel

size of bubble in dielec-

dielectric glasslayer vol-

dielectric glass

voltage endurance

test

tric glass layer (μm)

tage endurance (DC, KV)

layer

defect after with

sample

on discharge

on address

on discharge

on address

transmittance

200V at 50 kHz

panel intensity

No.

electrodes

electrodes

electrodes

electrodes

(%)

(per 20)

(cd/m

2

)

15

none

none

3.3

3.1

97

0

565

16

none

none

3.6

3.1

97

0

558

17

0.1

0.1

3.2

2.9

95

0

553

18

0.1

0.1

3.1

2.8

95

0

547

19

0.2

0.2

3.1

2.7

94

0

545

20

0.1

0.1

3.3

2.9

95

0

557

21*

4.8

4.4

1.4

0.9

81

8

520

22*

4.5

4.3

0.9

0.7

83

9

518

*test samples Nos. 21, 22 are comparative examples

TABLE 20

characteristics of panel

size of bubble in dielec-

dielectric glasslayer vol-

dielectric glass

voltage endurance

test

tric glass layer (μm)

tage endurance (DC, KV)

layer

defect after with

sample

on discharge

on address

on discharge

on address

transmittance

200V at 50 kHz

panel intensity

No.

electrodes

electrodes

electrodes

electrodes

(%)

(per 20)

(cd/m

2

)

23

none

none

3.3

3.2

96

0

555

24

none

none

3.7

3.3

96

0

560

25

0.1

0.1

3.2

3.0

95

0

553

26

0.1

0.1

3.2

3.0

95

0

550

27

0.1

0.1

3.2

2.7

94

0

548

28

0.1

0.1

3.1

3.0

95

0

555

29*

3.2

3.5

1.5

1.0

83

7

519

30*

4.0

3.8

1.0

0.8

84

8

515

*test samples Nos. 29, 30 are comparative examples

TABLE 21

characteristics of panel

size of bubble in dielec-

dielectric glasslayer vol-

dielectric glass

voltage endurance

test

tric glass layer (μm)

tage endurance (DC, KV)

layer

defect after with

sample

on discharge

on address

on discharge

on address

transmittance

200V at 50 kHz

panel intensity

No.

electrodes

electrodes

electrodes

electrodes

(%)

(per 20)

(cd/m

2

)

31

none

none

3.5

3.3

95

0

560

32

none

none

3.5

3.3

95

0

568

33

0.1

0.1

3.2

3.1

95

0

563

34

0.1

0.1

3.1

3.0

94

0

567

35*

4.0

4.1

1.0

0.8

81

10

517

36*

4.2

4.0

1.1

0.9

82

11

514

*test samples Nos. 35, 36 are comparative examples

Claims

1. A manufacturing method of a plasma display panel, the plasma display panel comprising a front panel, including a front glass substrate on which a first electrode and a first dielectric glass layer have been formed, and a back panel, including a back glass substrate on which a second electrode and a phosphor layer have been formed, the front and back panels being positioned so that the first and second electrodes face each other at a predetermined distance, walls being formed between the front and back panels, and spaces surrounded by the front panel, the back panel, and the walls being filled with a dischargeable gas,the plasma display panel manufacturing method being characterized by forming the first dielectric glass layer by firing a glass powder with an average particle diameter of 0.1 to 1.5 μm and a maximum particle diameter that is no greater than three times the average particle diameter.
2. The plasma display panel manufacturing method according to claim 1, whereinthe back panel further includes a second dielectric glass layer, and the plasma display panel manufacturing method forms the second dielectric glass layer by firing a glass powder with an average particle diameter is 0.1 to 1.5 μm and a maximum particle diameter that is no greater than three times the average particle diameter.
3. A manufacturing method of a plasma display panel, the plasma display panel comprising a front panel, including a front glass substrate on which a first electrode and a first dielectric glass layer have been formed, and a back panel, including a back glass substrate on which a second electrode and a phosphor layer have been formed, the front and back panels being positioned so that the first and second electrodes face each other at a predetermined distance, walls being formed between the front and back panels, and spaces surrounded by the front panel, the back panel, and the walls being filled with a dischargeable gas,the plasma display panel manufacturing method being characterized by forming the first dielectric glass layer by applying a first glass paste on the front glass substrate and the first electrode according to a screen printing method and firing a first glass powder in the first glass paste, the first glass paste being a mixture of the first glass powder, at least one of a plasticizer and a surface active agent, a binder, and a binder dissolution solvent, the first glass powder with an average particle diameter of 0.1 to 1.5 μm and a maximum particle diameter that is no greater than three times the average particle diameter.
4. The plasma display panel manufacturing method according to claim 3, whereinthe back panel further includes a second dielectric glass layer, and the plasma display panel manufacturing method forms the second dielectric glass layer by applying a second glass paste on the back glass substrate and the second electrode according to the screen printing method and firing a second glass powder in the second glass paste, the second glass paste being a mixture of the second glass powder, at least one of a plasticizer and a surface active agent, a binder, and a binder dissolution solvent, the second glass powder with an average particle diameter of 0.1 to 1.5 μm and a maximum particle diameter that is no greater than three times the average particle diameter.
5. The plasma display panel manufacturing method according to claim 4, wherein the first and second glass pastes include a titanium oxide powder with an average particle diameter of 0.1 to 0.5 μm.
6. A manufacturing method of a plasma display panel, the plasma display panel comprising a front panel, including a front glass substrate on which a first electrode and a first dielectric glass layer have been formed, and a back panel, including a back glass substrate on which a second electrode, a second dielectric glass layer, and a phosphor layer have been formed, the front and back panels being positioned so that the first and second electrodes face each other at a predetermined distance, walls being formed between the front and back panels, and spaces surrounded by the front panel, the back panel, and the walls being filled with a dischargeable gas,the plasma display panel manufacturing method being characterized by (1) forming the first dielectric glass layer by applying a first glass paste on the front glass substrate and the first electrode according to a screen printing method and firing a first glass powder in the first glass paste, the first glass paste being a mixture of 35 to 70 wt. % of the first glass powder and 30 to 65 wt. % of a first binder component, the first glass powder being an oxide glass powder with an average particle diameter of 0.1 to 1.5 μm and a maximum particle diameter that is no greater than three times the average particle diameter, and the first binder component being formed by adding 0.1 to 3.0 wt. % of at least one of a plasticizer and a surface active agent to at least one of acrylic resin, ethyl cellulose, and ethylene oxide that has been dissolved in at least one of terpineol, butyl carbitol acetate, and pentanediol, and by (2) forming the second dielectric glass layer by applying a second glass paste on the back glass substrate and the second electrode according to the screen printing method and firing a second glass powder in the second glass paste, the second glass paste being a mixture of 35 to 70 wt. % of the second glass powder and 30 to 65 wt. % of a second binder component, the second glass powder being formed by adding 5 to 30 wt. % of a titanium oxide powder with an average particle diameter of 0.1 to 0.5 μm to an oxide glass powder with an average particle diameter of 0.1 to 1.5 μm and a maximum particle diameter that is no greater than three times the average particle diameter, and the second binder component being formed by adding 0.1 to 3.0 wt. % of at least one of a plasticizer and a surface active agent to at least one of acrylic resin, ethyl cellulose, and ethylene oxide that has been dissolved in at least one of terpineol, butyl carbitol acetate, and pentanediol.
7. The plasma display panel manufacturing method according to claim 6, wherein at least one of the first and second glass powders includes at least one of a PbO—B2O3—SiO2—CaO glass powder, a PbO—B2O3—SiO2—MgO glass powder, a PbO—B2O3—SiO2—BaO glass powder, a PbO—B2O3—SiO2—MgO—Al2O3 glass powder, a PbO—B2O3—SiO2—BaO—Al2O glass powder, a PbO—B2O3—SiO2—CaO—Al2O3 glass powder, a Bi2O3—ZnO—B2O3—SiO2—CaO glass powder, a ZnO—B2O3—SiO2—Al2O3—CaO glass powder, a P2O5—ZnO—Al2O3—CaO glass powder, and an Nb2O5—ZnO—B2O3—SiO2—CaO glass powder as the oxide glass powder.
8. The plasma display panel manufacturing method according to claim 7, wherein at least one of the first and second binder components includes at least one of polycarboxylic acid, alkyl diphenyl ether sulfonic acid sodium salt, alkyl phosphate, phosphate salt of a high-grade alcohol, carboxylic acid of polyoxyethylene ethlene diglycerolboric acid ester, polyoxyethylene alkylsulfuric acid ester salt, naphthalenesulfonic acid formalin condensate, glycerol monooleate, sorbitan sesquioleate, and homogenol and a surface active agent.
9. The plasma display panel manufacturing method according to claim 8, wherein at least one of the first and second binder components includes at least one of dibutyl phthalate, dioctyl phthalate, and glycerol as a plasticizer.
10. A manufacturing method of a plasma display panel, the plasma display panel comprising a front panel, including a front glass substrate on which a first electrode and a first dielectric glass layer have been formed, and a back panel, including a back glass substrate on which a second electrode and a phosphor layer have been formed, the front and back panels being positioned so that the first and second electrodes face each other at a predetermined distance, walls being formed between the front and back panels, and spaces surrounded by the front panel, the back panel, and the walls being filled with a dischargeable gas,the plasma display panel manufacturing method being characterized by forming the first dielectric glass layer by applying a first glass paste on the front glass substrate and the first electrode according to one of a die coating method, a spray coating method, a spin coating method, and a blade coating method and firing a first glass powder in the first glass paste, the first glass paste being a mixture of the first glass powder, at least one of a plasticizer and a surface active agent, a binder, and a binder dissolution solvent, the first glass powder with an average particle diameter of 0.1 to 1.5 μm and a maximum particle diameter that is no greater than three times the average particle diameter.
11. The plasma display panel manufacturing method according to claim 10, whereinthe back panel further includes a second dielectric glass layer, and the plasma display panel manufacturing method forms the second dielectric glass layer by applying a second glass paste on the back glass substrate and the second electrode according to one of the die coating method, the spray coating method, the spin coating method, and the blade coating method and firing a second glass powder in the second glass paste, the second glass paste being a mixture of the second glass powder, at least one of a plasticizer and a surface active agent, a binder, and a binder dissolution solvent, the second glass powder with an average particle diameter of 0.1 to 1.5 μm and a maximum particle diameter that is no greater than three times the average particle diameter.
12. The plasma display panel manufacturing method according to claim 11, wherein the first and second glass pastes include a titanium oxide powder with an average particle diameter of 0.1 to 0.5 μm.
13. A manufacturing method of a plasma display panel, the plasma display panel comprising a front panel, including a front glass substrate on which a first electrode and a first dielectric glass layer have been formed, and a back panel, including a back glass substrate on which a second electrode, a second dielectric glass layer, and a phosphor layer have been formed, the front and back panels being positioned so that the first and second electrodes face each other at a predetermined distance, walls being formed between the front and back panels, and spaces surrounded by the front panel, the back panel, and the walls being filled with a dischargeable gas,the plasma display panel manufacturing method being characterized by (1) forming the first dielectric glass layer by applying a first glass paste on the front glass substrate and the first electrode according to one of a die coating method, a spray coating method, a spin coating method, and a blade coating method and firing a first glass powder in the first glass paste, the first glass paste being a mixture of 35 to 70 wt. % of the first glass powder and 30 to 65 wt. % of a first binder component, the first glass powder being an oxide glass powder with an average particle diameter of 0.1 to 1.5 μm and a maximum particle diameter that is no greater than three times the average particle diameter, and the first binder component being formed by adding 0.1 to 3.0 wt. % of at least one of a plasticizer and a surface active agent to at least one of acrylic resin, ethyl cellulose, and ethylene oxide that has been dissolved in at least one of terpineol, butyl carbitol acetate, and pentanediol, and by (2) forming the second dielectric glass layer by applying a second glass paste on the back glass substrate and the second electrode according to one of the die coating method, the spray coating method, the spin coating method, and the blade coating method and firing a second glass powder in the second glass paste, the second glass paste being a mixture of 35 to 70 wt. % of the second glass powder and 30 to 65 wt. % of a second binder component, the second glass powder being formed by adding 5 to 30 wt. % of a titanium oxide powder with an average particle diameter of 0.1 to 0.5 μm to an oxide glass powder with an average particle diameter of 0.1 to 1.5 μm and a maximum particle diameter that is no greater than three times the average particle diameter, and the second binder component being formed by adding 0.1 to 3.0 wt. % of at least one of a plasticizer and a surface active agent to at least one of acrylic resin, ethyl cellulose, and ethylene oxide that has been dissolved in at least one of terpineol, butyl carbitol acetate, and pentanediol.
14. The plasma display panel manufacturing method according to claim 13, wherein at least one of the first and second glass powders includes at least one of a PbO—B2O3—SiO2—CaO glass powder, a PbO—B2O3—SiO2—MgO glass powder, a PbO—B2O3—SiO2—BaO glass powder, a PbO—B2O3—SiO2—MgO—Al2O3 glass powder, a PbO—B2O3—SiO2—BaO—Al2O glass powder, a PbO—B2O3—SiO2—CaO—Al2O3 glass powder, a Bi2O3—ZnO—B2O3—SiO2—CaO glass powder, a ZnO—B2O3—SiO2—Al2O3—CaO glass powder, a P2O5—ZnO—Al2O3—CaO glass powder, and an Nb2O3—ZnO—B2O3—SiO2—CaO glass powder as the oxide glass powder.
15. The plasma display panel manufacturing method according to claim 14, wherein at least one of the first and second binder components includes at least one of polycarboxylic acid, alkyl diphenyl ether sulfonic acid sodium salt, alkyl phosphate, phosphate salt of a high-grade alcohol, carboxylic acid of polyoxyethylene ethylene diglycerolboric acid ester, polyoxyethylene alkylsulfuric acid ester salt, naphthalenesulfonic acid formalin condensate, glycerol monooleate, sorbitan sesquioleate, and homogenol as a surface active agent.
16. The plasma display panel manufacturing method according to claim 15, wherein at least one of the first and second binder components includes at least one of dibutyl phthalate, dioctyl phthalate, and glycerol as a plasticizer.
17. The plasma display panel manufacturing method according to claim 16, wherein a viscosity of the first and second glass pastes is 100 to 50,000 cp.
18. A manufacturing method of a plasma display panel, the plasma display panel comprising a front panel, including a front glass substrate on which a first electrode and a first dielectric glass layer have been formed, and a back panel, including a back glass substrate on which a second electrode, a second dielectric glass layer, and a phosphor layer have been formed, the front and back panels being positioned so that the first and second electrodes face each other at a predetermined distance, walls being formed between the front and back panels, and spaces surrounded by the front panel, the back panel, and the walls being filled with a dischargeable gas,the plasma display panel manufacturing method being characterized by forming the second dielectric glass layer by firing a glass powder with an average particle diameter of 0.1 to 1.5 μm and a maximum particle diameter that is no greater than three times the average particle diameter.

Priority Claims (5)

Number	Date	Country
10-127989	May 1998	JP
10-153323	Jun 1998	JP
10-157295	Jun 1998	JP
10-252548	Sep 1998	JP
11-005016	Jan 1999	JP

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Number	Name	Date	Kind
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6043604	Horiuchi et al.	Mar 2000	A
6046121	Masuko et al.	Apr 2000	A
6184621	Horiuchi et al.	Feb 2001	B1
6194333	Ryu	Feb 2001	B1

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Entry
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Manufacturing method of plasma display panel that includes adielectric glass layer having small particle sizes

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Priority Claims (5)

US Referenced Citations (5)

Non-Patent Literature Citations (4)