KR20030065801A - Barrier Rib Material of Plasma Display Panel and Method of Fabricating Barrier Rib - Google Patents

Abstract

PURPOSE: A barrier rib material and a method for manufacturing a barrier rib are provided to reduce costs and allow the barrier rib to have a high aspect ratio, while achieving improved formability of barrier ribs. CONSTITUTION: A plasma display panel comprises a green sheet(60) containing a composition of ZnO-B2O3-MgO-SiO2 and ZnO-B2O3-MgO-SiO2-K2O+TiO2 which are mixed at a predetermined ratio. A method for manufacturing a barrier rib includes the steps of forming a green sheet; bonding the green sheet onto a substrate(62); and forming a barrier rib by pressing the mold having a groove with a shape corresponding to the shape of the barrier rib against the green sheet.

Description

Barrier Rib Material of Plasma Display Panel and Method of Fabricating Barrier Rib}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel, and more particularly, to a partition material of a PDP and a method of manufacturing the partition wall which can improve the formability of the partition wall.

Plasma Display Panels (hereinafter referred to as "PDPs") display an image including characters or graphics by emitting phosphors by ultraviolet rays of 147 nm generated upon discharge of He + Xe or Ne + Xe gas. Such a PDP is not only thin and easy to enlarge, but also greatly improved in quality due to recent technology development.

Referring to FIG. 1, there is shown an AC drive type PDP having a lower glass substrate 14 on which an address electrode 2 is mounted and an upper glass substrate 16 on which a pair of sustain electrodes 4 are mounted. On the lower glass substrate 14 on which the address electrode 2 is mounted, a partition wall 8 for dividing the dielectric thick film 18 and the discharge cells is formed. The phosphor 6 is coated on the surfaces of the dielectric thick film 18 and the partition wall 8. The phosphor 6 emits light by ultraviolet rays generated at the time of plasma discharge so that visible light is generated. The dielectric layer 12 and the passivation layer 10 are sequentially formed on the upper glass substrate 16 on which the sustain electrode pairs 4 are mounted. The dielectric layer 12 accumulates wall charges during plasma discharge, and the protective layer 10 protects the pair of sustain electrodes 4 and the dielectric layer 12 from sputtering of gas ions during plasma discharge and improves the emission efficiency of secondary electrons. Height plays a role. The discharge cells of the PDP are filled with a mixed gas of He + Xe or Ne + Xe.

The partition 8 serves to prevent electrical and optical crosstalk between discharge cells. Therefore, the partition wall 8 is the most important factor for display quality and luminous efficiency, and as the panel is enlarged and fixed, various studies on the partition wall have been made. As the barrier rib manufacturing method, a screen printing method, a sand blasting method, an additive, a photosensitive paste method, and a low temperature cofired ceramic on metal (LTCCM) method are applied.

Among them, the screen printing method has a simple process and low manufacturing cost, but there is a problem of repeating the screen and the glass substrate 14 in each printing, printing and drying the glass paste several times. In addition, when the position of the screen and the glass substrate is shifted, the partition wall is deformed, so that the shape accuracy of the partition wall is lowered.

The sand blasting method has a merit of forming a partition on a large-area substrate, but a large amount of glass paste removed by the abrasive (sand particles) has a disadvantage of wasting material and manufacturing cost. In addition, the glass substrate 14 is impacted by the abrasive, so that the glass substrate 14 is cracked or damaged.

The addition method has an advantage of forming barrier ribs 8 on a large-area substrate, but it is difficult to separate photoresist and glass paste, leaving a residue or collapsing barrier ribs when forming barrier ribs.

The LTCCM method has a low temperature process and a simple process compared with other barrier rib manufacturing methods.

Figure 2a to 2h shows step by step manufacturing method using the LTCCM method. First, the green sheet 30 as shown in Figure 2a is produced. The green sheet 30 is manufactured by drying a slurry in which a glass powder, an organic solution, a plasticizer, a binder, an additive, and the like are mixed in a predetermined ratio on a polyester film, and forming a sheet in a doctor blading, followed by drying. . As a material of the substrate 32 to which the green sheet 30 is bonded, a metal, for example, titanium (Titanum) is usually used. Titanium may be manufactured to have a thickness thinner than that of other glass and ceramic materials because of its greater strength and heat resistance than glass or ceramic substrates, and may reduce thermal and mechanical deformation of the substrate 32.

In order to bond the substrate 32 and the green sheet 30, as shown in FIG. 2B, an inorganic material for glaze is sprayed onto the substrate 32 and then fired at a temperature of 500 to 550 ° C. to glaze. Form layer 34. Subsequently, an organic substance for glue is sprayed on the glaze layer 34 and dried to form a glue layer 36. The glue layer 36 serves as a bonding agent, and the substrate 32 and the green sheet 30 are bonded by a lamination process as shown in FIG. 2C. The lamination process is a process of adhering the substrate 32 and the green sheet 30 while applying a uniform pressure and temperature.

Subsequently, the address electrode 2 is printed on the green sheet 30 as shown in FIG. 2D and then dried.

On the substrate 32 on which the address electrode 2 is formed, as shown in FIG. 2E, the dielectric slurry is printed on the front surface and dried, thereby forming the electrode protective layer 37. Subsequently, an organic binder used as a binder for increasing the fluidity of the green sheet 30 bonded on the substrate 32, for example, poly-vinyl-butiral (hereinafter referred to as "PVB") The temperature is heated to the softening point of).

In the state where the flowability of the green sheet 30 is increased, as shown in FIG. 2F, the mold 38 having the groove 38a having the opposite shape to the partition wall is aligned on the substrate 32.

The mold 38 is pressed onto the substrate 32 at a pressure of about 150 kgf / cm 2 or more as shown in FIG. 2G. When the mold 38 is pressed, the green sheet 30 and the electrode protective layer 37 are moved into the groove 38a of the mold 38 to rise.

After the mold 38 is separated from the green sheet 30 and the electrode protective layer 37 as shown in FIG. 2H, the partition wall 8 is fired while passing through a temperature raising, holding, and cooling zone. In this firing process, after the burnout (Binder burn out) of the organic material in the green sheet 30 is burned out, crystal nuclei are formed and grown on the inorganic materials at a temperature higher than the burnout.

However, the barrier rib manufacturing method using the LTCCM method requires a pressure of 150 kgf / cm 2 or more because of low fluidity when forming the green sheet 30 having a composition ratio as shown in Table 1. In the case of molding at a high pressure as described above, the pressure difference is different between the portion where the pressure is applied on the substrate 32 and the portion that is not. That is, the polarization pressure is generated on the substrate 32, so that the height of the partition wall 8 is not uniform as shown in FIG. In order to make the height of the non-uniform partition 8 uniform, a polishing step is required. In particular, since the fluidity of the green sheet 30 is low during molding, it is difficult to form a partition wall having a high aspect ratio.

Accordingly, it is an object of the present invention to provide a barrier material and barrier rib manufacturing method of PDP which can improve the formability of the barrier rib.

1 is a perspective view showing a surface discharge type plasma display panel of an AC driving method.

2A to 2H are diagrams showing step by step manufacturing methods of a lower panel of a plasma display panel using a conventional LTCCM method.

3 is a view showing the shape before and after firing of the partition wall shown in FIG.

4A to 4H are diagrams illustrating a method of manufacturing a lower plate of a plasma display panel according to an exemplary embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

2, 64 address electrode 4 sustain electrode pair

6: phosphor 8: partition wall

10: protective film 12, 18: dielectric layer

14, 32, 60: lower substrate 16: upper glass substrate

30, 60: green sheet 34: glaze layer

37, 66: electrode protective layer 38, 68: mold

In order to achieve the above object, the partition wall material of the plasma display panel according to the present invention is a plasma display panel having a green sheet for forming a partition wall, ZnO-B ₂ O ₃ -MgO-SiO ₂ and ZnO-B ₂ A green sheet having a composition in which O ₃ -MgO-SiO ₂ -K ₂ O + TiO ₂ is mixed at a predetermined ratio is provided.

PDP bulkhead manufacturing method according to the present invention is a green sheet having a composition in which 27ZnO-32B ₂ O ₃ -18MgO-23SiO ₂ and 27ZnO-23B ₂ O ₃ -28MgO-23SiO ₂ -9K ₂ O + TiO ₂ mixed in a predetermined ratio And forming a barrier rib by pressing a mold having a groove having a barrier rib shape on the green sheet, and forming a barrier rib.

The composition ratio of the composition contained in the green sheet is 10 to 40 (wt%) ZnO, 5 to 35 (wt%) B ₂ O ₃ , 10 to 32 (wt%) MgO, 10 to 35 (wt%) SiO ₂ , 0 to 22 (% by weight) is characterized in that K ₂ O.

In order to make the thermal expansion coefficient of the green sheet and the substrate the same, 0 to 20 (wt%) Ti ₂ O is added to the green sheet.

Other objects and features of the present invention in addition to the above object will become apparent from the description of the embodiments with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described with reference to FIGS. 4A to 4H.

4A to 4H illustrate a method of manufacturing a lower plate of a PDP according to an embodiment of the present invention.

4A to 4H, the green sheet 60 of the PDP according to the present invention is ZnO-B ₂ O ₃ -MgO-SiO ₂ and ZnO-B ₂ O ₃ -MgO-SiO ₂ -K ₂ O + TiO _It has a composition in which ₂ is mixed at a predetermined ratio.

The green sheet 60 having the composition described above has a smaller shrinkage rate than the conventional green sheet 60 and thus does not deform the partition wall shape before and after firing. The dielectric constant of the green sheet 60 has a value of 7.2 to 11. In consideration of the fact that the higher the dielectric constant, the greater the power consumed during discharging, the composition of the green sheet 60 has a suitable dielectric constant. By adjusting the composition ratio of TiO _{2, which} is a composition in the green sheet 60, the coefficient of thermal expansion (hereinafter referred to as “CTE”) of the green sheet 60 and the substrate 62 is the same. Here, 0 to 20 (wt%) TiO _{2 is} used in the green sheet 60. Accordingly, the green sheet 60 is formed to be uniformly matched on the substrate 62. Here, the composition ratio of the composition contained in the green sheet 60 is as shown in Table 1 below.

Composition Composition ratio (wt%) ZnO 10 to 40 B ₂ O ₃ 5 to 35 MgO 10 to 32 SiO ₂ 10 to 35 K ₂ O 0 to 22 TiO ₂ 0 to 20

ZnO can lower the glass softening point and control the CTE. The content of ZnO is selected in the range of 5 to 35wt%, and CTE is excessively reduced when the composition ratio is added at 40wt% or more.

B ₂ O ₃ is a glass forming element for extending the vitrification range of the element and is selected in the range of 10 to 35wt%. When the glass is more than 40wt%, phase separation of the glass produced easily occurs.

In addition, SiO _{2 is} also a glass forming element and is selected from 10 to 35wt%, preferably 15 to 23wt%. If the content is 30wt% or more, the softening point of the glass is excessively increased, so that the viscosity change through the softening point is slowed, so that defoaming is difficult.

K ₂ O lowers the melting point of the glass and adjusts the CTE.

In order to increase the flow temperature of the green sheet 60 having the composition ratio of such an inorganic material, a composition such as Forsterite, Cordierite, ZrO ₂ , and Al ₂ O ₃ may be added.

The green sheet 60 having such a composition is bonded to the substrate 62 by a laminating process. When the green sheet 60 is laminated with the substrate 62, the substrate 62 and the green sheet 60 are bonded to each other under the influence of the organic material contained in the green sheet 60.

Subsequently, the address electrode 64 is printed on the green sheet 60 as shown in FIG. 4D and then dried.

On the substrate 60 on which the address electrode 64 is formed, as shown in FIG. 4E, the dielectric paste is completely printed and then dried to form the electrode protective layer 66. Subsequently, the substrate 62 is heated near the softening point of the organic binder in order to increase the fluidity of the green sheet 60 bonded onto the substrate 62. The composition of Forsterite, Codierite, ZrO ₂ , Al ₂ O _3, etc. is added to the green sheet 60, thereby increasing the flow temperature when using glass powder having a softening point lower than the crystallization temperature. .

In this state in which the fluidity of the green sheet 60 is increased, as shown in FIG. 4F, the mold 68 having the grooves 68a having the opposite shape to the partition wall is aligned on the substrate 62.

The mold 68 is then pressed onto the substrate 62 at approximately a predetermined pressure as shown in FIG. 4G. When the mold 68 is pressed, the green sheet 60 and the electrode protective layer 66 are moved into the grooves 68a of the mold 68 to rise.

This is achieved by using a property that the organic material contained in the green sheet 60 is softened at a predetermined temperature and has a constant adhesiveness.

This is described in detail as follows. The softening point of the inorganic material in the green sheet 60 is determined by observing a change in heat capacity, shrinkage, etc. of the polymer sample with temperature change. For example, 27ZnO-32B ₂ O ₃ -18MgO-23SiO ₂ and 27ZnO-23B ₂ O ₃ -18MgO-23SiO ₂ -9K ₂ O may be mixed in a ratio of 1: 1 or 2: 1 in the green sheet 60. Add. The green sheet 60 having such a composition adheres the green sheet 60 to the substrate 62 by using a property of changing the physical properties of the inorganic material contained in the green sheet 60 according to the temperature. That is, when the inorganic material in the green sheet 60 is softened at a high temperature, the green sheet 60 has strong bonding at the interface with the substrate 62.

After the mold 68 is separated from the green sheet 60 and the electrode protective layer 66 as shown in FIG. 4H, the partition wall is fired while passing through a temperature raising, holding, and cooling zone. This firing process is carried out at a temperature of 700 ~ 850 ℃ to burn off the organic material in the green sheet (60). Thereafter, at the firing temperature, the glass is produced and grown into glass-ceramic.

As described above, the green sheet in the barrier rib material and the barrier rib manufacturing method according to the present invention is ZnO-B ₂ O ₃ -MgO-SiO ₂ and ZnO-B ₂ O ₃ -MgO-SiO ₂ -K ₂ O + TiO _It has a composition in which ₂ is mixed at a predetermined ratio. The green sheet having such a composition can maintain the original partition shape even after firing after partition wall formation. That is, the moldability of a partition can be improved. In the PDP partition material and the method for manufacturing the partition wall according to the present invention, since the upper surface grinding process can be omitted, the process cost can be reduced by simplifying the process. Furthermore, the molded partition can have a high aspect ratio and can improve uniformity.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (7)

In the plasma display panel having a green sheet for forming a partition wall, A plasma display panel comprising a green sheet having a composition in which ZnO-B ₂ O ₃ -MgO-SiO ₂ and ZnO-B ₂ O ₃ -MgO-SiO ₂ -K ₂ O + TiO ₂ are mixed at a predetermined ratio. Bulkhead material. The method of claim 1, The composition contained in the green sheet is 10 to 40 (wt%) ZnO, 5 to 35 (wt%) B ₂ O ₃ , 10 to 32 (wt%) MgO, 10 to 35 (wt%) SiO A barrier material of a plasma display panel comprising ₂ , 0 to 22 (wt%) K ₂ O. The method of claim 1, The green sheet has a composition in which 27ZnO-32B ₂ O ₃ -18MgO-23SiO ₂ and 27ZnO-23B ₂ O ₃ -28MgO-23SiO ₂ -9K ₂ O + TiO ₂ are mixed at a predetermined ratio. Bulkhead material. The method of claim 1, A barrier material of a plasma display panel, wherein 0 to 20 (wt%) of Ti ₂ O is added to the green sheet so that the thermal expansion coefficient of the green sheet and the substrate are the same. Forming a green sheet having a composition in which 27ZnO-32B ₂ O ₃ -18MgO-23SiO ₂ and 27ZnO-23B ₂ O ₃ -28MgO-23SiO ₂ -9K ₂ O + TiO ₂ are mixed at a predetermined ratio; Adhering the green sheet to a substrate; And forming a barrier rib by pressing a mold having a groove having a barrier rib shape on the green sheet, thereby forming a barrier rib. The method of claim 5, The composition ratio of the composition contained in the green sheet is 10 to 40 (wt%) ZnO, 5 to 35 (wt%) B ₂ O ₃ , 10 to 32 (wt%) MgO, 10 to 35 (wt%) The SiO ₂ , 0 ~ 22 (wt%) of K ₂ O characterized in that the plasma display panel partition wall manufacturing method. The method of claim 5, And adding 0 to 20 (wt%) Ti ₂ O in the green sheet to equalize the thermal expansion coefficient of the green sheet and the substrate.