KR20060094284A - A plasma display panel and driving method of the same - Google Patents

Abstract

The plasma display panel of the present invention is to reduce the discharge start voltage, shorten the reset period and the addressing period to improve gray scale expressive power, and includes a plurality of discharge spaces adjacent to the first substrate, the second substrate, and adjacent to the first substrate. A first partition wall layer partitioning a second partition wall, a second partition wall layer partitioning a discharge space facing the discharge space adjacent to the second substrate, a phosphor layer formed inside discharge cells formed by the both discharge spaces, and Between each of the first and second barrier rib layers, an expansion portion disposed alternately on both sides of the discharge cell and shared by other discharge cells adjacent to each side and extending in a direction perpendicular to the substrate plane, respectively; Between the 1st electrode and the 2nd electrode, and the said 1st partition wall layer and the 2nd partition wall layer, it is piled on one side of this 1st partition wall layer side and the 2nd partition wall layer side by side, And a first address electrode and a second address electrode each having a protrusion extending in a direction crossing the first electrode and the second electrode and alternately disposed in discharge cells disposed along the extension direction. do.

Plasma, display, opposite discharge, address electrode, protrusion, reset period, addressing period

Description

Plasma Display Panel and Driving Method {A PLASMA DISPLAY PANEL AND DRIVING METHOD OF THE SAME}

1 is a partially exploded perspective view illustrating a plasma display panel according to a first embodiment of the present invention.

2 is a partial plan view schematically illustrating a structure of an electrode and a discharge cell in a plasma display panel according to a first embodiment of the present invention.

FIG. 3 is a partial cross-sectional view of the plasma display panel of FIG. 1 taken along a line A-A.

4 is a partial perspective view schematically illustrating a structure of an electrode in a plasma display panel according to a first embodiment of the present invention.

FIG. 5 is a schematic diagram illustrating a connection relationship between a first address electrode and a second address electrode and respective drivers of a plasma display panel according to a first embodiment of the present invention.

6 is a driving waveform diagram of a method of driving a plasma display panel according to a first embodiment of the present invention.

7 to 9 are partial cross-sectional views of the plasma display panel according to the second to fourth embodiments of the present invention.

10 is a partial cutaway view of a plasma display panel according to a fifth embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel and a driving method thereof, and more particularly, to a plasma display panel and a driving method thereof for lowering a discharge start voltage and shortening a reset period and an addressing period to improve gray scale expression.

A typical plasma display panel (hereinafter referred to as 'PDP') includes a three-electrode surface discharge type PDP. The three-electrode surface discharge type PDP consists of a substrate including sustain electrodes and scan electrodes located on the same surface, and another substrate including address electrodes extending in a vertical direction spaced apart from the substrate by a predetermined distance therebetween, and discharging a discharge gas therebetween. Doing. In this PDP, the presence or absence of discharge is determined by the discharge of the scan electrode and the address electrode independently connected to each line, and the sustain discharge displaying the screen is made by the sustain electrode and the scan electrode located on the same plane.

PDP uses glow discharge to generate visible light, and after the glow discharge occurs, several steps are taken before visible light reaches the human eye. That is, when a glow discharge occurs, an excited gas is generated by the collision of electrons and gases, and ultraviolet rays are generated from the excited gas, and visible light is generated because the ultraviolet rays collide with the phosphor in the discharge cell. It passes through the transparent substrate and reaches the human eye. Through this step, input power applied to the sustain electrode and the scan electrode is considerably lost.

This glow discharge is caused by applying a voltage higher than the discharge start voltage between the two electrodes. In other words, a very high voltage is required for this discharge to start. Once discharge occurs, the voltage distribution between the cathode and the anode is distorted due to the space charge effect generated in the dielectric layers around the cathode and the anode. That is, between the two electrodes, a cathode sheath region around the cathode that consumes most of the voltage applied to the two electrodes for discharge, and an anode sheath region around the anode that consumes a portion of the voltage, And a positive column region formed between these two regions and consuming little voltage. The electron heating efficiency in the cathode sheath region depends on the secondary electron coefficient of the MgO protective film formed on the surface of the dielectric layer, and most of the input energy in the positive column region is consumed by electron heating. It is known.

The vacuum ultraviolet rays that collide with the phosphor and emit visible light are generated when the Xen gas in the excitation state is transitioned to the ground state, and the excited state of Xen is Xe gas. Is created by the collision between and electrons. Therefore, in order to increase the ratio of generating the visible light among the input energy (that is, the luminous efficiency), the electron heating efficiency must be increased to increase the collision of electrons with the xenon (Xe) gas.

In the cathode sheath region, most of the input energy is consumed, but the electron heating efficiency is low. In the positive column region, the electron heating efficiency is very high while the input energy consumption is low. Therefore, high luminous efficiency is possible because it increases the positive column region (discharge gap).

In addition, the ratio of electrons consumed among all electrons according to the change of the ratio E / n of the electric field E and the gas density n between the discharge gaps (positive column region) is equal to (E / In n), the electron consumption ratio is known to increase in the order of xenon excitation (Xe *), xenon ion (Xe ⁺ ), neon excitation (Ne *), and neon ion (Ne ⁺ ). Also, at the same ratio (E / n), it is known that the electron energy decreases as the Xen partial pressure increases. That is, when this electron energy decreases, the partial pressure of xenon (Xe) increases, and when the partial pressure of xenon (Xe) increases, the above-mentioned xenon excitation (Xe *), xenon ions (Xe ⁺ ), neon excitation (Ne *) ), The ratio of electrons consumed to excitation of xenon (Xe) is increased among the electrons consumed in neon ions (Ne ⁺ ), thereby improving the luminous efficiency.

As mentioned above, the increase in the positive column area increases the electron heating efficiency. Increasing the partial pressure of xenon (Xe) increases the rate of electron heating consumed for xenon excitation (Xe *) in electrons. Therefore, both of them increase electron heating efficiency, thereby improving luminous efficiency.

However, increasing the positive column area or increasing the Xen partial pressure all have problems of increasing the gas breakdown voltage and increasing the manufacturing cost of the PDP.

Therefore, in order to increase the luminous efficiency, it is required to implement an increase in the positive column area and an increase in the xenon partial pressure under a low discharge start voltage.

As is known, when the distance and pressure of the discharge gap are the same, the discharge start voltage required for the counter discharge structure is lower than the discharge start voltage required for the surface discharge structure.

SUMMARY OF THE INVENTION The present invention has been made in view of the above, and provides a plasma display panel and a method of driving the same, which lower the discharge start voltage and shorten the reset period and the addressing period to improve gradation expression.

According to an embodiment of the present invention, a plasma display panel includes a first substrate and a second substrate that are disposed to face each other, a first partition layer that partitions a plurality of discharge spaces adjacent to the first substrate, and adjacent to the second substrate. A second partition wall partitioning a discharge space facing the discharge space, a phosphor layer formed inside discharge cells formed by the both discharge spaces, and the discharge cell between the first partition layer and the second partition wall layer. A first electrode and a second electrode, each of which is alternately arranged side by side on each side and is shared with other discharge cells neighboring on each side and extends in a direction perpendicular to the surface of the substrate; Between two partition wall layers, they are arranged side by side on either one of the first partition wall layer side and the second partition wall layer side, and extend in a direction intersecting with the first electrode and the second electrode, and along this extension direction. And a first address electrode and a second address electrode each having protrusions alternately disposed in the discharge cells.

The first address electrode is provided adjacent to any one side of the first barrier layer and the second barrier layer, and the second address electrode is provided adjacent to the first electrode and the second electrode side. In addition, the protrusion of the first address electrode is provided adjacent to any one of the first barrier layer and the second barrier layer, and the protrusion of the second address electrode is provided adjacent to the first electrode and the second electrode side. .

The first address electrode and the second address electrode are preferably formed of a metal electrode having excellent electrical conductivity.

The distance L ₂ between each protrusion of the first address electrode and the second address electrode and the second electrode is shorter than the distance L ₁ between the protrusion and the first electrode, thereby facilitating address discharge due to a lower voltage. Let's do it.

The first address electrode and the second address electrode are respectively formed on both sides of the discharge cells arranged in the extending direction thereof, and the protrusions of the first address electrode and the protrusions of the first address electrode are each discharge cells on both sides of the discharge cells. Protruding alternately toward the center of the.

The dielectric layer formed on the outer surface of each protrusion of the first address electrode and the second address electrode may be directly connected to the dielectric layer provided on the outer surface of the second electrode.

On the other hand, the extended portion of the first electrode and the extended portion of the second electrode is formed in the vertical cross section of the substrate surface in the vertical length (h _v ) of the cross section is longer than the horizontal length (h _h ) of the cross section It is desirable to have a cross-sectional structure for counter discharge.

The first electrode and the second electrode are preferably formed of a metal electrode having excellent electrical conductivity.

The first electrode, the second electrode, the first address electrode, and the second address electrode have a dielectric layer on an outer surface thereof. This dielectric layer preferably has a matrix structure corresponding to the discharge cells. The dielectric layer may have a protective film on its outer surface, and the protective film may be formed of a visible light impermeable material to increase the secondary electron emission coefficient.

Preferably, the discharge space formed by the second barrier layer is formed in a larger volume than the discharge space formed by the first barrier layer.

The first partition layer includes a first partition member formed in a direction parallel to the address electrode and a second partition member formed to intersect the first partition member, and the second partition layer is in a direction parallel to the address electrode. And a third partition member formed to be a fourth partition member formed to intersect with the third partition member. In this case, the first partition layer and the second partition layer each form a closed partition structure.

The first partition wall layer may include a first partition wall member formed in a direction parallel to the address electrode, and the second partition wall layer may be formed in a direction parallel to the address electrode corresponding to the first partition wall member. It may be made of a partition member. In this case, each of the first and second partition walls forms a stripe-type partition wall structure.

The phosphor layer includes a first phosphor layer formed on the first substrate side of the discharge cell and a second phosphor layer formed on the second substrate side of the discharge cell. The first phosphor layer is formed of a reflective phosphor, and the second phosphor layer is formed of a transmissive phosphor. Further, the thickness t ₁ of the first phosphor layer is preferably formed thicker than the thickness t ₁ of the second phosphor layer.

In addition, the plasma display panel driving method according to an embodiment of the present invention, the first electrode and its extension and the second electrode which are disposed alternately on both sides of the discharge cell and shared by the adjacent discharge cells, respectively; An expansion portion thereof, overlapped between the electrode and the first partition wall layer of the first substrate and between any one side of the electrode and the second partition wall layer of the second substrate to intersect the first electrode and the second electrode, A method of driving a plasma display panel including a first address electrode and a second address electrode, which are disposed in parallel with each other in correspondence to a discharge cell and alternately correspond to the discharge cells, and which are adjacent to each other during an addressing period. Applying a scan pulse to a second electrode shared by a discharge cell and another discharge cell, and a side different from the one side discharge cell to which the scan pulse is applied Addressing the discharge cells.

In the addressing step, one of the neighboring discharge cells is addressed to the first address electrode, and the other side of the discharge cells is addressed to the second address electrode.

In the addressing step, one of the neighboring discharge cells is addressed to the first address electrode, the other side of the discharge cell is addressed to the second address electrode, and each addressing by the first address electrode and the second address electrode is simultaneously performed. Implement

An address pulse is applied from the first address electrode driver to the first address electrode, and an address pulse is applied from the second address electrode driver to the second address electrode.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like elements throughout the specification.

FIG. 1 is a partially exploded perspective view illustrating a plasma display panel according to a first embodiment of the present invention, and FIG. 2 schematically illustrates structures of electrodes and discharge cells in the plasma display panel according to the first embodiment of the present invention. FIG. 3 is a partial cross-sectional view of the plasma display panel cut along the AA line by combining the plasma display panel shown in FIG. 1, and FIG. 4 illustrates a structure of an electrode in the plasma display panel according to the first embodiment of the present invention. It is a schematic partial perspective view.

Referring to the PDP, the PDP according to the first embodiment basically includes a first substrate 10 (hereinafter referred to as a "back substrate") and a second substrate 20 (hereinafter referred to as "opposite substrates") arranged at predetermined intervals. And a first partition layer 16 (hereinafter, referred to as a "back plate partition wall") and a second partition wall layer 26 provided between the rear substrate 10 and the front substrate 20. And "face plate bulkheads"). The back plate partition wall 16 and the front plate partition wall 26 divide a plurality of discharge spaces to form discharge cells 18 and 28 facing each other. The discharge cells 18 and 28 include phosphor layers 19 and 29 that absorb vacuum ultraviolet rays and emit visible light, and discharge gases (for example, xenon and neon) to generate vacuum ultraviolet rays by plasma discharge. (Mixed gas containing Ne) and the like.

The rear plate partition wall 16 protrudes from the rear substrate 10 toward the front substrate 20, and the front plate partition wall 26 protrudes from the front substrate 20 toward the rear substrate 10. The back plate partition wall 16 divides a plurality of discharge spaces adjacent to the back substrate 10 to form discharge cells 18 on one side, and the front plate partition wall 26 has a plurality of adjacent face plates 20. The discharge space of the compartment is divided to form a discharge cell 28 on the other side. As described above, substantially one discharge cell 18 or 28 is formed by discharge spaces facing each other. In the present invention, unless otherwise specified for the discharge cells 18 and 28, the discharge cells 18 and 28 mean discharge spaces formed as one by two discharge spaces.

It is preferable that the volume of the discharge space formed by the front plate partition 26, that is, the volume of the discharge cell 28 is greater than the volume of the discharge space formed by the back plate partition 16, that is, the discharge cell 18. . Due to the difference in volume, visible light generated in the discharge cells 18 and 28 can be effectively transmitted through the front substrate 10.

The back plate partition wall 16 and the front plate partition wall 26 can form the discharge cells 18 and 28 in various shapes, such as a square or a hexagon, and the present embodiment has the discharge cells 18 and 28 formed in a square. To illustrate. Referring to this, the back plate partition wall 16 is formed on the inner surface of the back substrate 10 in a long direction in one direction (y-axis direction) and is arranged, and the first partition wall member 16a And a second partition wall member 16b which is formed to intersect with each other and partitions the discharge cells 18 into independent discharge spaces. The front plate partition 26 has a third partition member 26a protruding toward the rear substrate 10 in a shape corresponding to the first partition member 16a on the inner surface of the front substrate 20, and the third partition member 26a. And a fourth partition member 26b formed in a shape corresponding to the second partition member 16b to form a discharge cell 28 corresponding to the discharge cell 18 on the front substrate 28 side.

The phosphor layers 19 and 29 are formed in the discharge cells 18 and 28 as described above, and the first phosphor layer 19 and the front substrate 20 side formed in the discharge cell 18 on the back substrate 10 side. The second phosphor layer 29 formed in the discharge cell 28 is included. The discharge cells 18 formed by the back plate partition wall 16 and the discharge cells 28 formed by the front plate partition wall 26 are substantially one discharge cell 18, 28, so that the discharge cells 18 are formed inside the discharge cell 18. Each of the first phosphor layer 19 and the second phosphor layer 29 formed at the same generates visible light of the same color by vacuum ultraviolet rays generated by gas discharge. In addition, the first phosphor layer 19 and the second phosphor layer 29 generate visible light at both sides of substantially one discharge cell 18, 28 to improve luminous efficiency.

The first phosphor layer 19 is formed on the inner surface of each of the first and second barrier rib members 16a and 16b and the surface of the back substrate 10 positioned in the discharge cell 18. The second phosphor layer 29 is formed on the inner surface of each of the third and fourth partition wall members 26a and 26b and the surface of the back substrate 10 positioned in the discharge cell 28.

The first phosphor layer 19 may be formed by forming a back plate partition 16 on the back substrate 10 and then applying a phosphor, and discharging the back substrate 10 to the discharge cell 18. After etching to correspond to the shape of), it may be formed by applying a phosphor to the etched surface. As illustrated, the second phosphor layer 29 may be formed by forming the front plate partition 26 on the front substrate 20 and then applying a phosphor, and discharging the front substrate 20 to the discharge cell 28. After etching to correspond to the shape of the may be formed by applying a phosphor to the etched surface.

When the back substrate 10 is etched to form the back plate partition 16, the back substrate 10 and the back plate partition 16 are made of the same material (not shown), and the front substrate 20 is etched to form the back plate. When the partition wall 26 is formed, the front substrate 20 and the front plate partition 26 are made of the same material (not shown). This etching method can reduce the manufacturing cost compared to the method of forming the back plate partition wall 16 and the front plate partition wall 26 separately from the back substrate 10 and the front substrate 20, respectively.

The first phosphor layer 19 absorbs vacuum ultraviolet rays from the inside of the discharge cell 18 on the rear substrate 10 and the second phosphor layer 29 inside the discharge cell 28 on the front substrate 20, respectively. Visible light directed toward the substrate 20 is generated. In addition, since the first phosphor layer 19 is made of a reflective phosphor which reflects visible light, and the second phosphor layer 29 is made of a transmissive phosphor which transmits visible light, light is emitted by visible light transmitted to the front substrate 20. In order to improve the efficiency, the thickness t ₁ of the first phosphor layer 19 on the rear substrate 10 is made thicker than the thickness t ₂ of the second phosphor layer 29 on the front substrate 20 ( t ₁ > t ₂ ). In other words, the particle size of the phosphor powder forming the first phosphor layer 19 is larger than the particle size of the phosphor powder forming the second phosphor layer 29. Such a difference in thickness t ₁ and t ₂ may increase the luminous efficiency by minimizing the loss of vacuum ultraviolet rays.

The plasma display panel of the present invention is configured to generate vacuum ultraviolet rays that will collide with the first phosphor layer 19 and the second phosphor layer 29 by plasma discharge so as to implement an image corresponding to each of the discharge cells 18 and 28. The address electrode 11, the second address electrode 12, the first electrode 31 (hereinafter referred to as a 'holding electrode') and the second electrode 32 (hereinafter referred to as a 'scan electrode') are formed on the back substrate 10. It is provided between the front substrate 20.

As shown in FIG. 2, the sustain electrode 31 and the scan electrode 32 are disposed on both sides of the discharge cells 18 and 28 (both in the y-axis direction) between the rear plate partition 16 and the front plate partition 26. ) Are alternately arranged side by side, and are shared by other discharge cells 18 and 28 neighboring on each side, and form mutually opposite discharge structures. The sustain electrode 31 is adjacent to the discharge cells 18 along the extending direction (y axis direction) of the first address electrode 11 and the second address electrode 12 based on one discharge cell 18, 28. , 28 is shared on one side, and the scan electrode 32 is shared on the other side of the discharge cells 18, 28 neighboring along this y-axis direction. As a result, the sustain electrode 31 and the scan electrode 32 are involved in sustain discharge of two discharge cells 18 and 28 adjacent to each side.

The first address electrode 11 and the second address electrode 12 may be disposed between the back plate partition 16 and the front plate partition 26 with the back plate partition 16 and the front plate partition based on the electrode layer. 26) Any one side is placed side by side on the same side spaced apart from each other. The first address electrode 11 is provided adjacent to any one of the rear plate partition 16 and the front plate partition 26, and the second address electrode 12 includes the sustain electrode 31 and the scan electrode 32. It is provided adjacent to the side. As the first address electrode 11 and the second address electrode 12 are stacked and disposed, the protrusions 11a, in order to alternately address the discharge cells 18 and 28 that are adjacent in the extending direction (y axis direction) thereof. 12a), respectively. The protrusion 11a of the first address electrode 11 is provided adjacent to any one of the rear plate partition 16 and the front plate partition 26, and the protrusion 12a of the second address electrode 12 is held. It is provided adjacent to the electrode 31 and the scanning electrode 32 side.

3 illustrates a configuration in which the first address electrode 11 and the second address electrodes 11 and 12 are stacked on the rear plate partition 16. The first address electrode 11 and the second address electrode 12 intersect the sustain electrode 31 and the scan electrode 32 and alternately correspond to the discharge cells 18, 28 arranged in the y-axis direction. Protruding portions 11a and 12a are provided, respectively, and alternately engage in addressing of discharge cells 18 and 28 neighboring in the y-axis direction. That is, when referring to one discharge cell 18, 28, the first address electrode 11 and the second address electrode 12 are on the same side (between the sustain electrode and the scan electrode side and the back plate partition wall 16). Although stacked and arranged in pairs, the first address electrode 11 and its protrusion 11a act on the addressing of the discharge cells 18 and 28 as long as they are adjacent, and the second address electrode 12 and the protrusion 12a thereof. 에 acts on the addressing of the other discharge cells 18, 28 adjacent to the discharge cells 18, 28 addressed by the first address electrode 11. That is, the first address electrode 11 and the second address electrode 12 alternately address the discharge cells 18 and 28 arranged in the y-axis direction.

The first address electrode 11 and the second address electrode 12 are formed on the sustain electrode 31, the scan electrode 32, and the back plate in the z-axis direction of the back substrate 10 and the front substrate 20. Between the side of the partition 16, it corresponds to the 1st partition member 16a and the 3rd partition member 26a, and is formed long in parallel with them (y-axis direction), and overlaps with each other, x They are arranged in parallel with each other while maintaining a distance corresponding to the discharge cells 18, 28 in the axial direction. The first address electrode 11 and the protrusion 11a are provided adjacent to the rear substrate 10 side, that is, the rear plate partition 16, and the second address electrode 12 and the protrusion 12a are retained. It is provided adjacent to the electrode 31 and the scanning electrode 32 side. As a result, the first address electrode 11 and the second address electrode 12 are disposed on the rear plate partition 16 with the sustain electrode 31 and the scan electrode 32 at the center of the discharge cells 18 and 28. It is provided. As a result, the sustain electrode 31, the scan electrode 32, and the first address electrode 11 and the second address electrode 12 that cross each other do not interfere with each other.

The first address electrode 11 and the second address electrode 12 are disposed on one side of one discharge cell 18, 28, but the protrusions 11a of the first address electrode 11 are continuously disposed discharge cells ( 18 and 28 corresponding to even groups, and the protrusion 12a of the second address electrode 12 corresponds to an odd group of discharge cells 18 and 28 arranged in series. Or may be interchanged with each other. Since the first address electrode 11 and the second address electrode 12 are addressed by the interaction with the scan electrode 32, the protrusion 11a of the first address electrode 11 may serve as the scan electrode 32. The protruding portion 12a of the second address electrode 12 protrudes toward the center of the shared one side discharge cell 18a, 28a, and the center of the other side discharge cell 18a, 28a sharing the same scan electrode 32. Protrudes. That is, the protrusion 11a and the protrusion 12b are alternately arranged in the discharge cells 18 and 28 arranged in succession.

Since the first address electrode 11 and the second address electrode 12 are provided between the first partition member 16a and the third partition member 26a which are non-discharge regions, visible light generated in the discharge cells 18 and 28. It may be formed of an opaque material because it does not block, and may be formed of a metal positive electrode having excellent electrical conductivity. Each of the protrusions 11a and 12a protrudes toward the center of the discharge cells 18 and 28 and may be formed of a transparent electrode, and may be formed of the same material as the first address electrode 11 and the second address electrode 12, respectively. May be

Each of the protrusions 11a and 12a of the first address electrode 11 and the second address electrode 12 is a portion for applying an address pulse applied to each of the discharge cells 18 and 28 to the scanning electrode 32. When a scan pulse is applied to the first address electrode 11 and the second address electrode 12, an address pulse may be applied to the first address electrode 11 and the second address electrode 12. In addition, the protrusions 11a and 12a form a short gap between the scan electrodes 32 and the discharge gaps in the respective discharge cells 18 and 28, and also trigger the triggering action to address discharge due to low voltage. To make it possible.

On the other hand, the sustain electrode 31 and the scan electrode 32 are formed on the back plate partition wall 16 constituting the discharge cells 18, 28 on both sides of the back substrate 10 and the front substrate 20 in the z-axis direction. It is formed between the front plate partition wall 26 and is formed long along the direction (x-axis direction) which is electrically insulated from and intersects with the first address electrode 11 and the second address electrode 12. The sustain electrode 31 is disposed on one side of the discharge cells 18, 28, and the scan electrode 32 is disposed side by side with the sustain electrode 31 on the other side of the discharge cells 18, 28. The sustain electrode 31 and the scan electrode 32 are shared by neighboring discharge cells 18, 28 alternately in discharge cells 18, 28 arranged in succession. That is, based on the two discharge cells 18 and 28 arranged in series, the scan electrode 32 is the second partition member 16b and the fourth partition member 26b which divide the two discharge cells 18 and 28. ) Is provided between. Of course, the sustain electrode 31 is also provided between the second partition member 16b and the fourth partition member 26b which divide two adjacent discharge cells 18 and 28. Accordingly, when an address pulse is applied to the first address electrode 11 and the second address electrodes 11 and 12 and a scan pulse is applied to the scan electrode 32, two discharge cells 18 and 28 neighboring in one scan are applied. 2 addressing to select is implemented, so that the addressing period is shortened. When a reset pulse is applied to the scan electrode 32, the two discharge cells 18 and 28 shared by the scan electrode 32 are reset to shorten the reset period. In this way, the reset period and the addressing period are shortened, so the sustain period is long, and the extension of the sustain period increases the number of sustain pulses, thereby improving the gray scale expressive power.

As shown in FIG. 4, the sustain electrode 31 and the scan electrode 32 are formed and arranged to implement two addressings in one scan action with respect to the discharge cells 18 and 28 neighboring in the y-axis direction. One discharge cell 18, 28 sharing the scan electrode 32 is provided with a protrusion 11a of the first address electrode 11, and the other discharge cell 18, 28 of the shared scan electrode 32 is provided. The protrusion 12a of the second address electrode 12 is provided. The protrusions 11a and 12a are triggered between the sustain electrode 31 and the scan electrode 32 to enable sustain discharge by low voltage.

Since the sustain electrode 31 and the scan electrode 32 are disposed between the second partition member 16b and the fourth partition member 26, the lengths of the first address electrode 11 and the second address electrode 12 are long. It may be a reference for distinguishing neighboring discharge cells 18 and 28 in the direction (y axis direction).

The scan electrode 32, together with the first address electrode 11 and the second address electrode 12, serves to select the discharge cells 18 and 28 to be turned on by participating in the addressing of the addressing period, and the sustain electrode ( 31) and the scan electrode 32 serve to display the screen by participating in the sustain discharge during the sustain period. That is, the sustain pulse is applied to the sustain electrode 31 in the sustain period, the sustain pulse is applied in the sustain period, and the scan pulse is applied in the scan period. However, since the electrodes may perform their roles differently according to the signal voltage applied thereto, the present invention does not need to be limited to the above.

The sustain electrode 31 and the scan electrode 32 are formed together with the first address electrode 11 and the second address electrode 12 so as to partition the discharge cells 18 and 28 which are substantially one to both sides. , 20), so as to form an opposite discharge structure, so that the discharge start voltage for sustain discharge can be lowered.

The sustain electrode 31 and the scan electrode 32 are perpendicular to the back substrate 10 and the front substrate 20 at portions corresponding to the respective discharge cells 18 and 28 in order to induce surface facing discharge of a larger area. Expansion parts 31a and 32a which extend in one direction (z-axis direction) are respectively provided. Each of the extension portions 31a and 32a has a vertical length h _v in its horizontal cross section in the vertical cross-section of the back substrate 10 and the front substrate 20 in the horizontal direction h _h . Has a longer cross-sectional structure. The widespread opposite discharge thus produces a strong vacuum ultraviolet ray, which impinges on the first phosphor layer 19 and the second phosphor layer 29 over a large area inside the discharge cells 18 and 28. The amount of visible light generated is increased.

In addition, the sustain electrode 31 and its extension part 31a and its scanning electrode 32 and its extension part 32a are provided between the second partition member 16b and the fourth partition member 26a which are non-discharge regions. Since it does not have a side effect of blocking visible light generated in the discharge cells 18 and 28, it may be formed of an opaque material, and may be formed of a metal positive electrode having excellent electrical conductivity.

Each of the sustain electrode 31, its extension part 31a, and the scanning electrode 32 and its extension part 32a may be formed in a vertical cross section (yz plane) of the front substrate 20 and the rear substrate 20. A symmetrical structure is formed with respect to its longitudinal direction (x axis direction). As a result, the sustain electrode 31 and the scan electrode 32 form an opposite discharge structure with the discharge cells 18 and 28 interposed therebetween.

The sustain electrode 31 and the scan electrode 32 form opposite discharges to the respective extension portions 31a and 32a in the discharge cells 18 and 28 to lower the discharge start voltage and share the scan electrode 32. The two discharge cells 18 and 28 implement two resets with one reset and two addressing with one scan, thereby reducing the reset period and the addressing period.

On the other hand, the sustain electrode 31, the scan electrode 32, and the first address electrode 11 and the second address electrode 12 have dielectric layers 34 and 35 on their outer surfaces. These dielectric layers 34 and 35 also accumulate wall charges, but form an insulating structure of the electrodes. The sustain electrode 31, the scan electrode 32, the first address electrode 11, and the second address electrode 12 can be manufactured by a thick film ceramic sheet (TFCS) method. That is, the electrode part including the sustain electrode 31, the scan electrode 32, and the first address electrode 11 and the second address electrode 12 is separately manufactured, and then the back substrate on which the back plate partition wall 16 is formed. The PDP can be manufactured by the method of combining with (10).

The dielectric layers 34 and 35 preferably have a matrix structure corresponding to the discharge cells 18 and 28. The dielectric layers 34 and 35 of the matrix structure covering this electrode correspond to the matrix structure of the back plate partition 16 and the front plate partition 26.

In addition, the dielectric layers 34 and 35 preferably include a protective film 36 on the outer surface thereof. In particular, the passivation layer 36 may be formed at a portion exposed to the plasma discharge occurring in the discharge space inside the discharge cells 18 and 28. This protective film 36 protects the dielectric layers 34 and 35 and requires a high secondary electron emission coefficient, but does not need to have visible light transmission. In other words, the sustain electrode 31, the scan electrode 32, the first address electrode 11, and the second address electrode 12 are not formed on the front substrate 20 and the rear substrate 10, but instead the two substrates 10,. 20 provided between the sustain electrodes 31, the scan electrodes 32, and the dielectric layers 34 and 35 covering the first address electrodes 11 and the second address electrodes 12. Silver may be made of a material having properties of visible light impermeability. As an example of the protective film 36, the visible light-transmissive MgO has a much higher secondary electron emission coefficient value than the visible light-transmissive MgO, and thus the discharge start voltage can be further lowered.

In addition, since the first address electrode 11 and the second address electrode 12 are surrounded by the dielectric layer 35 having the same dielectric constant, the same discharge start voltage between red (R), green (G), and blue (B). By having a large voltage margin can be secured.

Meanwhile, as described above, the sustain electrode 31 corresponds to the second partition member 16b and the fourth partition member 26b that form one side (one side in the y-axis direction) of the discharge cells 18 and 28. Is provided in a shared structure, and the scan electrodes 32 correspond to the second partition member 16b and the fourth partition member 26b, which form the other side of the discharge cells 18 and 28, in a shared structure therebetween. As provided, the electrode arrangement in the same order as that of the sustain electrode 31-the scan electrode 32-the sustain electrode 31 is formed.

In addition, the first barrier member 16a and the third barrier member 16 in which the first address electrode 11 and the second address electrode 12 form one side (both sides in the x-axis direction) of the discharge cells 18 and 28 ( 26a), the protrusions 11a and 12a are disposed at the centers of the discharge cells 18 and 28, corresponding to the sustain electrodes 31, the scanning electrodes 32, and the sustain electrodes. The arrangement of the 31 is substantially along the direction in which the address electrode 12 extends, and the protrusion 11a-the scan electrode 32-the second address electrode 12 of the sustain electrode 31-the first address electrode 11 substantially. The electrode arrangements in the same order as the protruding portion 12a-sustaining electrode 31 are formed.

As shown in FIG. 5, the first address electrode 11 is drawn out to one side of the front substrate 20 and the back substrate 10 and connected to the first address electrode driver 11b, and the second address electrode 12 ) Is drawn to the other side of the front substrate 20 and the rear substrate 10 and connected to the second address electrode driver 12b to scan one adjacent discharge cell 18, 28 sharing the scan electrode 32. 2 addressing is enabled.

As shown in FIG. 6, the driving method of the PDP configured as described above includes a scan electrode 32 which is shared between the neighboring one discharge cells 18 and 28 and the other discharge cells 18 and 28 in the addressing period. Applying a scan pulse (V _sc ) and addressing the one side discharge cells (18, 28) and the other side discharge cells (18, 28) to which the scan pulse has been applied.

In this addressing step, one of the two discharge cells 18 and 28 adjacent to each other is addressed by an address pulse V _a1 applied to the first address electrode 11, and the other side discharge cell ( 18 and 28 are addressed by an address pulse V _a2 applied to the second address electrode 12. In this case, an address pulse V _a1 is applied to the first address electrode 11 from the first address electrode driver 11 b, and an address pulse V _a2 from the second address electrode driver 12 b to the second address electrode 12. ) Is applied. Each addressing by the first address electrode 11 and the second address electrode 12 is implemented simultaneously.

In the reset step performed before the scan and addressing step, the reset pulse V _r is applied to one scan electrode 32 to interact with the sustain electrodes 31 provided on both sides of the scan electrode 32. Thus, two neighboring discharge cells 18 and 28 are simultaneously reset. A known waveform may be used for the reset pulse V _r applied in this reset period, and a known waveform may be used for the sustain pulse V _s applied in the sustain period.

Hereinafter, various embodiments of the present invention will be described. Since the following embodiments are generally similar or identical in structure to the above embodiments, detailed descriptions thereof will be omitted here and other parts will be described.

7 is a second embodiment of the present invention. Wherein the first address electrode 11 and the second address each protrusion (11a _2, 12a ₂₎ and the sustain electrode 32 and the distance (L ₂₎ each protruding portion of the electrode 11 (11a _2, 12a ₂₎ and It is formed shorter than the distance L ₁ from the sustain electrode 31. Therefore, each protrusion 11a ₂ , 12a ₂ triggers an address discharge more easily by triggering between the first address electrode 11 and the scan electrode 32 and between the second address electrode 12 and the scan electrode 32. do.

8 is a third embodiment of the present invention. Here, the first address electrode 11 and the second address electrode 12 are formed on both sides of the discharge cells 18 arranged in the extending direction (y axis direction) thereof. The protrusions 11a ₃ of the first address electrode 11 and the protrusions 12a ₃ of the second address electrode 12 alternately toward the center of each discharge cell 18 on both sides of the discharge cells 18. Is formed to protrude.

9 is a fourth embodiment of the present invention. The first address electrode 11 and the second address electrode are arranged as in the third embodiment, and each of the protrusions 11a ₄ and 12a ₄ is formed to have a larger width than the third embodiment. Therefore, the dielectric layer 35 formed on the outer surface of each of the protrusions 11a ₄ and 12a _{4 of} the first address electrode 11 and the second address electrode 12 is directly connected to the dielectric layer 34 provided on the outer surface of the scan electrode 32. Connected. Therefore, each of the protrusions 11a ₄ and 12a ₄ is more than the third embodiment by triggering between the first address electrode 11 and the scan electrode 32 and between the second address electrode 12 and the scan electrode 32. Address discharge is facilitated.

10 is a fifth embodiment of the present invention. The rear plate partition 16 is formed of a first partition member 16a formed in a direction (y axis direction) parallel to the first and second address electrodes 11 and 12, and the front plate partition 26 is The third partition member 26a may be formed to correspond to the first partition member 16a in a direction parallel to the first and second address electrodes 11 and 12. In the first to fourth embodiments, the back plate partition wall 16 and the front plate partition wall 26 are formed in a matrix-type partition wall structure, respectively. In the fifth embodiment, the back plate partition wall 16 and the front plate partition wall are formed. Each of 26 is formed in a stripe-type partition wall structure.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications or changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. It goes without saying that it belongs to the scope of the present invention.

As described above, according to the plasma display panel according to the present invention, electrodes are provided between a rear substrate and a front substrate, and among these electrodes, a sustain electrode and an extension part thereof are provided on one side of the discharge cell, and a scan electrode and an extension part thereof are provided. The discharge cell is provided on the other side of the discharge cell in an opposite discharge structure, and the sustain electrode and the scan electrode are shared by neighboring discharge cells, alternately arranged, and the first and second address electrodes are stacked on the same substrate side. Since the addressing of the even-numbered and the odd-numbered group discharge cells is simultaneously involved with the protrusions of the first and second address electrodes, the discharge start voltage is lowered by the opposite discharge of the sustain electrodes and the scan electrodes, and the discharge cells adjacent to the scan electrodes are discharged. And reset the even group discharge cells and the odd group discharge cells at the same time, thereby shortening the reset period. The second address electrode simultaneously addresses the even group discharge cells and the odd group discharge cells, thereby reducing the addressing period. The shortening of the reset period and the addressing period in this way extends the sustain period, thereby improving the gray scale expressive power.

Claims (24)

A first substrate and a second substrate disposed to face each other; A first barrier rib layer partitioning a plurality of discharge spaces adjacent to the first substrate; A second partition wall layer adjacent to the second substrate and partitioning a discharge space facing the discharge space; A phosphor layer formed inside discharge cells formed by the discharge spaces on both sides; Between the first barrier layer and the second barrier layer, each side is provided with an extension part alternately arranged side by side on both sides of the discharge cell and shared by other discharge cells adjacent to each side and extending in a direction perpendicular to the substrate surface A first electrode and a second electrode; And Between the first and second partition walls, the first and second partition walls are arranged side by side on either side of the second partition wall layer, and extend in a direction intersecting with the first electrode and the second electrode. And a first address electrode and a second address electrode each having protrusions alternately arranged in discharge cells arranged along the extension direction. The method of claim 1, The first address electrode is provided adjacent to any one side of the first barrier layer and the second barrier layer, The second address electrode is disposed adjacent to the first electrode and the second electrode side. The method of claim 2, The protruding portion of the first address electrode is provided adjacent to any one side of the first and second barrier rib layers. The protrusion of the second address electrode is disposed adjacent to the first electrode and the second electrode. The method of claim 1, And the first address electrode and the second address electrode are formed of a metal electrode. The method of claim 1, The distance L ₂ between each protrusion of the first address electrode and the second address electrode and the second electrode is The plasma display panel is shorter than the distance (L ₁ ) between the protrusion and the first electrode. The method of claim 1, And the first address electrode and the second address electrode are formed on both sides of the discharge cells arranged in the extending direction thereof. The method of claim 6, And a protrusion of the first address electrode and a protrusion of the second address electrode are alternately protruded from both sides of the discharge cells toward the center of each discharge cell. The method of claim 4, wherein And a dielectric layer formed on an outer surface of each of the protrusions of the first address electrode and the second address electrode is directly connected to the dielectric layer provided on the outer surface of the second electrode. The method of claim 1, The extension part of the first electrode and the extension part of the second electrode have a cross-sectional structure in which a vertical length h _v of the cross section is formed longer than a horizontal length h _h of the cross section in a vertical cross section of the substrate surface. Plasma display panel. The method of claim 1, The first electrode and the second electrode is a plasma display panel formed of a metal electrode. The method of claim 1, And a dielectric layer formed on an outer surface of the first electrode, the second electrode, the first address electrode, and the second address electrode. The method of claim 11, The dielectric layer has a protective film on its outer surface. The method of claim 11, And a matrix structure in which the dielectric layer corresponds to a discharge cell. The method according to any one of claims 1 to 13, And a discharge space formed by the second barrier layer is larger than a discharge space formed by the first barrier layer. The method according to any one of claims 1 to 13, The first partition layer is formed of a first partition member formed in a direction parallel to the address electrode and a second partition member formed to cross the first partition member, And the second partition layer comprises a third partition member formed in a direction parallel to the address electrode and a fourth partition member formed to intersect the third partition member. The method according to any one of claims 1 to 13, The first partition layer is formed of a first partition member formed in a direction parallel to the address electrode, And the second partition wall layer includes a third partition wall member formed in a direction parallel to the address electrode in correspondence to the first partition wall member. The method according to any one of claims 1 to 13, And the phosphor layer includes a first phosphor layer formed on the first substrate side of the discharge cell and a second phosphor layer formed on the second substrate side of the discharge cell. The method of claim 17, And the first phosphor layer is formed of a reflective phosphor, and the second phosphor layer is formed of a transmissive phosphor. The method of claim 17, And a thickness t ₁ of the first phosphor layer is thicker than a thickness t ₁ of the second phosphor layer. A first electrode and an extension portion thereof and a second electrode and an extension portion thereof, which are alternately disposed on both sides of the discharge cell in parallel with each other and shared by neighboring discharge cells, and between the electrode and the first barrier layer of the first substrate; It is arranged side by side on either side of the electrode and the second partition wall layer of the second substrate to intersect the first electrode and the second electrode, and are arranged side by side corresponding to each of the discharge cells and alternately corresponding to the discharge cells In the method of driving a plasma display panel comprising a first address electrode and a second address electrode having each protrusion, In the addressing period, applying a scan pulse to a second electrode shared by a discharge cell adjacent to one neighboring discharge cell; And And addressing the one side discharge cell and the other side discharge cell to which the scan pulse is applied. The method of claim 20, The addressing step of the plasma display panel driving method of addressing one discharge cell of the adjacent discharge cells to the first address electrode. The method of claim 20, The addressing step of the plasma display panel driving method for addressing the discharge cell of the other side of the adjacent discharge cells to the second address electrode. The method of claim 20, In the addressing step, one of the neighboring discharge cells is addressed to the first address electrode, The other discharge cell is addressed to the second address electrode, A plasma display panel driving method for simultaneously implementing the addressing by the first address electrode and the second address electrode. The method of claim 23, wherein An address pulse is applied to the first address electrode from a first address electrode driver, And applying an address pulse from the second address electrode driver to the second address electrode.

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