KR100670292B1 - Plasma display panel - Google Patents

Abstract

An object of the present invention is to provide a plasma display panel having a structure that can significantly improve the aperture ratio and transmittance as compared to the conventional plasma display panel and at the same time ensure stable discharge in the discharge space and secure the required voltage margin. In order to achieve this object, the present invention comprises: a front substrate and a rear substrate disposed facing each other; A first partition wall disposed between the front substrate and the rear substrate to form a plurality of corner portions, the discharge cell partitioning the discharge cells together with the front substrate and the rear substrate; First electrodes arranged in the first partition wall to surround the first corner part for each discharge cell; Second electrodes arranged in parallel with the first electrodes in a first partition wall so as to surround the second corner part facing the first corner part for each discharge cell, the second electrodes having a predetermined gap from the first electrodes; A phosphor layer disposed in the discharge cell; And a discharge gas in the discharge cell, wherein at least one of the first electrodes and the second electrodes has a gap adjacent portion having a discharge cross section smaller than a body of an electrode corresponding to an end adjacent to the gap. do.

Description

Plasma display panel {Plasma display panel}

1 is an exploded perspective view of a conventional plasma display panel according to the related art;

2 is an exploded perspective view illustrating a plasma display panel according to an embodiment of the present invention;

3 is a plan view illustrating the relationship between the electrodes in the discharge cell of FIG.

4 is a perspective view illustrating a relationship between a first electrode, a second electrode, and an address electrode of FIG. 2;

FIG. 5 is a perspective view illustrating a state in which sustain discharge starts and is generated in one discharge cell of FIG. 2;

FIG. 6A is a side view illustrating the side surface of the electrode in the direction A of FIG. 4;

FIG. 6B is a first modification of FIG. 6A, and

FIG. 6C is a second modification of FIG. 6A, and

7 is a cross-sectional view taken along the line VII-VII of FIG. 3 in order to explain the address discharge of the present invention;

8 to 10 are plan views illustrating the sustain discharge of the present invention.

Explanation of symbols on the main parts of the drawings

100: plasma display panel 120: front substrate

123: gap adjacent portion 127: first partition wall

130: rear substrate 130r: rear substrate

133: address electrode 136: dielectric layer

137: second partition 139: phosphor layer

140: first electrode 150: second electrode

141: first base 142: first protrusion

143: first gap adjacent portion 151: second base portion

152: second protrusion 153: second gap adjacent portion

C: discharge cell

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel that expresses a character or an image by using gas discharge. More particularly, the present invention relates to a plasma display panel capable of low voltage driving, an enlarged surface of a discharge, and an improved aperture ratio. It is about.

Recently, a device employing a plasma display panel as a flat panel display device has a large screen, and has excellent characteristics of high definition, ultra-thin, light weight, and wide viewing angle, and has a simpler manufacturing method and easier size than other flat panel display devices. It is in the spotlight as the next generation large flat panel display device.

The plasma display panel is classified into a direct current (DC) type, an alternating current (AC) type, and a hybrid type according to an applied discharge voltage, and classified into a counter discharge type and a surface discharge type according to a discharge structure.

In the DC plasma display panel, all electrodes are exposed to a discharge space, and charges are directly transferred between the corresponding electrodes. In the AC plasma display panel, at least one electrode is surrounded by a dielectric layer, and discharge is performed by an electric field of wall charge instead of direct charge transfer between the corresponding electrodes.

In the DC plasma display panel, since the charge is directly transferred between the corresponding electrodes, there is a problem in that the electrode is severely damaged. In recent years, an AC plasma display panel having an AC type, in particular, a three-electrode surface discharge structure is present. This has been generally employed.

The conventional surface discharge plasma display panel 10 including the AC three-electrode surface discharge plasma display panel includes a front substrate 20 and a rear substrate 30 as shown in FIG. 1.

The rear substrate 30 includes an address electrode 33 for generating an address discharge, a rear dielectric layer 35 embedding the address electrode, a partition wall 37 partitioning discharge cells, and both sides of the partition wall and the partition wall. The phosphor layer 39 applied to the back substrate which is not formed is formed.

The front substrate disposed to face the rear substrate so as to be spaced apart from each other, the front and rear dielectric layers 25 having the X and Y electrodes 22 and 23 generating a sustain discharge, and the X and Y electrodes 22 and 23 embedded therein; The protective film 29 is provided.

However, in the conventional plasma display panel, first, the transparent X electrode 22a and one side of the transparent X electrode are disposed on the front substrate 20 through which visible light emitted from the phosphor layer 39 in the discharge space passes. Y electrode 23 normally provided with an X electrode 22 having a bus X electrode 22b, and a bus Y electrode 23b disposed on one side of the transparent Y electrode 23a and the transparent Y electrode 23a. ), A front dielectric layer 27, and a protective film 29 formed sequentially on the X and Y electrodes. These factors have a serious problem that the visible light transmittance of about 60%.

Second, in the conventional surface discharge plasma display panel 10, the electrode which causes the discharge is formed on the upper surface of the discharge space, that is, the inner surface of the front substrate 20 through which visible light passes, so that the discharge occurs on the inner surface and diffuses. Therefore, there is an inherent problem of low luminous efficiency.

Third, the conventional surface discharge plasma display panel 10 has a problem that, when used for a long time, the charged particles of the discharge gas causes ion sputtering on the phosphor by an electric field, causing permanent afterimage.

SUMMARY OF THE INVENTION The present invention solves the above problems, and provides a plasma display panel that can dramatically increase the discharge area and transmittance as compared to the conventional plasma display panel, and can significantly expand the discharge area by greatly expanding the discharge surface. will be.

Another object of the present invention is to provide a plasma display panel having a structure in which stable discharge is performed in a discharge space and a required voltage margin is secured.

Another object of the present invention is to concentrate the plasma by the discharge to a predetermined portion of the discharge space, for example, the center portion, to efficiently use the space charge of the plasma, it is possible to drive low voltage, and to significantly improve the luminous efficiency It is to provide a plasma display panel.

In order to achieve the above object, a plasma display panel according to a first embodiment of the present invention is:

A front substrate and a rear substrate disposed to face each other;

A first partition wall disposed between the front substrate and the rear substrate to form a plurality of corner portions, the discharge cells partitioning discharge cells together with the front substrate and the rear substrate;

First electrodes arranged in a first partition wall to surround a first corner part for each of the discharge cells;

A second electrode disposed in parallel with the first electrodes in the first partition wall so as to surround the second corner part facing the first corner part for each of the discharge cells, and having a predetermined gap with the first electrodes; field;

A phosphor layer disposed in the discharge cell; And

And a discharge gas in the discharge cell,

At least one of the first and second electrodes may have a gap adjacent portion having a discharge cross-sectional area smaller than a body of the corresponding electrode at an end adjacent to the gap.

In this case, it is preferable that the height of the gap adjacent portion is smaller than the body of the first or second electrodes connected thereto.

In this case, the gap adjacent portion is preferably rounded at its ends.

Meanwhile, the plasma display panel according to the second embodiment of the present invention is:

A front substrate and a rear substrate disposed to face each other;

A first partition wall disposed between the front substrate and the rear substrate to form a plurality of corner portions, the discharge cells partitioning discharge cells together with the front substrate and the rear substrate;

A first base part disposed in the first partition wall and extending in one direction for each of the discharge cells, a first protrusion and a first protrusion protruding from the first base part in the first corner part for each of the discharge cells; First electrodes having a first gap adjacent portion extending from the first gap and having a height smaller than that of the first protrusion;

A second base part disposed in the first partition wall and arranged to be spaced apart in a direction parallel to the first base part for each of the discharge cells, and a second corner part facing the first corner part for each of the discharge cells; Second electrodes having a second gap projecting from a base and a second gap adjacent portion extending from the second projecting portion and having a height smaller than that of the second projecting portion;

A phosphor layer disposed in the discharge cell; And

And a discharge gas in the discharge cell.

Here, it is preferable to further include address electrodes arranged to extend in a direction crossing the direction in which the first electrode and the second electrode extend, wherein the address electrode is disposed between the back substrate and the phosphor layer, and the phosphor It is preferable that a dielectric layer filling the address electrode is disposed between the layer and the address electrode.

In addition, a second partition wall is formed between the first partition wall and the rear substrate to partition the discharge cell together with the first partition wall, and the phosphor layer includes a dielectric layer on which side surfaces of the second partition wall and the second partition wall are not formed. It is preferable that it is formed in the upper surface.

Next, a plasma display panel according to a preferred embodiment of the present invention will be described in detail with reference to the drawings.

2 to 4, the plasma display panel 100 according to the embodiment of the present invention includes a front substrate 120, a rear substrate 130, a first partition 127, a first electrode 140, The phosphor layer 139 and a discharge gas.

The transparent front substrate 120 is disposed in parallel with the rear substrate 130 so that visible light passes and the image is projected. A first partition 127 is formed between the front substrate 120 and the rear substrate 130. The first partition wall 127 is disposed in the non-discharge unit to partition the discharge cell (C). The first partition wall 127 has a first corner portion 127a forming a corner of the discharge cell C, a second corner portion 127b facing the first corner portion 127a in a diagonal direction, and a discharge, respectively. Corner parts 127c and 127d are provided.

The discharge cell C is disposed in a sub-pixel in which a red discharge cell is disposed in a subpixel on which a red phosphor layer 139R emitting red visible light is formed, and a green phosphor layer 139G in which green visible light is emitted. One of the green discharge cells and the blue discharge cells disposed in the sub-pixels on which the blue phosphor layer 139B emitting blue visible light is formed. The discharge cell C is a space for generating a discharge and generating light to implement an image.

In the first partition 127, the first electrode 140 and the second electrode 150 extend in one direction for each discharge cell. The first electrode 140 is disposed in the first partition wall 127 so as to surround the first corner portion 127a for each of the discharge cells C. In addition, the second electrode 150 has a constant gap G with the first electrodes so as to surround the second corner part 127b facing the first corner part 127a for each of the discharge cells C. Placed side by side to have.

In this case, at least one of the first electrodes 140 and the second electrodes 150 has a gap adjacent portion 123 having a discharge cross-sectional area smaller than that of the electrodes main body at an end adjacent to the gap G. do.

If the discharge cross-sectional area is small in the gap adjacent portion 123, the electrical resistance increases. As a result, the current flows in the gap adjacent portion 123 smaller than that of the main body of the electrodes, thereby causing a voltage drop. Because of this, as will be described later, a stable discharge can be realized by smoothly and quickly spreading the discharge from the gap adjacent part 123 toward the main body.

In this case, in order to make the discharge cross-sectional area of the gap adjacent portion 123 smaller than the main body of the electrodes having the same, the height H1 of the gap adjacent portion may be lower than the height H2 of the main body.

For example, the first electrode 140 may include a first base 141, a first protrusion 142, and a first gap adjacent part 143. The first base part 141 is disposed to extend in one direction, for example, the x axis direction in each of the discharge cells C, and the first protrusion part 142 is discharged at the first corner part 127a. Each cell protrudes from the first base 141 in the y-axis direction, for example. The first gap adjacent part 143 extends from the first protrusion part 142 and has a constant gap G1 with the second base part 151 of the second electrodes 150, the height H1 of which is defined as the first gap part 142. It is formed so that it is smaller than the height H2 of 1 protrusion.

The second electrode 150 includes a second base portion 151, a second protrusion portion 152, and a second gap adjacent portion 153. The second base part 151 is disposed in the first partition wall and extends in a direction parallel to the first base part 141 in one discharge cell, for example, in the x axis direction in the drawing, and the second protrusion part 152. ) Projects from the second base portion 151 at the second corner portion 127b facing the first corner portion 127a, for example, in the y-axis direction. The second gap adjacent portion 153 extends from the second protrusion 152 and has a first gap 141 and a constant gap G2 of the first electrodes 140. It is formed to be smaller than the height (H2) of the second protrusion.

In particular, as shown in FIG. 3, the first partition 127 has a second corner facing the first corner portion 127a and the first corner portion 127a which form an edge of the discharge cell C in a diagonal direction. The part 127b and discharge corner parts 127c and 127d are provided. In this case, in one discharge cell, the first electrode 140 is arranged to surround the first corner portion 127a of the first partition wall, and the second electrode 150 is disposed with the first corner portion 127a. The second corner portion 127b of the first partition wall facing in a diagonal direction is disposed to surround.

Meanwhile, the present invention further includes address electrodes 133, which may be stacked on the front surface 130f of the rear substrate. In this case, in the drawing, the address electrodes 133 extend to intersect the first and second electrodes 140 and 150, and may extend in the y-axis direction across the discharge cells C. The address electrodes may be formed in the dielectric layer. 136 may be covered.

In this case, in particular, as shown in FIG. 4, the first base part 141 and the second base part 151 extend in one direction in parallel with each other, and the address electrode 133 is formed of the first and second base parts 141. , 151 is formed to cross the direction in which it extends. The extension of the first and second base portions 141 and 151 to intersect the address electrode 133 means that the column of discharge cells C through which the address electrode 133 passes and the second electrode 150 pass through the first and second base portions 141 and 151 cross each other. This means that the columns of the discharge cells C cross each other. In addition, the first electrode 140 extends in parallel with the second electrode 150, which means that the first electrode 140 is disposed together at a predetermined interval from the second electrode 150.

In the present exemplary embodiment, the first electrode 140, the second electrode 150, and the address electrode 133 are disposed to surround the upper side of the discharge cell C. The upper side of the discharge cell means a portion higher than the second partition wall 137.

The first electrode 140 and the second electrode 150 provided in the present invention are not disposed at the center of the discharge cell (C). Therefore, the cross-sectional area of the AC plasma display panel 10 having the three-electrode surface discharge structure can be larger than that of the X electrode and the Y electrode. As the cross-sectional area of the electrode increases, a large amount of current flows, and as the amount of current increases, power consumption and discharge amount increase. Therefore, a strong discharge occurs between the first electrode 140 and the second electrode 150.

If excessively strong discharge occurs between the first gap adjacent portion 143 and the second base portion 151 and the voltage of the first protrusion portion is equal to the voltage of the first gap adjacent portion, to spread it across the electrode, An additional voltage application is required, which is disadvantageous in securing a voltage margin, thus forming an unstable discharge state.

In detail, the sustain discharge occurring between the first electrode 140 and the second electrode 150 starts first at the place having the smallest gap between the first electrode 140 and the second electrode 150. do. Therefore, a sustain discharge occurs first between the first gap adjacent portion 143 and the second base portion 151 and between the second gap adjacent portion 153 and the first base portion 141, and gradually the first protrusion 142 is formed. And the discharge discharge between the second base 151 and the second protrusion 152 and the first base 141. In this case, the first and second protrusions 142 and 152 and the first and second base portions 141 and 151 are electrode bodies, and the first and second gap adjacent portions 143 and 153 are gap adjacent portions 123.

The diffusion of the sustain discharge occurring between the first gap adjacent portion 143 and the second base portion 151 and the diffusion of the sustain discharge occurring between the second gap adjacent portion 153 and the first base portion 141 are symmetric with each other. Will occur.

Therefore, in FIG. 5, only the diffusion of the sustain discharge occurring between the first gap adjacent portion 143 and the second base portion 151 will be described. As shown in FIG. 5, according to Gauss' law, a sustain discharge occurs first between the first gap adjacent portion 143 and the second base portion 151 located at the most adjacent distances from each other. This causes ions to move between these first gap adjacent portions and the second base portion and generate wall charges on the first partition wall.

In this case, the height of the first gap adjacent portion 143 is formed smaller than the height of the first protrusion 151. Therefore, the discharge generated in this part becomes relatively weak discharge.

After that, the sustain discharge is gradually spread between the first protrusion 142 and the second base 151. In this case, if the voltage of the first protrusion 142 and the voltage of the first gap adjacent part 143 are the same, In the first gap adjacent portion 143 located close to the base portion 151, the sustain discharge occurs in the gap portion until the discharge becomes saturated, and the rate of diffusion of the sustain discharge into the first protrusion 142 is slowed. . Therefore, to prevent this, it is necessary to apply an additional voltage.

However, in the present invention, the discharge area of the first gap adjacent portion 143 is smaller than that of the first protrusion portion 142, thereby increasing the battery resistance in the first gap adjacent portion 143, and consequently, the first gap adjacent portion. The voltage drop at 143 becomes large. Therefore, since the voltage of the first protrusion 142 is greater than the voltage of the first gap adjacent part 143, it is unnecessary to apply additional voltage, thereby sufficiently securing the voltage margin.

In addition, the speed at which the sustain discharge spreads from the first gap adjacent part 143 to the first protrusion 142 is increased. Therefore, the discharge spreads quickly to a large area of the discharge region, so that excessive sustain discharge does not occur at the corner portion, thereby forming a stable discharge state.

In the present invention, as shown in FIGS. 2 to 6A, the gap adjacent portions 123 such as the first and second gap adjacent portions 143 and 153 may have the same height. Alternatively, however, as shown in FIG. 2, the gap adjacent portions 123 such as the first and second gap adjacent portions 143 and 153 may have a shape that gradually increases from the end portion 123a to the main body. The voltage drop also decreases gradually from the gap adjacent part 123 toward the main body, so that the diffusion rate of the sustain discharge can be constant.

On the other hand, as shown in Figure 6c, it is preferable to form the edge (123a) so that the edges of the gap adjacent portion 123, such as the first, second gap adjacent portion (143, 153) is rounded so as not to occur However, the first partition wall covering them between the first gap adjacent portion 143 and the second base portion 151 and between the second gap adjacent portion 153 and the first base portion 141 shown in FIG. This is because the 127 can be prevented from being damaged by edge-curl phenomena.

Meanwhile, the front substrate 120 and the rear substrate 130 are generally formed of glass, and the front substrate 120 is preferably formed of a material having high light transmittance.

The first partition wall 127 disposed between the front substrate 120 and the rear substrate 130 is formed to define the discharge cells C together with the front substrate 120 and the rear substrate 130.

First and second electrodes 140 and 150 are disposed in the first partition 127, and discharge occurs because a potential is applied to the discharge electrode, so that the first partition 127 is connected to the discharge electrode. The electric field formed by the applied potential must be formed of a dielectric so that it can be transferred into the discharge cell by the molecular arrangement of the first barrier material.

In this case, the first partition wall 127 may be formed of a glass component including elements such as Pb, B, Si, Al, and O, and the like, and, if necessary, ZrO ₂ , TiO ₂ , and Al ₂ O 3. It may be formed of a dielectric including a filler (filler) and pigments such as Cr, Cu, Co, Fe, TiO _2, etc. The dielectric induces charged particles by the potential applied to the discharge electrode to participate in the discharge Induces wall charge, and protects the discharge electrodes.

After forming the first partition 127, it is preferable to form the passivation layer 129 on the side surface of the first partition by deposition or the like. The protective layer protects the first electrode and the second electrode 150 and the first partition 127 covering the discharge electrode, and emits secondary electrons during discharge to facilitate discharge. In the process of forming the passivation layer 129, a passivation layer may be formed on the rear surface 120r of the front substrate and the back surface of the first partition wall. However, the protective film formed on the rear surface 120r of the front substrate and the rear surface of the first partition wall does not significantly affect the present invention.

The second partition 137 may be formed between the dielectric layer 136 and the first partition 127. In this case, the second partition 137 may also be formed of a glass component including elements such as Pb, B, Si, Al, and O, such as the first partition, and, if necessary, ZrO ₂ Fillers such as, TiO ₂ , and Al ₂ O ₃ and pigments such as Cr, Cu, Co, Fe, TiO ₂ may be included.

The second partition 137 is secured to the space to which the phosphor layer 139 can be applied, and is filled in the front substrate 120 and the rear substrate 130 together with the first partition 127. It supports the pressure generated due to the vacuum state of the discharge gas (for example, 0.5 atm), secures the space of the discharge cell (C), and serves to prevent cross talk between the discharge cells. Can be. In addition, the second partition wall may include a reflective material so that visible light generated from the discharge cell may be reflected forward. The second partition wall 137 prevents an erroneous discharge between the discharge cells (C).

In FIG. 2, the second partition wall 137 partitions the discharge cells in a matrix form, but is not limited thereto. The second partition wall 137 may be partitioned into other shapes such as a honeycomb form. In addition, although the cross section of the discharge cell C defined by the second partition 137 is illustrated in FIG. Can be formed.

As the discharge gas charged in the discharge cell, a penning mixture such as Xe-Ne, Xe-He, Xe-Ne-He, etc. is used. The reason why Xe is used as the main discharge gas is that because Xe is a chemically stable inert gas, it is not dissociated due to discharge, but because the atomic number is large, the excitation voltage is lowered and the wavelength of light emitted is increased. to be. The reason for using He or Ne as a buffer gas is because the voltage reduction effect due to the panning effect due to Xe and the sputtering effect due to the high pressure are reduced. The main discharge gas may be a rare gas such as Kr in addition to Xe.

As described above, the phosphor layer 139 may be roughly classified into a red phosphor layer 139R, a green phosphor layer 139G, and a blue phosphor layer 139B according to the color of visible light emitted. The red phosphor layer 139R is formed to include phosphors such as Y (V, P) O ₄ : Eu and the like, and the green phosphor layer 139G includes phosphors such as Zn ₂ SiO ₄ : Mn and YBO ₃ : Tb. The blue phosphor layer 139B may be formed to include a phosphor such as BAM: Eu.

In the discharge cell C of the front substrate 120 employed in the plasma display panel 100 according to the present invention, an indium tin oxide (ITO) film existing on the front substrate of the conventional plasma display panel shown in FIG. A front dielectric layer 27 covering the transparent Y electrode 23a and the transparent X electrode 22a, the bus X electrode and the bus Y electrode 22b and 23b formed of metal, and the electrodes 22a, 22b, 23a and 23b. ) And the protective film 29 do not exist, so that the front transmittance of visible light is remarkably improved from about 60% to about 90%. Therefore, when the image is implemented with the luminance of the conventional level, the electrodes 140 and 150 are driven at a relatively low voltage, thereby improving luminous efficiency.

In this case, since the first electrode 140 and the second electrode 150 serving as the X electrode and the Y electrode, respectively, are not disposed on the front substrate 120 through which visible light is transmitted, they are disposed on the side of the discharge space. Since a low resistance electrode such as a metal electrode can be used as a discharge electrode without using a transparent electrode having a high resistance as a discharge electrode, the discharge response speed is increased and low voltage driving can be performed without distortion of the waveform.

In addition, since the discharge path of the ions between the X and Y electrodes 140 and 150 is formed in parallel with the phosphor layer 139, the rate at which the phosphor layer 139 is damaged during the sustain discharge is compared with the conventional plasma display panel. This is less.

Hereinafter, a driving method of the plasma display panel having the above configuration will be described. When an address voltage is applied between the address electrode 133 and the second electrode 150, an address discharge occurs, and as a result of the address discharge, a discharge cell C in which sustain discharge occurs is selected.

Thereafter, when a sustain discharge voltage of AC is applied between the second electrode 150 and the first electrode 140 of the selected discharge cell, a sustain discharge occurs between the second electrode 150 and the first electrode 140, Ultraviolet rays are emitted while the energy level of the discharged gas excited by this sustain discharge is lowered. The ultraviolet light excites the phosphor layer 139 coated in the discharge cell. The energy level of the excited phosphor layer 139 is lowered to emit visible light, and the emitted visible light forms an image.

This will be described in detail with reference to FIGS. 7 to 10. In this case, as shown in FIG. 4, since the address discharge is disposed so that the first electrode 140 and the second electrode 150 cross the address electrode 133, the first electrode 140 and the address electrode ( 133 or the second electrode 212 and the address electrode 133, but it is assumed here that an address discharge occurs between the second electrode 150 and the address electrode 133.

As shown in FIG. 7, a predetermined pulse voltage is applied between the address electrode 133 and the second electrode 150 from an external power source so that the second electrode 150 and the address electrode 133 cross each other. The discharge cell C to be emitted is selected, and the selected discharge cell is discharged while the potential difference applied to the second electrode 150 and the address electrode 133 reaches a firing voltage, thereby The wall charges are accumulated on the inner side of the discharge cell.

8 to 10, a sustain discharge of the plasma display panel according to the embodiment of the present invention will be described by way of example. In general, sustain discharge means that in a discharge cell selected by an address discharge, a potential is applied to the sustain electrode pairs alternately a specific number of times to display a specific gray level, so that predetermined visible light is emitted from the discharge cell. As is the discharge of the step of implementing the image on the panel. At this time, in the sustain discharge, when a potential is applied to a plurality of sustain electrode pairs arranged in all the discharge cells alternately to form a voltage lower than the discharge start voltage, wall charges are accumulated only in the discharge cells in which the address discharge has occurred. As the potential difference formed by the wall charge and the sustain electrode pair is added to exceed the discharge start voltage, discharge occurs only in the discharge cell in which the address discharge has occurred, thereby generating visible light.

Referring to FIG. 7 to describe such sustain discharge, positive wall charges are stored on the inner side of the discharge cell in which the first electrode 140 is disposed, in more detail, than the inner side of the discharge cell by the address discharge. Negative wall charges are accumulated on the second electrode 150. In this case, a negative potential is applied to the first electrode 140 and a positive potential is applied to the second electrode 150.

Then, as shown in FIG. 8, a predetermined potential difference occurs as a positive potential is applied to the first electrode 140 and a negative potential is applied to the second electrode 150. The dielectric of the one partition 127 is polarized, whereby an electric field is formed inside the discharge cell C. At this time, according to the Gauss law, since the equipotential surface is formed on the surface of the conductor to which the same potential is applied, the same equipotential surface corresponding to the potential applied to the first electrode is formed on the entire first electrode surface, and the second electrode The same equipotential surface corresponding to the potential applied to the second electrode is formed on the entire surface.

In this case, the first electrode 140 is disposed to surround the first corner portion 127a of the first partition wall 127 in one discharge cell, and the second electrode 150 is disposed in the first corner portion (1). Since it is arranged to surround the second corner portion 127b of the partition facing the diagonal direction 127a), the magnitude of the electric field around the first corner portion 127a of the discharge cell wrapped around the first electrode is Electric fields of substantially the same size are formed, and electric fields of the same size are formed around the second corner portion 127b of the discharge cell for the same reason. On the other hand, in the other corner portions 127c and 127d of the discharge cell except for the first corner portion 127a and the second corner portion 127b, hereinafter referred to as discharge corner portions, between the first electrode and the second electrode. A strong magnitude electric field is formed from the first electrode to the second electrode due to the potential difference generated according to the applied potential.

In addition, as the distance from the discharge corners 127c and 127d toward the center of the discharge cell C decreases, the size of the electric field decreases. This can easily be confirmed by the physical law that the magnitude of the electric field is proportional to the magnitude of the potential difference and inversely proportional to the spaced distance between the points where the potential is applied. At this time, the discharge starts in a portion where the electric field is relatively strong, and the discharge extends to a portion where the electric field is relatively weak. Therefore, the discharge starts at the discharge corner and extends toward the center of the discharge cell.

Based on this reason, the wall charges stored in the discharge corners are moved along the direction of the electric field by the strong electric field formed in the discharge corners, and the discharge gas atoms and the walls in the discharge cells are moved by the movement of the wall charges. As the charges collide, the collision with the discharge gas due to the movement of the wall charges extends toward the center of the discharge cell C as shown in FIG. 9, and the energy level of the discharge gas inside the discharge cell is increased at a low energy level. Will be excited at a high energy level. The energy level of the excited discharge gas is changed from the high energy level to the low energy level, thereby generating ultraviolet rays having a predetermined wavelength.

In the present invention, the heights of the first gap adjacent portion 143 and the second gap adjacent portion 153 are lower than that of the first protrusion 142 and the second protrusion 152, respectively. As a result, voltage drops occur in the first and second gap adjacent portions 143 and 153. In addition, the discharge cross-sectional area is reduced, and as a result, between the first gap adjacent portion 143 and the second base portion 151 and the second gap adjacent portion 153 respectively disposed with a constant gap G1 (G2) therebetween. And relatively weak discharge occurs between the first base portion 141 and the first base portion 141. As a result, a discharge region is formed from the first and second gap adjacent portions 143 and 153 toward the first and second protrusion portions 142 and 152 having a voltage higher than that of the first and second gap adjacent portions 143 and 153. Diffuses quickly, resulting in stable discharge.

The ultraviolet light excites the phosphor layer 139 disposed in the discharge cell, more specifically, in the space defined by the second partition 137 and the dielectric layer 136, from a low energy level to a high energy level. In addition, the phosphor layer 139 changes from a high energy level to a low energy level, thereby generating predetermined visible light.

On the other hand, if the voltage difference between the first electrode 140 and the second electrode 150 is lower than the discharge voltage after the discharge is formed, the discharge is no longer generated, the space charge and the wall charge is discharge cell (C) Is formed. At this time, when the polarity of the pulse voltage between the discharge electrodes is changed and a voltage lower than the applied voltage is applied, the discharge starting voltage is reached again with the help of the wall charge, and the discharge is generated again. If the potential of the pulse voltage is alternately applied between the first electrode 140 and the second electrode 150 repeatedly, the discharge is maintained. In addition, a predetermined visible light is generated as many times as the number of discharges in the phosphor layer due to the potentials applied to the first electrode 140 and the second electrode 150 alternately, thereby displaying a predetermined gray scale on the screen. . Through such a sustain discharge, a desired image can be finally realized on the plasma display panel. On the other hand, this driving example is only one example of the driving method of the first embodiment of the present invention, the description of the driving method described above does not limit or limit the features of the present invention.

According to the plasma display panel having the above structure, first, since there is no other element other than the substrate in the portion of the front substrate through which visible light passes, the aperture ratio can be significantly improved, and the transmittance can be improved at 60% or less. Up to about 90%.

Second, since the speed of diffusion into the discharge region during sustain discharge is fast and weak discharge is possible in the gap portion, a stable discharge state is formed, which results in a long lifetime of the panel.

Third, even when a high concentration of Xe gas is used as the discharge gas, the luminous efficiency can be improved. When using a high concentration of Xe gas as a discharge gas in order to increase the luminous efficiency, it is difficult to drive a low voltage, the low voltage can be driven as described above in the plasma display panel of the present invention, even when using a high concentration of Xe gas as a discharge gas It becomes possible to drive and can improve luminous efficiency.

Fourth, the discharge response speed is high and low voltage driving is possible. In the plasma display panel and the flat panel display device having the same according to the present invention, since the discharge electrode is not disposed on the front substrate through which visible light is transmitted, the discharge electrode is disposed on the side of the discharge space. Therefore, it is necessary to use a transparent electrode having high resistance as the discharge electrode. Since a low-resistance electrode such as a metal electrode can be used as the discharge electrode, the discharge response speed is high, and low-voltage driving is possible without distortion of the waveform.

In addition, as the structure of the plasma display panel is drastically changed as compared with the related art, the discharge region is greatly enlarged, and the amount of plasma is greatly increased to emit a lot of ultraviolet rays.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (11)

A front substrate and a rear substrate disposed to face each other; A first partition wall disposed between the front substrate and the rear substrate to form a plurality of corner portions, the discharge cells partitioning discharge cells together with the front substrate and the rear substrate; First electrodes arranged in a first partition wall to surround a first corner part for each of the discharge cells; A second electrode disposed in parallel with the first electrodes in the first partition wall so as to surround the second corner part facing the first corner part for each of the discharge cells, and having a predetermined gap with the first electrodes; field; A phosphor layer disposed in the discharge cell; And And a discharge gas in the discharge cell, And at least one of the first electrodes and the second electrodes has a gap adjacent portion having a discharge cross-sectional area smaller than a main body of the corresponding electrode at an end adjacent to the gap. The method of claim 1, And the height of the adjacent portion of the gap is smaller than that of the first or second electrodes connected thereto. The method of claim 2, And the height of the adjacent portion of the gap increases from the end toward the first electrode body or the second electrode body connected thereto. The method of claim 2, And the gap adjacent portion is rounded at an end thereof. A front substrate and a rear substrate disposed to face each other; A first partition wall disposed between the front substrate and the rear substrate to form a plurality of corner portions, the discharge cells partitioning discharge cells together with the front substrate and the rear substrate; A first base part disposed in the first partition wall and extending in one direction for each of the discharge cells, a first protrusion and a first protrusion protruding from the first base part in the first corner part for each of the discharge cells; First electrodes having a first gap adjacent portion extending from the first gap and having a height smaller than that of the first protrusion; A second base part disposed in the first partition wall, the second base part being disposed to be spaced apart in a direction parallel to the first base part for each of the discharge cells, and a second corner part facing the first corner part for each of the discharge cells; Second electrodes having a second protrusion protruding from a second base and a second gap adjacent portion extending from the second protrusion and having a height smaller than that of the second protrusion; A phosphor layer disposed in the discharge cell; And And a discharge gas in the discharge cell. The method of claim 5, And the height of the first gap adjacent portion increases in the direction of the first protrusion from the end thereof, and the height of the second gap adjacent portion increases in the direction of the second protrusion from the end thereof. The method of claim 5, And an end portion of the first gap adjacent portion and the second gap adjacent portion is rounded. The method according to any one of claims 1 to 7, And a plurality of address electrodes arranged to extend in a direction crossing the direction in which the first electrode and the second electrode extend. The method of claim 8, And the address electrode is disposed between the rear substrate and the phosphor layer, and a dielectric layer filling the address electrode is disposed between the phosphor layer and the address electrode. The method according to any one of claims 1 to 7, And at least a side surface of the first partition wall is covered by a protective film. The method according to any one of claims 1 to 7, A second partition wall is formed between the first partition wall and the rear substrate to partition the discharge cell together with the first partition wall. And the phosphor layer is formed on a side surface of the second partition wall and an upper surface of the dielectric layer on which the second partition wall is not formed.

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