The present invention relates to a plasma display panel and more specifically to a plasma display panel in which metal and auxiliary metal electrodes are formed such that brightness and efficiency are improved.
As shown in
Wall charges occurred upon the plasma discharge is accumulated on the upper dielectric layer 18 and the lower dielectric layer 24. The protection layer 20 serves to prevent damage of the upper dielectric layer 18 due to sputtering generated upon the plasma discharge and to increase emission efficiency of secondary electrons. The protection layer 20 is usually formed using magnesium oxide (MgO).
The address electrodes 22 are formed in the direction intersecting a pair of sustain electrodes 14, 16. A data signal is supplied for the address electrodes 22 to select a cell that is displayed.
The barrier ribs 26 are formed in parallel to the address electrode 22 and serves to prevent ultraviolet rays and a visible ray generated due to the discharge from leaking toward neighboring discharge cells. The barrier ribs 26 may be existed or not a boundary line of sub-pixel.
The phosphor layer 28 is excited by ultraviolet rays generated upon the plasma discharge to generate a visible ray of one of red, green and blue. Inert mixed gases such as He+Xe, Ne+Xe and He+Ne+Xe for discharge are inserted into a discharge space of the discharge cell formed between the upper/lower substrates 10, 12.
A pair of sustain electrode 14, 16 comprises scan electrodes 14 and sustain electrodes 16. A scan signal for scanning of the panel is supplied for scan electrodes 14 and a sustain signal for maintaining discharge of a selected cell is supplied for sustain electrodes.
A pair of sustain electrode 14, 16 comprises transparent ITO electrodes 14A, 16A, which are stripe pattern, are made of transparent material in order to transmit a visible ray and have a wide width relatively, and metal electrodes 14B, 16B, which compensate a resistance of transparent ITO electrodes 14A, 16A and have a narrow width relatively. Each of the transparent ITO electrodes of a pair of sustain electrodes 14, 16 is opposite to each other at a predetermined distance. Further, metal electrodes 14B, 16B are formed in parallel to the transparent ITO electrodes 14A, 16A and formed on a verge of the transparent ITO electrodes 14A, 16A, respectively. Namely, metal electrodes 14B, 16B are formed on outside verge of the transparent ITO electrodes 14A, 16A.
A PDP cell of this structure sustains a discharge according to surface discharge between a pair of sustain electrodes 14, 16 after being selected by opposite discharge between the address electrode 22 and the scan electrode 14. In the PDP cell, a visible ray is emitted to an outside of cell as radiating phosphors 28 by ultraviolet rays which are generated while the sustain discharge occurs. As a result, the PDP having cells displays an image. In this case, the PDP realizes a gray scale by controlling the discharge sustaining period, i.e. the number of sustain discharge according to a video data.
In the conventional PDP, Xe inert gas excites phosphors 28 using a vacuum ultraviolet generated by changing from excited state to ground state according to gas discharge. Therefore, as a content of Xe is much, a quantity of vacuum ultraviolet rays generated upon the gas discharge and the efficiency of the PDP increase. However, the increase of Xe is caused by rising discharge starting voltage and discharge sustaining voltage between sustain electrodes.
Furthermore, in the conventional PDP, the discharge starting voltage and the discharge sustaining voltage is risen because the metal electrodes 14B, 16B are formed on the outside verge of the transparent ITO electrodes 14A, 16A, respectively. Also, the brightness and efficiency of the conventional PDP are decreased.
That is, the conventional PDP structure has a difficulty in increasing brightness and efficiency without any problem such as the structure of electrodes within the discharge cell.
Accordingly, the present invention has been made in view of the above problems, and it is an object of the present invention to provide a plasma display panel for increasing brightness and efficiency.
A plasma display panel comprises: transparent ITO electrodes which are spaced in parallel to each other at a predetermined distance within a discharge cell; metal electrodes which are formed in parallel to said transparent ITO electrodes and formed on verge of said transparent ITO electrodes, respectively; and auxiliary metal electrodes which are formed on said transparent ITO electrodes so that are positioned in the direction of sides of said transparent ITO electrodes which are opposite to each other, respectively.
Further a plasma display panel comprises: transparent ITO electrodes which are spaced in parallel to each other at a predetermined distance within a discharge cell; metal electrodes which are formed on said transparent ITO electrodes and in parallel to said transparent ITO electrodes so that are positioned in the direction of sides of said transparent ITO electrodes which are opposite to each other, respectively; and auxiliary metal electrodes which are formed on verge of said transparent ITO electrodes, respectively.
Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.
The First Embodiment
As shown in
According to the first embodiment of the present invention, the sustain electrodes 114, 116 are consisted of the transparent ITO electrodes 114A, 116A and the metal electrodes 114B, 116B and the auxiliary metal electrodes 114C, 116C on the transparent ITO electrodes 114A, 116A.
Each of the transparent ITO electrodes 114A, 116A of a pair of sustain electrodes 114, 116 are opposite to each other at a predetermined distance.
The transparent ITO electrodes 114A, 116A are made of transparent material in order to transmit a visible ray, and have a stripe pattern of a wide width relatively.
The metal electrodes 114B, 116B are formed on a verge of the transparent ITO 114A, 116A and have a stripe pattern of a narrow width relatively, respectively. The metal electrodes 114B, 116B and the auxiliary metal electrodes 114C, 116C made of material having a good conductivity in order to compensate a conductivity of transparent ITO electrodes 114A, 116A.
As shown in
A discharge voltage supplied from the metal electrodes 114B, 116B via the transparent ITO electrodes 114A, 116A is applied to each of the auxiliary metal electrodes 114C, 116C. In this result, each of the auxiliary metal electrodes 114C, 116C induces a strong electric field in the central portion of discharge cell and the discharge starting voltage and the discharge sustaining voltage are decreased.
A PDP cell of this structure is sustained a discharge according to surface discharge between a pair of sustain electrodes 114, 116 after being selected by opposite discharge between the address electrode 122 and the scan electrode 114. As shown in
Further, as shown in
In the conventional PDP, Xe inert gas excites phosphors 28 using a vacuum ultraviolet generated upon changing from excited state to ground state. Therefore, as a content of Xe is much, a quantity of vacuum ultraviolet rays generated upon the gas discharge and the efficiency of the PDP increase. However, the increase of Xe is caused by rising discharge starting voltage and discharge sustaining voltage between sustain electrodes.
However, in the PDP according to the first embodiment of the present invention, the discharge starting voltage and discharge sustaining voltage are decreased and the brightness and efficiency are increased at this time of the discharge, although the contents of Xe inert gas increases.
In the concrete, since the distance between the auxiliary metal electrodes 114C, 116C is near, the strong electric field generates at the central portion of the discharge cell, at this time of the discharge. And, the discharge starting voltage and discharge sustaining voltage are decreased by the strong electric field generated at the central portion of the discharge cell. Therefore, as shown in
The description of the same elements with the first embodiment of the present invention shown in
According to the modification of the first embodiment of the present invention, the sustain electrodes 214, 216 are consisted of the transparent ITO electrodes 214A, 216A and the metal electrodes 214B, 216B and the auxiliary metal electrodes 214C, 216C on the transparent ITO electrodes 214A, 216A.
Each of the transparent ITO electrodes 214A, 216A of a pair of sustain electrodes 214, 216 are opposite to each other at a predetermined distance.
The transparent ITO electrodes 214A, 216A are made of transparent material in order to transmit a visible ray and have a stripe pattern of a wide width relatively.
The metal electrodes 214B, 216B are formed on a verge of the transparent ITO 214A, 216A and have a stripe pattern of a narrow width relatively, respectively. The metal electrodes 214B, 216B and the auxiliary metal electrodes 214C, 216C are made of material having a good conductivity in order to compensate a conductivity of transparent ITO electrodes 214A, 216A.
As shown in
A discharge voltage supplied from the metal electrodes 214B, 216B via the transparent ITO electrodes 214A, 216A is applied to each of the auxiliary metal electrodes 214C, 216C. In this result, each of the auxiliary metal electrodes 214C, 216C induces a strong electric field in the central portion of discharge cell and the discharge starting voltage and the discharge sustaining voltage are decreased.
In this time, the appearance of the current density and discharge is similar to that shown in
The description of the same elements with the first embodiment of the present invention shown in
According to another transformation of the first embodiment of the present invention, the sustain electrodes 314, 316 are consisted of the transparent ITO electrodes 314A, 316A and the metal electrodes 314B, 316B and the auxiliary metal electrodes 314C, 316C on the transparent ITO electrodes 314A, 316A.
Each of the transparent ITO electrodes 314A, 316A of a pair of sustain electrodes 314, 316 are opposite to each other at a predetermined distance.
The transparent ITO electrodes 314A, 316A are made of transparent material in order to transmit a visible ray and have a stripe pattern of a wide width relatively.
The metal electrodes 314B, 316B are formed on a verge of the transparent ITO 314A, 316A and have a stripe pattern of a narrow width relatively, respectively. The metal electrodes 314B, 316B and the auxiliary metal electrodes 314C, 316C made of material having a good conductivity in order to compensate a conductivity of transparent ITO electrodes 314A, 316A.
As shown in
A discharge voltage supplied from the metal electrodes 314B, 316B via the transparent ITO electrodes 314A, 316A is applied to each of the auxiliary metal electrodes 314C, 316C. In this result, each of the auxiliary metal electrodes 314C, 316C induces a strong electric field in the central portion of discharge cell and the discharge starting voltage and the discharge sustaining voltage are decreased.
In this time, the appearance of the current density and discharge is similar to that shown in
The Second Embodiment
The description of the same elements with the first embodiment of the present invention shown in
According to the second embodiment of the present invention, the sustain electrodes 414, 416 are consisted of the transparent ITO electrodes 414A, 416A and the metal electrodes 414B, 416B and the auxiliary metal electrodes 414C, 416C on the transparent ITO electrodes 414A, 416A.
Each of the transparent ITO electrodes 414A, 416A of a pair of sustain electrodes 414, 416 are opposite to each other at a predetermined distance.
Each of the metal electrodes 414B, 416B is formed on the transparent ITO electrodes 414A, 416A between a central portion of the transparent ITO electrodes 414A, 416A and a central portion of the discharge cell.
That is, each of the metal electrodes 414B, 416B is formed on the transparent ITO electrodes 414A, 416A so that is positioned in the direction of sides of the transparent ITO electrodes 414A, 416A which are opposite to each other.
Preferably, the position of each of the metal electrodes 414B, 416B satisfies the following the equation 1.
D<H/4 [Equation. 1]
Wherein H represents a length of discharge cell, D represents a distance between a central portion of the metal electrodes 414B, 416B and a central portion of the discharge cell.
Each of the metal electrodes 414B, 416B induces a strong electric field in the central portion of discharge cell and the discharge starting voltage and the discharge sustaining voltage are decreased.
As shown in
A surface discharge is occurred between the metal electrodes 414B, 416B by applied voltage, and then the discharge is expanded in the direction of the outside sides of the discharge cell by the auxiliary metal electrodes 414C, 416C.
In the PDP according to the second embodiment of the present invention, the discharge starting voltage and discharge sustaining voltage are decreased and the brightness and efficiency are increased at this time of the discharge, although the contents of Xe inert gas increases. In the concrete, since the distance between the metal electrodes 414B, 416B is near, the strong electric field generates at the central portion of the discharge cell, at this time of the discharge, and then the discharge is expanded in the direction of the verge of the discharge cell. In this result, the discharge starting voltage and discharge sustaining voltage are decreased by the generated strong electric field at the central portion of the discharge cell and the brightness and efficiency are increased. Furthermore, since the discharge starting voltage and the discharge delay time are decreased, the stability of the discharge is improved.
The brightness and efficiency of the second embodiment according to the present invention and the conventional PDP show in
According to a modification of the second embodiment of the present invention, the sustain electrodes 514, 516 are consisted of the transparent ITO electrodes 514A, 516A and the metal electrodes 514B, 516B and the auxiliary metal electrodes 514C, 516C on the transparent ITO electrodes 514A, 516A.
Each of the transparent ITO electrodes 514A, 516A of a pair of sustain electrodes 514, 516 are opposite to each other at a predetermined distance.
The transparent ITO electrodes 514A, 516A are made of transparent material in order to transmit a visible ray and have a stripe pattern of a wide width relatively.
Each of the metal electrodes 514B, 516B is formed on the transparent ITO electrodes 514A, 516A between a central portion of the transparent ITO electrodes 514A, 516A and a central portion of the discharge cell.
That is, each of the metal electrodes 514B, 516B is formed on the transparent ITO electrodes 514A, 516A so that is positioned in the direction of sides of the transparent ITO electrodes 514A, 516A which are opposite to each other.
Each of the metal electrodes 514B, 516B induces a strong electric field in the central portion of discharge cell and the discharge starting voltage and the discharge sustaining voltage are decreased.
As shown in
The surface discharge is occurred between the metal electrodes 514B, 516B via applied voltage, and then the discharge is expanded in the direction of the outside sides of the discharge cell by the auxiliary metal electrodes 514C, 516C.
According to another modification of the second embodiment of the present invention, the sustain electrodes 614, 616 are consisted of the transparent ITO electrodes 614A, 616A and the metal electrodes 614B, 616B and the auxiliary metal electrodes 614C, 616C on the transparent ITO electrodes 614A, 616A.
Each of the transparent ITO electrodes 614A, 616A of a pair of sustain electrodes 614, 616 are opposite to each other at a predetermined distance.
The transparent ITO electrodes 614A, 616A are made of transparent material in order to transmit a visible ray and have a stripe pattern of a wide width relatively.
Each of the metal electrodes 614B, 616B is formed on the transparent ITO electrodes 614A, 616A between a central portion of the transparent ITO electrodes 614A, 616A and a central portion of the discharge cell.
That is, each of the metal electrodes 614B, 616B is formed on the transparent ITO electrodes 614A, 616A so that is positioned in the direction of sides of the transparent ITO electrodes 614A, 616A which are opposite to each other.
Each of the metal electrodes 614B, 616B induces a strong electric field in the central portion of discharge cell and the discharge starting voltage and the discharge sustaining voltage are decreased.
As shown in
The surface discharge is occurred between the metal electrodes 614B, 616B via applied voltage, and then the discharge is expanded in the direction of the outside sides of the discharge cell by the auxiliary metal electrodes 614C, 616C.
In a plasma display panel according to a first embodiment of the present invention, an auxiliary metal electrode induces a strong electric field in the central portion of discharge cell and the discharge starting voltage and the discharge sustaining voltage are decreased. Therefore, the present invention has an effect that it can increase the brightness and efficiency at the same discharge voltage.
In a plasma display panel according to a second embodiment of the present invention, since a distance between metal electrodes is near, the strong electric field generates at the central portion of the discharge cell and the discharge is expanded in the direction of the verge of the discharge cell by an auxiliary metal electrode. Therefore, the discharge starting voltage and discharge sustaining voltage are decreased and the brightness and efficiency are increased at the same discharge voltage. Furthermore, as the discharge starting voltage and the discharge delay time are decreased, the stability of the discharge is improved.
Number | Date | Country | Kind |
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10-2003-0018453 | Mar 2003 | KR | national |
10-2003-0035337 | Jun 2003 | KR | national |
Number | Name | Date | Kind |
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6531819 | Nakahara et al. | Mar 2003 | B1 |
Number | Date | Country | |
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20040189201 A1 | Sep 2004 | US |