This application claims the benefit of Korean Patent Application No. 10-2007-0067213 filed on Jul. 4, 2007 which is hereby incorporated by reference.
1. Field of the Disclosure
This document relates to a plasma display panel.
2. Description of the Background Art
The plasma display panel includes a phosphor layer inside discharge cells partitioned by barrier ribs and a plurality of electrodes.
A driving signal is supplied to the electrodes, thereby generating a discharge inside the discharge cells. When the driving signal generates a discharge inside the discharge cells, a discharge gas filled inside the discharge cells generates vacuum ultraviolet rays, which thereby cause phosphors formed inside the discharge cells to emit light, thus displaying an image on the screen of the plasma display panel.
In an aspect, a plasma display panel comprises a front substrate, a scan electrode and a sustain electrode that are positioned parallel to each other on the front substrate, an upper dielectric layer positioned on the scan electrode and the sustain electrode, a rear substrate on which an address electrode is positioned to intersect the scan electrode and the sustain electrode, a lower dielectric layer positioned on the address electrode, and a barrier rib that is positioned between the front substrate and the rear substrate and partitions a discharge cell, the barrier rib including lead (Pb) equal to or less than 1,000 ppm (parts per million), wherein a discharge gas is filled between the front substrate and the rear substrate and includes helium (He) of 9% to 42%.
In another aspect, a plasma display panel comprises a front substrate, a scan electrode and a sustain electrode that are positioned parallel to each other on the front substrate, the scan electrode and the sustain electrode each having a single-layered structure, an upper dielectric layer positioned on the scan electrode and the sustain electrode, a rear substrate on which an address electrode is positioned to intersect the scan electrode and the sustain electrode, a lower dielectric layer positioned on the address electrode, and a barrier rib that is positioned between the front substrate and the rear substrate and partitions a discharge cell, the barrier rib including lead (Pb) equal to or less than 1,000 ppm, wherein a discharge gas is filled between the front substrate and the rear substrate arid includes helium (He) of 9% to 42%.
In still another aspect, a plasma display panel comprises a front substrate, a scan electrode and a sustain electrode that are positioned parallel to each other on the front substrate, an interval between the scan electrode and the sustain electrode ranging from 80 μm to 250 μm, an upper dielectric layer positioned on the scan electrode and the sustain electrode, a rear substrate on which an address electrode is positioned to intersect the scan electrode and the sustain electrode, a lower dielectric layer positioned on the address electrode, and a barrier rib that is positioned between the front substrate and the rear substrate and partitions a discharge cell, the barrier rib including lead equal to or less than 1,000 ppm, wherein a discharge gas is filled between the front substrate and the rear substrate and includes helium (He) of 9% to 42%.
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated on and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention. In the drawings:
Reference will now be made in detail embodiments of the invention examples of which are illustrated in the accompanying drawings.
As illustrated in
An upper dielectric layer 104 for covering the scan electrode 102 and the sustain electrode 103 is positioned on the front substrate 101 on which the scan electrode 102 and the sustain electrode 103 are positioned.
The upper dielectric layer 104 limits discharge currents of the scan electrode 102 and the sustain electrode 103, and provides electrical insulation between the scan electrode 102 and the sustain electrode 103.
A protective layer 105 is positioned on the upper dielectric layer 104 to facilitate discharge conditions. The protective layer 105 may include a material having a high secondary electron emission coefficient, for example, magnesium oxide (MgO).
A lower dielectric layer 115 for covering the address electrode 113 is positioned on the rear substrate 111 on which the address electrode 113 is positioned. The lower dielectric layer 115 provides electrical insulation of the address electrodes 113.
Barrier ribs 112 of a stripe type, a well type, a delta type, a honeycomb type, and the like, are positioned on the lower dielectric layer 115 to partition discharge spaces (i.e., discharge cells). A red (R) discharge cell, a green (G) discharge cell, and a blue (B) discharge cell, and the like, may be positioned between the front substrate 101 and the rear substrate 111. In addition to the red (R), green (G), and blue (B) discharge cells, a white (W) discharge cell or a yellow (Y) discharge cell may be positioned.
Each discharge cell partitioned by the barrier ribs 112 is filled with a discharge gas.
A phosphor layer 114 is positioned inside the discharge cells to emit visible light for an image display during the generation of an address discharge. For instance, first, second and third phosphor layer respectively emitting red (R), green (G) and blue (B) light may be positioned inside the discharge cells. In addition to the red (R), green (G) and blue (B) light, a phosphor layer emitting white (W) or yellow (Y) light may be positioned.
A thickness of at least one of the phosphor layers 114 formed inside the red (R), green (G) and blue (B) discharge cells may be different from thicknesses of the other phosphor layers. For instance, thicknesses of the second and third phosphor layers inside the green (G) and blue (B) discharge cells may be larger than a thickness of the first phosphor layer inside the red (R) discharge cell. The thickness of the second phosphor layer may be substantially equal or different from the thickness of the third phosphor layer.
Widths of the red (R), green (G), and blue (B) discharge cells may be substantially equal to one another. Further, a width of at least one of the red (R), green (G), or blue (B) discharge cells may be different from widths of the other discharge cells. For instance, a width of the red (R) discharge cell may be the smallest, and widths of the green (G) and blue (B) discharge cells may be larger than the width of the red (R) discharge cell. The width of the green (G) discharge cell may be substantially equal or different from the width of the blue (B) discharge cell.
A width of the phosphor layer 114 positioned inside the discharge cell changes depending on the width of the discharge cell. For instance, a width of the second phosphor layer inside the green (G) discharge cell may be larger than a width of the first phosphor layer inside the red (R) discharge cell. Further, a width of the third phosphor layer inside the blue (B) discharge cell may be larger than the width of the first phosphor layer. Hence, a color temperature of an image displayed on the plasma display panel can be improved.
The plasma display panel 100 according the exemplary embodiment may have various forms of barrier rib structures as well as a structure of the barrier rib 112 illustrated in
In the differential type barrier rib structure, the height of the first barrier rib 112b may be smaller than the height of the second barrier rib 112a.
While
While
It should be noted that only one example of the plasma display panel according to the exemplary embodiment has been illustrated and described above, and the exemplary embodiment is not limited to the plasma display panel with the above-described structure. For instance, while the above description illustrates a case where the upper dielectric layer 104 and the lower dielectric layer 115 each have a sing-layered structure, at least one of the upper dielectric layer 104 or the lower dielectric layer 115 may have a multi-layered structure.
While the address electrode 113 positioned on the rear substrate 111 may have a substantially constant width or thickness, a width or thickness of the address electrode 113 inside the discharge cell may be different from a width or thickness of the address electrode 113 outside the discharge cell. For instance, a width or thickness of the address electrode 113 inside the discharge cell may be larger than a width or thickness of the address electrode 113 outside the discharge cell.
Referring to
In the first area 140, a plurality of first address electrodes Xa1, Xa1, . . . Xam are positioned parallel to one another. In the second area 150, a plurality of second address electrodes Xb1, Xb1, . . . Xbm are positioned parallel to one another to be opposite to the plurality of first address electrodes Xa1, Xa1, . . . , Xam.
Referring to
When the distance d between the first address electrode and the second address electrode is excessively small, it is likely that a current flows due to a coupling effect between the first address electrode and the second address electrode. On the other hand, when the distance d is excessively large, a user may watch a striped noise in an image displayed on the plasma display panel.
Considering this, the distance d may range from about 50 μm to 300 μm. Further, the distance d may range from about 70 μm to 220 μm.
As illustrated in
During the setup period, the rising signal is supplied to the scan electrode. The rising signal sharply rises from a first voltage V1 to a second voltage V2, and then gradually rises from the second voltage V2 to a third voltage V3. The first voltage V1 may be a ground level voltage GND.
The rising signal generates a weak dark discharge (i.e., a setup discharge) inside the discharge cell during the setup period, thereby accumulating a proper amount of wall charges inside the discharge cell.
During the set-down period, a falling signal of a polarity direction opposite a polarity direction of the rising signal is supplied to the scan electrode. The falling signal gradually falls from a fourth voltage V4 lower than a peak voltage (i.e., the third voltage V3) of the rising signal to a fifth voltage V5.
The falling signal generates a weak erase discharge (i.e., a set-down discharge) inside the discharge cell. Furthermore, the remaining wall charges are uniform inside the discharge cells to the extent that an address discharge can be stably performed.
During an address period which follows the reset period, a scan bias signal, which is maintained at a sixth voltage V6 higher than a lowest voltage (i.e., the fifth voltage V5) of the falling signal, is supplied to the scan electrode. A scan signal, which falls from the scan bias signal by a scan voltage magnitude ΔVy, is supplied to the scan electrode.
A width of a scan signal supplied during an address period of at least one subfield may be different from a width of a scan signal supplied during address periods of the other subfields. For instance, a width of a scan signal in a subfield may be larger than a width of a scan signal in the next subfield in time order. Further, a width of the scan signal may be gradually reduced in the order of 2.6 μs, 2.3 μs, 2.1 μs, 1.9 μs, etc., or in the order of 2.6 μs, 2.3 μs, 2.3 μs, 2.1 μs, . . . , 1.9 μs, 1.9 μs, etc.
As above, when the scan signal is supplied to the scan electrode, a data signal corresponding to the scan signal is supplied to the address electrode. The data signal rises from a ground level voltage GND by a data voltage magnitude ΔVd.
As the voltage difference between the scan signal and the data signal is added to the wall voltage generated during the reset period, the address discharge occurs within the discharge cell to which the data signal is supplied.
A sustain bias signal is supplied to the sustain electrode during the address period to prevent the generation of the unstable address discharge by interference of the sustain electrode Z.
The sustain bias signal is substantially maintained at a sustain bias voltage Vz. The sustain bias voltage Vz is lower than a voltage Vs of a sustain signal and is higher than the ground level voltage GND.
During a sustain period which follows the address period, a sustain signal is alternately supplied to the scan electrode and the sustain electrode. The sustain signal has a voltage magnitude corresponding to the sustain voltage Vs.
As the wall voltage within the discharge cell selected by performing the address discharge is added to the sustain voltage Vs of the sustain signal, every time the sustain signal is supplied, the sustain discharge, i.e., a display discharge occurs between the scan electrode and the sustain electrode.
A plurality of sustain signals are supplied during a sustain period of at least one subfield, and a width of at least one of the plurality of sustain signals may be different from widths of the other sustain signals. For instance, a width of a first supplied sustain signal among the plurality of sustain signals may be larger than widths of the other sustain signals. Hence, a sustain discharge can be more stable.
A discharge gas filled inside the plasma display panel includes helium (He). In addition to He, the discharge gas may further include xenon (Xe) and neon (Ne). Helium (He) can lower a firing voltage, thereby improving the driving efficiency.
A barrier rib in the cases 1 to 4 is formed of PbO—B2O3-SiO2 glass. The barrier rib in the cases 1 to 4 includes lead (Pb) exceeding 1,000 ppm (parts per million), and is called an A-type barrier rib.
Further,
A barrier rib in the cases 5 to 8 includes Pb equal to or less than 1,000 ppm, and is called a B-type barrier rib.
As illustrated in
Further, in the case 3, a consumption power is 215.2 W, an efficiency is 0.997 lm/W, and a luminance is 140 cd/m2. In the case 4, a consumption power is 193 W, an efficiency is 1.21 lm/W, and a luminance is 120 cd/m2. The case 4 including He of 25% has the lower consumption power and the higher efficiency compared with the case 3 not including He.
In other words, helium (He) reduces the consumption power and increases the efficiency regardless of the content of Xe.
Because helium gas acts as a catalyst for a discharge generated inside the discharge cell, the discharge can occur at a relatively low voltage. Hence, in the plasma display panel including helium, the consumption power is reduced and the efficiency increases.
While helium improves the consumption power and the efficiency, helium reduces the luminance. For instance, the cases 2 and 4 including helium of 25% have the lower luminance compared with the cases 1 and 3 not including He.
A reduction in the luminance caused by helium can be prevented by setting a content of Pb in the barrier rib to be equal to or less than 1,000 ppm.
In the case 5, a consumption power is 269 W, an efficiency is 1.121 lm/W, and a luminance is 143 cd/m2.
In the ease 6, a consumption power is 252 W, an efficiency is 1.352 lm/W, and a luminance is 130 cd/m2.
In the case 7, a consumption power is 210.5 W, an efficiency is 1.02 lm/W, and a luminance is 142 cd/m2.
In the case 8, a consumption power is 189.2 W, an efficiency is 1.28 lm/W, and a luminance is 128 cd/m2.
The cases 5 to 8 including the B-type barrier rib have the higher efficiency and the higher luminance compared with the cases 1 to 4 including the A-type barrier rib. In other words, because the B-type barrier rib of the cases 5 to 8 includes a smaller amount of Pb than the A-type barrier rib of the cases 1 to 4, capacitance of the B-type barrier rib is less than capacitance of the A-type barrier rib. Hence, a discharge current decreases and an intensity of a discharge generated by an equal voltage level increases.
As above, when the Pb content of the barrier rib is equal to or less than 1,000 ppm, a reduction in a luminance of a displayed image can be prevented even if the discharge gas includes He.
To prevent the reduction in the luminance caused by helium of the discharge gas, at least one of the barrier rib, the address electrode or the lower dielectric layer may include Pb equal to or less than 1,000 ppm. In this case, a total content of Pb in the plasma display panel is equal to or less than 1,000 ppm.
As illustrated in
In addition to the barrier rib, the address electrode and the lower dielectric layer, at least one of the upper dielectric layer, the scan electrode, the sustain electrode, the front substrate or the rear substrate may include Pb equal to or less than 1,000 ppm. In this case, a total content of Pb in the plasma display panel is equal to or less than 1,000 ppm.
If Pb is accumulated inside the human body, Pb is a toxic material capable of adversely affecting the human body. Accordingly, when the barrier rib includes Pb equal to or less than 1,000 ppm in the plasma display panel according to the exemplary embodiment, an influence of Pb on the human body can be reduced.
When a content of helium changes from 0% to 50% on condition that the discharge gas includes Ne, Xe and helium and a content of Xe is fixed to 15%,
Referring to
When the helium content ranges from 9% to 18%, a consumption power ranges from about 230 W to 265 W.
When the helium content ranges from 18% to 29%, a consumption power ranges from about 178 W to 230 W. When the helium content ranges from 29% to 42%, a consumption power ranges from about 1660 W to 178 W. When the helium content is equal to or more than 50%, a consumption power is about 164 W.
As illustrated in
Referring to
When the helium content ranges from 9% to 18%, a luminance of a displayed image ranges from 133 cd/m2 to 137 cd/m2.
When the helium content ranges from 18% to 29%, a luminance of a displayed image ranges from 129 cd/m2 to 133 cd/m2 and is sufficiently high. When the helium content ranges from 29% to 42%, a luminance of a displayed image ranges from 124 cd/m2 to 129 cd/m2.
When the helium content is equal to or more than 50%, a luminance of a displayed image is sharply reduced to about 112 cd/m2.
As can be seen from
For instance, when the helium content is equal to or less than 10%, the luminance ranges from about 137 cd/m2 to 140 cd/m2 and is sufficiently high. However, the consumption power ranges from about 265 W to 275 W and is excessively high.
When the helium content is equal to or more than 50%, the consumption power is equal to or less than 164 W and is sufficiently low. However, the luminance is equal to or less than 112 cd/m2 and is excessively low.
Accordingly, the helium content may range from 9% to 42% so as to maintain the consumption power at a low level and to increase the luminance. The helium content may range from 18% to 29%.
Since Xe increases the generation amount of vacuum ultraviolet rays inside the discharge cell, Xe can increase a luminance. Accordingly, a reduction in the luminance caused by helium can be compensated due to the control of a Xe content.
When a window pattern image of 25% is displayed on the screen on condition that a discharge gas includes Ne, He and Xe, a content of helium is fixed to 20% and a content of Xe changes from 5% to 25%,
Referring to
When the Xe content is about 10%, a luminance increases to about 353 cd/m2. Since Xe increases the generation amount of vacuum ultraviolet rays during the generation of a discharge, the quantity of light generated in the discharge cell increases due to an increase in the Xe content increases. Hence, the luminance increases.
When the Xe content is 11%, a luminance is about 359 cd/m2. When the Xe content ranges from 12% to 15%, a luminance has a high value ranging from 373 cd/m2 to 390 cd/m2. When the Xe content is equal to or more than 16%, a luminance is about 396 cd/m2.
As can be seen from
As illustrated in
Further, when the Xe content is about 11%, a firing voltage is about 137V. When the Xe content ranges from 12% to 15%, a firing voltage ranges from about 138V to 140V.
When the Xe content ranges from 16% to 20%, a firing voltage ranges from about 141V to 143V. When the Xe content is equal to or more than 25%, a firing voltage sharply increases to a value equal to or more about 153V.
As can be seen from
Accordingly, the discharge gas includes Xe of 10 to 20% so as to maintain a luminance of a displayed image at a sufficiently high level and to prevent an excessive rise in a firing voltage between the scan and sustain electrodes in the structure in which the transparent electrode is omitted. The discharge gas may include Xe of 12 to 15%.
As illustrated in
Black layers 120 and 130 are positioned between the scan and sustain electrodes 102 and 103 and a front substrate 101.
The scan electrode 102 and the sustain electrode 103 may be formed of a metal material, which has excellent conductivity and is easy to mold, for instance, silver (Ag), gold (An), copper (Cu) and aluminum (Al).
The scan and sustain electrodes 102 and 103 having the single-layered structure may be called an ITO-less electrode in which a transparent electrode is omitted.
In
The bus electrodes 402b and 403b may include a substantially opaque material, for instance, at least one of Ag, Au, Cu or Al. The transparent electrodes 402a and 403a may include a substantially transparent material, for instance, indium-tin-oxide (ITO).
Black layers 402a and 403a are formed between the transparent electrodes 402a and 403a and the bus electrodes 402b and 403b to prevent the reflection of external light caused by the bus electrodes 402b and 403b.
A manufacturing method of the scan electrode 402 and the sustain electrode 403 of
A bus electrode layer is formed on the transparent electrodes 402a and 403a. Then, the bus electrode layer is patterned to form the bus electrodes 402b and 403b.
On the other hand, the scan electrode 102 and the sustain electrode 103 of
In
In
As illustrated in
In
The line portions 521a, 521b, 531a and 531b have a predetermined width, respectively. For instance, the first and second line portions 521a and 521b of the scan electrode 102 have widths of W1 and W2, respectively. The first and second line portions 531a and 531b of the sustain electrode 103 have widths of W3 and W4, respectively.
The widths W1, W2, W3 and W4 may have a substantially equal value. At least one of the widths W1, W2, W3 or W4 may have a different value. For instance, the widths W1 and W3 may be about 35 μm, and the widths W2 and W4 may be about 45 μm larger than the widths W1 and W3.
When an interval g3 between the first and second line portions 521a and 521b of the scan electrode 102 and an interval g4 between the first and second line portions 531a and 531b of the sustain electrode 103 are excessively large, it is difficult to diffuse a discharge generated between the scan electrode 102 and the sustain electrode 103 into the second line portion 521b of the scan electrode 102 and the second line portion 531b of the sustain electrode 103. On the other hand, the intervals g3 and g4 are excessively small, it is difficult to diffuse the discharge into the rear of the discharge cell. Accordingly, the intervals g3 and g4 may ranges from about 170 μm to 210 μm, respectively.
To sufficiently diffuse the discharge generated between the scan electrode 102 and the sustain electrode 103 into the rear of the discharge cell, a shortest interval g5 between the second line portion 521b of the scan electrode 102 and the barrier rib 112 in a direction parallel to the address electrode 113 and a shortest interval g6 between the second line portion 531b of the sustain electrode 103 and the barrier rib 112 in a direction parallel to the address electrode 113 may ranges from about 120 μm to 150 μm, respectively.
At least one of the projecting portions 522a, 522b, 522c, 532a, 532b and 532c projects from the line portions 521a, 521b, 531a and 531b toward a central direction of the discharge cell. For instance, the projecting portions 522a and 522b of the scan electrode 102 project from the first line portion 521a toward the central direction of the discharge cell. The projecting portions 532a and 532b of the sustain electrode 103 project from the first line portion 531a toward the central direction of the discharge cell.
The projecting portions 522a, 522b, 522c, 532a, 532b and 532c are spaced apart from each other at a predetermined interval therebetween. For instance, the projecting portions 522a and 522b of the scan electrode 102 are spaced apart from each other at an interval of g1. The projecting portions 532a and 532b of the sustain electrode 103 are spaced apart from each other at an interval of g2. The intervals g1 and g2 may ranges from about 75 μm to 110 μm, respectively, so as to secure the discharge efficiency.
A length of at least one of the projecting portions 522a, 522b, 522c, 532a, 532b and 532c may be different from a length of the other projecting portions. Lengths of the projecting portions each having a different projecting direction may be different from each other. For instance, lengths of the projecting portions 522a and 522b may be different from a length of the projecting portion 522c, and lengths of the projecting portions 532a and 532b may be different from a length of the projecting portion 532c.
The scan electrode 102 and the sustain electrode 103 each include a connection portion for connecting at least two line portions. For instance, the scan electrode 102 includes a connection portion 523 for connecting the first and second line portions 521a and 521b, and the sustain electrode 103 includes a connection portion 533 for connecting the first and second line portions 531a and 531b.
A discharge starts to occur the between the projecting portions 522a and 522b projecting from the first line portion 521a of the scan electrode 102 and the projecting portions 532a and 532b projecting from the first line portion 531a of the sustain electrode 103.
The discharge is diffused into the first line portion 521a of the scan electrode 102 and the first line portion 531a of the sustain electrode 103, and then is diffused into the second line portion 521b of the scan electrode 102 and the second line portion 531b of the sustain electrode 103 through the connection portions 523 and 533.
The discharge diffused into the second line portions 521b and 531b is diffused into the rear of the discharge cell through the projecting portion 522c of the scan electrode 102 and the projecting portion 532c of the sustain electrode 103.
As illustrated in
Further, a portion connecting the projecting portions 521a, 521b, 521c, 531a, 531b and 531c to the line portions 521a, 521b, 531a and 531b may have a curvature.
Further, a portion connecting the line portions 521a, 521b, 531a and 531b to the connection portions 523 and 533 may have a curvature.
As above, when the scan electrode 102 and the sustain electrode 103 each have the portion with the curvature, the scan electrode 102 and the sustain electrode 103 can be manufactured more easily. Further, the excessive accumulation of wall charges on a predetermined portion of the scan electrode 102 and the sustain electrode 103 can be prevented during a driving of the panel, and thus the panel can be stably driven.
In
As above, because the scan electrode 701 and the sustain electrode 702 each include the transparent electrodes 701a and 702a in
In other words, because the scan electrode 701 and the sustain electrode 702 each include the transparent electrodes 701a and 702a in
Accordingly, since the areas of the scan electrode 703 and the sustain electrode 704 having the single-layered structure may be relatively small, a firing voltage between the scan electrode 703 and the sustain electrode 704 in
However, when a discharge gas includes helium in
Accordingly, it is advantageous that the discharge gas includes helium in the plasma display panel in which the scan electrode and the sustain electrode each have the single-layered structure.
As illustrated in
When the interval d is sufficiently large, the quantity of light can increase because the discharge between the scan electrode 102 and the sustain electrode 103 sufficiently uses positive column. On the other hand, when the interval d is sufficiently large, a firing voltage between the scan electrode 102 and the sustain electrode 103 excessively rises.
In other words, as the interval d between the scan electrode 102 and the sustain electrode 103 increases, a luminance of a displayed image increases but the firing voltage between the scan electrode 102 and the sustain electrode 103 rises.
When the interval d is relatively large, the discharge between the scan electrode 102 and the sustain electrode 103 sufficiently uses positive column due to helium of the discharge gas. Accordingly, the luminance can be improved and helium can prevent an excessive rise in the firing voltage between the scan electrode 102 and the sustain electrode 103.
A sign ⊚ indicates an excellent state (i.e., the luminance is very high or the firing voltage is sufficiently low). A sign ◯ indicates a relatively good state. A sign X indicates a bad state (i.e., the luminance is very low or the firing voltage is excessively high).
When an interval d between the scan electrode and the sustain electrode ranges from 50 μm to 70 μm, it is difficult that a discharge between the scan electrode and the sustain electrode sufficiently uses positive column because the interval d is excessively small. Hence, the luminance is very low (i.e., a bad slate of X).
When the interval d ranges from 80 μm to 90 μm, the luminance is a good state of ◯. In this case, because the interval d is relatively small, the luminance may be reduced. However, a reduction level in the luminance may be small.
When the interval d is equal to or more than 100 μm, a discharge between the scan electrode and the sustain electrode sufficiently use positive column because the interval d is sufficiently wide. Hence, the luminance is very high (i.e., an excellent slate of).
When the interval d ranges from 50 μm to 200 μm, the firing voltage is sufficiently low because the interval d is sufficiently small. Hence, the firing voltage is a excellent state of.
When the interval d ranges from 240 μm to 250 μm, the firing voltage is a relatively good state of ∘.
When the interval d ranges from 310 μm to 350 μm, the firing voltage is excessively high because the interval d is excessively wide. Hence, the firing voltage is a bad slate of X.
As can be seen from
As above, when the discharge gas includes helium, the efficiency and the consumption power are improved, but the luminance may be reduced.
A pressure of the discharge gas is adjusted to prevent a reduction in the luminance.
When the pressure of the discharge gas is relatively low, there is a small amount of particles in the discharge gas inside the discharge cell may be relatively small. Accordingly, the amount of ultraviolet rays emitted by the discharge gas during a discharge is relatively small, and thus the luminance may be reduced.
On the other hand, when the pressure of the discharge gas is relatively high, there is a relatively large amount of particles of the discharge gas inside the discharge cell. Accordingly, the amount of ultraviolet rays emitted by the discharge gas during a discharge increases, and thus the luminance may be improved.
A reduction in the luminance caused by helium can be compensated by setting the pressure of the discharge gas including helium to a relatively high value ranging from 400 torr to 500 torr.
The foregoing embodiments and advantages are merely exemplary and are not to be construed as limiting the present invention. The present Leaching can be readily applied to other types of apparatuses. The description of the foregoing embodiments is intended to be illustrative, and not to limit the scope of the claims. Many alternatives, modifications, and variations will be apparent to those skilled in the art.
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