KR100658724B1 - Plasma display panel - Google Patents

Abstract

A plasma display panel is provided to induce address discharge and sustain discharge by forming a first and second triggering electrodes projected to a center of discharge cells. A first and second substrates are disposed parallel to each other. A plurality of discharge cells(48) are formed between the first and second substrates. A plurality of address electrodes(12) corresponding to the discharge cells are extended in a first direction. A first and second electrodes(31,32) are extended in a second direction crossing the first direction and are expanded vertically to the first and second substrates in order to be disposed alternately at boundaries of the adjacent discharge cells. A first and second triggering electrodes(41,42) corresponding to the address electrodes are projected from the first and second electrodes to a center of the discharge cells.

Description

Plasma Display Panel {PLASMA DISPLAY PANEL}

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

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

3 is a cross-sectional view taken along line III-III of FIG.

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

5 to 7 are cross-sectional views illustrating a discharging process in the plasma display panel according to the first embodiment of the present invention.

8 is a cross-sectional view according to a second embodiment of the present invention.

9 is a cross-sectional view according to a third embodiment of the present invention.

The present invention relates to a plasma display panel, and more particularly, to a plasma display panel for lowering an address discharge voltage and a sustain discharge voltage.

A general plasma display panel ("PDP") can be described by taking a three-electrode surface discharge type PDP as an example. The three-electrode surface discharge type PDP includes a front substrate and a rear substrate, and is formed by enclosing the front substrate and the rear substrate with the discharge gas filled between the two substrates.

The front substrate has a sustain electrode and a scan electrode formed extending in one direction on its inner surface. The back substrate includes an address electrode spaced apart from the inner surface of the front substrate by a predetermined distance and extended in a direction crossing the sustain electrode and the scan electrode.

In this PDP, address discharge by the independently controlled scan electrode and address electrode determines whether discharge is present. Subsequently, sustain discharge by the sustain electrode and the scan electrode positioned on the inner surface of the front substrate realizes an image.

PDP generates visible light by using a glow discharge. After this glow discharge occurs, several steps are performed until visible light reaches the human eye.

That is, when glow discharge occurs, gas excited by the collision of electrons and gases is generated. Vacuum ultraviolet rays are generated from the gas thus excited. Since the vacuum ultraviolet rays collide with the phosphor in the discharge cell, visible light is generated. This visible light reaches the human eye through the transparent front substrate.

Through these steps, the input power applied to the cathode and anode is significantly lost.

This glow discharge is caused by applying a voltage higher than the discharge start voltage between the two electrodes. That is, a very high voltage is required for the glow discharge to be initiated.

Once discharge occurs, the voltage distribution between the cathode and the anode appears in a distorted form due to the space charge effect formed in each dielectric layer around the cathode and the anode.

That is, between the two electrodes, a cathode sheath region, an anode sheath region, and a positive column region are formed.

This cathode sheath region is the region around the cathode that consumes most of the voltage applied to both electrodes for discharge. The anode sheath region is the region around the anode that consumes a portion of the voltage. The positive column region consumes little voltage between the two regions.

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. Most of the input energy in the positive column region is consumed by electron heating.

The vacuum ultraviolet rays that collide with the phosphor to generate 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 to the input energy (that is, the luminous efficiency), it is necessary to increase the number of collisions between the xenon (Xe) gas and the electrons, so the higher the electron heating efficiency, the higher the luminous efficiency. You can expect an increase.

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 can be obtained by increasing the positive column area, which can be achieved by increasing the distance of the discharge gap.

On the other hand, as the Xen partial pressure increases, the luminous efficiency also increases.

Xe *, Xe excitation among all electrons as the reduced electric field, i.e. the ratio (E / n) of the electric field (E) between the discharge gap to gas density (n), changes ), The ratio of electrons consumed to xenon ions (Xe +, Xe ionization), neon excitation (Ne *, Ne excitation), neon ions (Ne +, Ne ionization) varies.

In the same converted electric field E / n, as the partial pressure of xenon (Xe) increases, electron energy decreases. As the electron energy decreases, the ratio of electrons consumed to excitation of xenon (Xe) increases. Since the vacuum ultraviolet rays that produce visible light are generated when the Xe gas in the excitation state transitions to the ground state, the luminous efficiency increases as the ratio of electrons consumed by the excitation of Xen increases. Is improved.

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, the increase in the positive column area or the increase in the Xen partial pressure all have problems of increasing the discharge firing voltage and increasing the manufacturing cost of the PDP.

Therefore, it is required to increase the positive column area and increase the xenon (Xe) partial pressure under a low discharge start voltage and increase the luminous efficiency.

As is known, when the distance of the discharge gap and the partial pressure of xenon 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 relates to a plasma display panel which lowers an address discharge voltage and a sustain discharge voltage by applying a counter discharge structure.

According to an embodiment of the present invention, a plasma display panel includes a first substrate, a second substrate disposed parallel to the first substrate at predetermined intervals, and discharge cells partitioned between the first substrate and the second substrate. An address electrode extending along the first direction to continuously correspond to the discharge cells along a first direction, extending along a second direction crossing the first direction, and extending from the first substrate to the second First and second electrodes alternately arranged along the first direction and extending in a vertical direction with respect to a substrate, and alternately disposed at boundaries between neighboring discharge cells, and the discharge cells at the first and second electrodes, respectively. A first triggering electrode and a second triggering electrode corresponding to the address electrode protruding toward the center of the electrode are included.

The address electrode may be formed on the first substrate.

In the vertical cross section of the first substrate and the second substrate, each of the first electrode and the second electrode has a cross-sectional structure in which lengths HV1 and HV2 in the vertical direction are longer than lengths HH1 and HH2 in the horizontal direction. Can have

In a vertical cross section of the first substrate and the second substrate, the length HV1 of the vertical direction of the first electrode may be greater than the length HVt1 of the vertical direction of the first triggering electrode.

In a vertical cross section of the first substrate and the second substrate, the length HV2 in the vertical direction of the second electrode may be greater than the length HVt2 in the vertical direction of the second triggering electrode.

The first triggering electrode may be connected to the opposite surface of the first electrode, and the second triggering electrode may be connected to the opposite surface of the second electrode.

The second triggering electrode is formed in the second electrode along the first direction to correspond to a boundary of the discharge cells along the second direction, and the second to the second discharge cell into the discharge cell. It may include a protrusion protruding along the direction.

The protruding portion may protrude from the elongating portion to the discharge cell on either side of the second direction.

The protrusion may protrude from both the discharge cells in the second direction in the extension portion.

The first triggering electrode may be formed in the first electrode along the first direction to correspond to a boundary of the discharge cells along the second direction, and the second to the discharge cell. And protrusions protruding along the direction.

In the plasma display panel according to an embodiment of the present invention, the first electrode, the second electrode, the first triggering electrode, and the second triggering electrode are disposed between the first substrate and the second substrate. The first barrier layer provided on the first substrate and the second barrier layer provided on the second substrate may be included.

The first partition wall layer may include a first partition wall member formed in the first direction, and the second partition wall layer may include a second partition wall member formed to be parallel to the first partition wall member.

The first partition wall layer includes a third partition wall member formed to cross the first partition wall member in the second direction, and the second partition wall layer is parallel to the third partition wall member and crosses the second partition wall member. It may include a fourth partition member formed in the second direction.

The first triggering electrode may be floated from an opposite side of the first electrode, and the second triggering electrode may be floated from an opposite side of the second electrode.

The second triggering electrode may be formed along the first direction at the second electrode side to correspond to a boundary of the discharge cells along the second direction, and the extension part may be formed into the discharge cell. It may include a protrusion protruding in two directions.

The first triggering electrode may be formed along the first direction on the first electrode side to correspond to a boundary of the discharge cells along the second direction, and the extension part may extend into the discharge cell. It may include a protrusion protruding in two directions.

The first electrode, the second electrode, the first triggering electrode, and the second triggering electrode may be formed of metal electrodes.

The first electrode, the second electrode, the first triggering electrode, and the second triggering electrode may be covered with a dielectric layer.

The dielectric layer may have a matrix structure corresponding to the discharge cells.

The dielectric layer may be covered with a protective film.

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.

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

Referring to the PDP, the PDP is basically a first substrate (hereinafter referred to as "back substrate") and a second substrate 20 (hereinafter referred to as "front surface") spaced at predetermined intervals and arranged in parallel with each other. Substrate "). The back substrate 10 and the front substrate 20 are encapsulated with each other by partitioning the discharge cells 48 therebetween.

In the discharge cells 48, a phosphor layer 49 which absorbs vacuum ultraviolet rays and emits visible light is applied, and a discharge gas (for example, a mixed gas including neon and xenon) is filled. do.

Around the discharge cells 48, the address electrode 12, the first electrode 31 (hereinafter referred to as "hold electrode"), the second electrode 32 (hereinafter referred to as "scan electrode"), and the first triggering electrode 41, and the second triggering electrode 42 are arranged to select the discharge cells 48 and then to implement an image.

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

Referring to this figure, the address electrode 12 is elongated in the y-axis direction so as to continuously correspond to the discharge cells 48 along the first direction (y-axis direction in the drawing). The address electrode 12 is provided on the back substrate 10, and is formed to pass through the center of the plane (x-y plane) of each discharge cell 18. In addition, the address electrodes 12 are disposed parallel to each other along the x-axis direction and covered with the dielectric layer 13.

3 is a cross-sectional view taken along line III-III of FIG. 1, and FIG. 4 is a partial perspective view schematically showing the structure of an electrode in the plasma display panel according to the first embodiment of the present invention.

Referring to these drawings, the sustain electrode 31 and the scan electrode 32 extend in the second direction (the x-axis direction in the drawing) to continuously correspond to the discharge cells 48 in the x-axis direction. alternately arranged at the boundary of the adjacent discharge cells 48 along the y-axis direction. For this reason, each of the sustain electrode 31 and the scan electrode 32 is shared by a pair of discharge cells 48 neighboring in the y-axis direction.

In addition, the sustain electrode 31 and the scan electrode 32 are formed to extend along the third direction (the z-axis direction in the drawing) with the discharge cells 48 interposed therebetween, and the y-axis direction in the discharge cells 48. To form an opposing discharge structure.

The first triggering electrode 41 protrudes from the sustain electrode 31 toward the center of the discharge cell 48, and the second triggering electrode 42 faces from the scan electrode 32 toward the center of the discharge cell 48. Is formed to protrude. The first triggering electrode 41 and the second triggering electrode 42 face each other in the discharge cell 48.

Among these electrodes, the address electrode 12 is formed on the back substrate 10, and the sustain electrode 31, the scan electrode 32, the first triggering electrode 41, and the second triggering electrode 42 are It is provided between the front substrate 20 and the rear substrate 10.

To this end, the PDP of the first embodiment includes a first partition layer 16 (hereinafter referred to as a "back plate partition wall") on the back substrate 10 and a second partition layer 26 (hereinafter referred to as "back panel partition wall") on the front substrate 20. Front plate partition wall ".

The rear plate partition 16 forms the first discharge space 18 in the rear substrate 10, and the front plate partition 26 forms the second discharge space 28 in the front substrate 10. As a result, the discharge cells 48 are divided by the first discharge space 18 and the second discharge space 28.

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 volume of the discharge space 28 formed by the front plate partition wall 26 is larger than the volume of the discharge space 18 formed by the back plate partition wall 16. Due to the difference in volume, visible light generated in the discharge cell 48 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 48 in various shapes such as square or hexagon with respect to the x-y plane. In addition, the back plate partition wall 16 and the front plate partition wall 26 may partition the discharge cells 48 in the same shape with respect to the x-y plane, and may partition the discharge cells 48 in different shapes.

The first embodiment illustrates a discharge cell 48 that is substantially rectangular with respect to the x-y plane. That is, the rear plate partition 16 forms the first discharge space 18 of the discharge cells 48 in a rectangular matrix structure, and the front plate partition 26 has the second discharge space 28 of the discharge cells 48. ) Is formed into a stripe structure open in the y-axis direction.

The rear plate partition wall 16 is formed to extend to intersect the first partition member 16a and the first partition member 16a which are formed to be formed to be elongated in the y-axis direction on the inner surface of the rear substrate 10. And a third partition wall member 16b for partitioning the first discharge space 18 of the discharge cell 48 into an independent structure.

The back plate partition wall 16 may be formed only of the first partition wall member 16a (see FIG. 8), but may further include a third partition wall member 16b as in the first embodiment. In this case, the third partition member 16b prevents address discharge from occurring at the intersection of the scan electrode 32 and the address electrode 12, and between the address electrode 12 and the second triggering electrode 42. Causes address discharge to occur.

In addition, the front plate partition wall 26 includes a second partition wall member 26a that is formed to be elongated in a shape corresponding to the first partition wall member 16a on the inner surface of the front substrate 20.

This front plate partition 26 may be formed of only the second partition member 26a as in the first embodiment, or may further include a fourth partition member 26b (see Fig. 8). In this case, the fourth partition member 26b is formed in a shape corresponding to the third partition member 16b to partition the second discharge space 28 of the discharge cell 48 into an independent structure.

Accordingly, the back plate partition wall 16 and the front plate partition wall 26 may be formed in the same manner as the discharge cell 48 in a matrix structure or a stripe structure, and in a different structure by selectively applying the matrix structure and the stripe structure, respectively. It may be formed.

On the other hand, the phosphor layer 49 is formed in the discharge cell 48. The discharge cell 48 has a first discharge space 18 partitioned by the back plate partition wall 16 and a second discharge space 28 partitioned by the front plate partition wall 26. Therefore, the phosphor layer 49 may be formed in both the first discharge space 18 and the second discharge space 28, or may be formed in only one place.

The first embodiment includes a first phosphor layer 19 formed in the first discharge space 18 and a second phosphor layer 29 formed in the second discharge space 28. In one discharge cell 48, the first phosphor layer 19 and the second phosphor layer 29 generate visible light of the same color by vacuum ultraviolet rays generated by gas discharge.

The first phosphor layer 19 is coated on the inner surface and the rear substrate 10 of the first partition member 16a and the third partition member 16b forming the first discharge space 18. In addition, the first phosphor layer 19 may be formed on the inner surface of the first partition member 16a and the rear substrate 10 forming the first discharge space 18 (see FIG. 8).

The second phosphor layer 29 is formed on the inner surface of the second partition member 26a and the front substrate 20 forming the second discharge space 28. In addition, the second phosphor layer 29 may be formed on the inner surface of the second partition member 26a and the fourth partition member 26b and the front substrate 20 to form the second discharge space 28 (FIG. 8).

In addition, as shown in the first embodiment, 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. In addition, the first phosphor layer 19 may be formed by etching the back substrate 10 to correspond to the shape of the first discharge space 18 and then applying a phosphor to the etched surface (not shown).

As shown in the first embodiment, the second phosphor layer 29 may be formed by forming the front plate partition wall 26 on the front substrate 20 and then applying a phosphor. In addition, the second phosphor layer 29 may be formed by etching the front substrate 20 to correspond to the shape of the second discharge space 28 and then applying a phosphor to the etched surface (not shown).

As such, 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. When the front plate partition 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 separately forming the back plate partition wall 16 and the front plate partition wall 26 on the back substrate 10 and the front substrate 20, respectively.

The PDP generates vacuum ultraviolet rays by plasma discharge, excites the phosphor layer 49 by the vacuum ultraviolet rays, and implements an image so that the address electrodes 12 and the sustain electrodes described above correspond to the discharge cells 48. 31, a scan electrode 32, a first triggering electrode 41, and a second triggering electrode 42.

The sustain electrode 31 and the scan electrode 32 are arranged in a mutually opposite discharge structure between the rear plate partition 16 and the front plate partition 26.

To form this counter discharge structure, as described above, the sustain electrode 31 and the scan electrode 32 are extended in the z-axis direction between the rear substrate 10 and the front substrate 20 (see FIG. 4). ).

That is, in the vertical cross section y-z of the rear substrate 10 and the front substrate 20, the sustain electrode 31 has a cross-sectional structure in which the length HV1 in the vertical direction is longer than the length HH1 in the horizontal direction. The scan electrode 32 has a cross-sectional structure in which the length HV2 in the vertical direction is longer than the length HH2 in the horizontal direction.

In the vertical cross section yz, the length HV1 in the vertical direction of the sustain electrode 31 is greater than the length HVt1 in the vertical direction of the first triggering electrode 41, and thus, The length HV2 in the vertical direction is greater than the length HVt2 in the vertical direction of the second triggering electrode 42.

The first triggering electrode 41 receives a voltage from the sustain electrode 31, and the second triggering electrode 42 receives a voltage from the scan electrode 32.

To this end, the first triggering electrode 41 is connected to the opposite surface of the sustain electrode 31, and the second triggering electrode 42 is connected to the opposite surface of the scan electrode 32 (see FIGS. 3 and 4). In this case, each of the first triggering electrode 41 and the second triggering electrode 42 may apply a voltage applied to the sustaining electrode 31 and the scan electrode 32 more effectively.

In addition, the first triggering electrode 41 may be floated from the opposite surface of the sustain electrode 31, and the second triggering electrode 42 may be floated from the opposite surface of the scan electrode 32 (see FIG. 8).

In the floating structure, the voltage applied to the sustain electrode 31 and the scan electrode 32 can be significantly lowered in the first triggering electrode 41 and the second triggering electrode 41 than in the direct connection structure.

Meanwhile, the first triggering electrode 41 is formed to include the extension part 41a and the protrusion part 41b. The extension part 41a is formed to extend in the y-axis direction from the sustain electrode 31 and disposed to correspond to the boundary of the discharge cells 48 in the x-axis direction. The protruding portion 41b protrudes along the x-axis direction from the extending portion 41a into the discharge cell 48. The extension part 41a applies the voltage applied to the sustain electrode 31 to the protrusion part 41b.

The protruding portion 41b protrudes from the extending portion 41a to the discharge cell 48 on one side (right side) of both sides (right and left in Fig. 2) in the x-axis direction. In addition, the protruding portion 41b may protrude from the extending portion 41a to both of the discharge cells 48 in the x-axis direction (left and right in FIG. 9).

The second triggering electrode 42 may be formed to resemble the first triggering electrode 41. In other words, the second triggering electrode 42 includes the extension part 42a and the protrusion part 42b. The extension part 42a is formed to extend in the y-axis direction of the scan electrode 32 and disposed to correspond to the boundary of the discharge cells 48 in the x-axis direction. The protrusion 42b protrudes along the x-axis direction from the extension 42a into the discharge cell 48. The stretcher 41b applies a voltage applied to the scan electrode 21 to the protrusion 42b.

The protruding portion 42b protrudes from the extending portion 42a to the discharge cell 48 on one side (right side) of both sides (right and left in Fig. 2) in the x-axis direction. In addition, the protruding portion 42b may protrude from the extending portion 42a to both of the discharge cells 48 in the x-axis direction (left and right in FIG. 9).

The sustain electrode 31, the scan electrode 32, the first triggering electrode 41, and the second triggering electrode 42 may be disposed between the back plate partition wall 16 and the front plate partition wall 26. Since the structure surrounding the x-axis and y-axis directions of 48) is disposed, the visible light generated in the discharge cells 48 is not shielded.

Therefore, the sustain electrode 31, the scan electrode 32, the first triggering electrode 41, and the second triggering electrode 42 may be formed of a metal electrode having an opaque material but excellent electrical conductivity.

In addition, the sustain electrode 31, the scan electrode 32, the first triggering electrode 41, and the second triggering electrode 42 are covered with the dielectric layer 35. At this time, the sustain electrode 31 and the first triggering electrode 41 are attached to each other or floated to be electrically connected to each other, and the scan electrode 32 and the second triggering electrode 42 are attached to each other or floated to be electrically connected to each other. . In this state, the dielectric layer 35 electrically insulates the sustain electrode 31 and the scan electrode 32, and electrically insulates the first triggering electrode 41 and the second triggering electrode 42.

The dielectric layer 35 may have a matrix structure corresponding to the first discharge space 18 of the discharge cell 48. This dielectric layer 35 is covered with a protective film 36.

The protective film 36 is formed at a portion exposed to the plasma discharge occurring inside the discharge cell 48. This protective film 36 protects the dielectric layer 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 triggering electrode 41, and the second triggering electrode 42 are not formed on the front substrate 20 or the rear substrate 10, but rather on both substrates ( It is provided between the 10, 20) may be made of a material having a characteristic 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.

5 to 7 are cross-sectional views illustrating a discharging process in the plasma display panel according to the first embodiment of the present invention.

Referring to these drawings, during address discharge, an address voltage is applied to the address electrode 12, and a voltage at which the extending part 42a of the second triggering electrode 42 is applied to the scan electrode 32 is applied to the protrusion part 42b. Is applied to.

As a result, primary discharge is generated between the protrusion 42b of the address electrode 12 and the second triggering electrode 42 (see FIG. 5). This primary discharge is implemented by opposing discharge between the protrusion 42b and the address electrode 12.

Following the primary discharge, a secondary discharge of the short gap is generated between the protrusion 42b of the second triggering electrode 42 and the protrusion 41b of the first triggering electrode 41 (see Fig. 6). This secondary discharge is implemented by opposing discharge between the protrusion 41b and the protrusion 42b.

Following the secondary discharge, a long gap tertiary discharge is generated between the sustain electrode 31 and the scan electrode 32 (see Fig. 7).

That is, the address discharge proceeds three times and selects the discharge cell 48 to be turned on. As such, since the first and second discharges are implemented as counter discharges, the address discharge voltage can be lowered.

After the address discharge, during sustain discharge, a sustain voltage applied to the sustain electrode 31 is applied to the protrusion 41b of the first triggering electrode 41, and a sustain voltage applied to the scan electrode 32 is second triggered. The protrusion 42b of the electrode 42 is applied.

The primary discharge of the short gap is generated between the protrusion 41b of the first triggering electrode 41 and the protrusion 42b of the second triggering electrode 42 (see Fig. 6). This primary discharge is realized by the opposite discharge between the protrusion 41b and the protrusion 42b.

Following the primary discharge, a long gap secondary discharge is generated between the sustain electrode 31 and the scan electrode 32 (see Fig. 7). This secondary discharge is implemented as a counter discharge between the sustain electrode 31 and the scan electrode 32.

That is, sustain discharge proceeds over two times to drive the discharge cells 48 selected by the address discharge. As such, since the primary discharge and the secondary discharge are implemented as counter discharges, the sustain discharge voltage can be lowered.

Hereinafter, various embodiments of the present invention will be described. The following second to third embodiments are generally similar or identical in structure to those of the first embodiment, and thus, detailed descriptions of these parts will be omitted and other parts will be described herein.

8 is a cross-sectional view according to a second embodiment of the present invention.

Compared with the first embodiment, the second embodiment forms the back plate partition wall 216 only with the first partition wall member 216a to form the first discharge space 218 in a stripe structure, and the front plate partition wall 226 is formed. The second discharge space 228 is formed in a matrix structure by forming the second wall member 226a and the fourth partition member 226b.

Thus, the first phosphor layer 219 is formed on the inner surface and the back substrate 10 of the first partition member 216a, and the second phosphor layer 229 is the second partition member 226a and the fourth partition member. It is formed on the inner surface and the front substrate 20 of (226b).

Compared with the first embodiment, the second embodiment may be somewhat disadvantageous to address discharge because there is no third partition member 16b, and the transmittance of visible light may be somewhat disadvantageous because the fourth partition member 226b is present.

As described above, the first triggering electrode 41 and the second triggering electrode 42 are each formed floating. Compared to the first embodiment, in the second embodiment, the voltage applied to the sustain electrode 31 and the scan electrode 32 may be slightly lowered at the first triggering electrode 41 and the second triggering electrode 42. .

9 is a cross-sectional view according to a third embodiment of the present invention.

Compared to the first embodiment, in the third embodiment, the protrusion 341b of the first triggering electrode 341 and the protrusion 342b of the second triggering electrode 342 are in the x-axis direction in each of the extension portions 341a and 342a. It protrudes on both sides.

In this case, one first triggering electrode 341 and one second triggering electrode 342 are provided per pair of discharge cells 48 in the x-axis direction. Therefore, compared with the first embodiment, the number of the first triggering electrode 341 and the second triggering electrode 342 can be reduced in the second embodiment.

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 present invention, an address electrode is provided on a rear substrate, and a sustain electrode and a scan electrode are provided between the rear substrate and the front substrate, and the discharge cells are adjacent to the sustain electrode and the scan electrode in the address electrode length direction. And first and second triggering electrodes protruding toward the center of the discharge cell from each of the sustain electrode and the scan electrode to face each other. The triggering electrodes are used to perform address discharge and sustain discharge. Induction, while lowering the address discharge voltage and the discharge start voltage, there is an effect of improving the luminous efficiency by forming a counter-discharge structure of the sustain electrode and the scan electrode.

Claims (22)

A first substrate; A second substrate disposed in parallel with the first substrate at a predetermined interval; Discharge cells partitioned between the first substrate and the second substrate; An address electrode extending along the first direction so as to continuously correspond to the discharge cells in a first direction; Extending along a second direction crossing the first direction and extending in a vertical direction with respect to the first substrate and the second substrate, disposed along the first direction, and alternately disposed at a boundary between adjacent discharge cells; A first electrode and a second electrode; And And a first triggering electrode and a second triggering electrode corresponding to the address electrode, respectively, protruding from the first electrode and the second electrode to the center of the discharge cell. According to claim 1, And the address electrode is formed on the first substrate. According to claim 1, In the vertical cross section of the first substrate and the second substrate, Each of the first electrode and the second electrode has a cross-sectional structure in which lengths HV1 and HV2 in the vertical direction are longer than lengths HH1 and HH2 in the horizontal direction. According to claim 1, In the vertical cross section of the first substrate and the second substrate, And a length HV1 in the vertical direction of the first electrode is greater than a length HVt1 in the vertical direction of the first triggering electrode. According to claim 1, In the vertical cross section of the first substrate and the second substrate, And a length HV2 in the vertical direction of the second electrode is greater than a length HVt2 in the vertical direction of the second triggering electrode. According to claim 1, The first triggering electrode is connected to an opposite surface of the first electrode, And the second triggering electrode is connected to an opposite surface of the second electrode. The method of claim 6, The second triggering electrode, An extension part formed in the second electrode along the first direction and corresponding to a boundary of the discharge cells along the first direction; And a protrusion protruding from the extension part into the discharge cell along the second direction. The method of claim 7, wherein And the protrusion protrudes from the extension part into the discharge cells on either side of the second direction. The method of claim 7, wherein And the projecting portion protrudes from both the discharge cells in the second direction in the extending portion. The method of claim 7, wherein The first triggering electrode, An extension part formed in the first electrode along the first direction and corresponding to a boundary of the discharge cells along the second direction; And a protrusion protruding from the extension part into the discharge cell along the second direction. The method of claim 10, And the protrusion protrudes from the extension part into the discharge cells on either side of the second direction. The method of claim 10, And the projecting portion protrudes from both the discharge cells in the second direction in the extending portion. The method of claim 10, The first electrode, the second electrode, the first triggering electrode, and the second triggering electrode are disposed between the first substrate and the second substrate, A first partition wall layer provided on the first substrate, And a second partition wall layer provided on the second substrate. The method of claim 13, The first partition layer includes a first partition member formed in the first direction, The second partition wall layer includes a second partition wall member formed in parallel with the first partition wall member. The method of claim 14, The first partition layer includes a third partition member formed in the second direction to cross the first partition member, And the second partition wall layer includes a fourth partition member parallel to the third partition member and intersecting with the second partition member to be formed in the second direction. According to claim 1, The first triggering electrode is floated from an opposite surface of the first electrode, And the second triggering electrode is floated from an opposite surface of the second electrode. The method of claim 16, The second triggering electrode, An extension part formed along the first direction at the second electrode side and corresponding to a boundary of the discharge cells along the second direction; And a protrusion protruding from the extension part into the discharge cell along the second direction. The method of claim 17, The first triggering electrode, An extension part formed along the first direction on the first electrode side and corresponding to a boundary of the discharge cells along the second direction; And a protrusion protruding from the extension part into the discharge cell along the second direction. According to claim 1, The first electrode, the second electrode, the first triggering electrode, and the second triggering electrode are formed of a metal electrode. According to claim 1, And the first electrode, the second electrode, the first triggering electrode and the second triggering electrode are covered with a dielectric layer. The method of claim 20, And the dielectric layer has a matrix structure corresponding to the discharge cells. The method of claim 20, And the dielectric layer is covered with a protective film.

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