Electric lamp and discharge devices – With gas or vapor – Three or more electrode discharge device
Reexamination Certificate
1998-07-21
2003-03-25
Patel, Nimeshkumar D. (Department: 2879)
Electric lamp and discharge devices
With gas or vapor
Three or more electrode discharge device
C313S495000, C313S586000, C313S496000, C445S024000, C445S025000
Reexamination Certificate
active
06538380
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to a Plasma Display Panel, hereinafter referred to as a PDP, which is a kind of thin display devices.
2. Description of the Related Arts
PDPs excel in the visual sensation because PDPs are of a self-luminescent type, and is comparatively easy to accomplish a large and high-speed display which suits television displays. Especially, surface discharge type PDPs are suitable for a color display by the use of fluorescent materials.
Large screen size is one of demands from the market for the PDP. In order to satisfy this demand, the development of the structure and the PDP manufacturing method suitable for a large panel has been progressing.
PDPs have discharge spaces therein arranged on a substantially flat plane. The panel envelope to form the external outline is provided by a pair of substrates opposed from each other via the discharge space. At least the substrate on the front side must be transparent. Soda lime glass plates are usually used for the substrates on the front side and the back side.
In a PDP display method where a lot of discharge cells arranged in a matrix emit lights selectively, there are separator walls, which are often called ribs, to define the discharge spaces.
The height of the separator walls is equal to the gap clearance of the discharge spaces. For instance, in a surface discharge type PDP where the display electrodes to form the discharge electrode pairs are arranged in mutually adjacent and parallel relationship, the separator walls lie straight on a plane and are provided at equal intervals in the direction of the line of the display, i.e. in the direction along which the display electrodes extend. Spread of the discharge is limited by the separator walls, whereby discrete discharge cells are defined. Accordingly, an accurate matrix display is accomplished.
Moreover, the separator walls play the role of distance pieces, i.e., spacers, to provide equal gap clearance of the discharge spaces all over the display area, in which an unequal clearance may affect the discharge condition.
The manufacturing process of a PDP is divided roughly into three processes. That is, PDP is completed after sequentially undergoing a process by which predetermined composition elements are formed on each substrate so as to make the front panel and the back panel, a process in which the front panel, and the back panel thus made respectively in this manner, are combined (sealed) with each other, and a process to fill a discharge gas therein after cleaning the inside. Usually, the front panel and the back panel are manufactured in parallel.
Main composition elements in surface discharge type PDPs are, for example, display electrodes, a dielectric layer for the AC drive, a dielectric layer protection film, electrodes for addressing the discharge cell to be lit, separator walls, and fluorescent material layers.
The formation of these composition elements accompanies heat processes. For example, in forming the display electrodes, the substrate is heated at a sputtering or vacuum evaporation of a film forming process of the conductive layer. Moreover, in forming the dielectric layer, a thick film material, represented by a low melting point glass, is heated so as to melt.
In forming plural composition elements sequentially on the same substrate, in the prior art, the material and the heat process condition of each composition element were selected so as to allow no influences, such as the deformation or change in quality, on the previously formed composition elements. For example, in the case where the heating is performed two times, the heating temperature of the second time is chosen lower than the heating temperature of the first time; and accordingly, the materials to be heated are chosen to correspond to the required heating temperatures.
In manufacturing PDPs as mentioned above, whenever the composition element is formed the substrate is expanded and contracted. Therefore, in mass-production, most substrates are in a warped state when each panel is finished, even if a smooth substrate is employed for the front panel or the back panel. The warp of the substrate becomes remarkable as the PDP screen size, i.e. the outline dimension of the substrate, becomes larger.
In prior arts, the direction of the warp of the substrate was irregular. That is, sometimes the inner surface on which the composition elements have been formed becomes convex, which is referred to hereinafter as a “warp in a positive direction”; or sometimes, on the contrary, the warp is such that the inner surface becomes concave, which is referred to hereinafter as a “warp in a negative direction”. Therefore, there were problems as follows.
FIGS. 1A
to
1
C schematically illustrate a cross-sectional view of panel shapes in the prior art sealing steps. In
FIGS. 1A
to
1
C, there are partially omitted the composition elements in order to make the figure simple, and the warp of the substrate is exaggerated.
The problem of the prior arts are hereinafter explained together with the procedure of the sealing process. A glass substrate
110
having a display electrode
120
thereon and a glass substrate
210
having plural separator walls
290
thereon are sealed with each other. Prior to the sealing operation, low melting-point glass layers
310
as the sealant are placed on the edges of glass substrate
210
, the thickness of the low melting point glass layers
310
being chosen to be higher than the height of separator walls
290
.
Glass substrate
110
and glass substrate
210
are stacked with each other as shown in FIG.
1
(
a
). The pair of glass substrates
110
&
210
is heated while pressed to each other so that low melting-point glass layer
310
is melted. Subsequently, the substrate temperature is lowered so that glass substrate
110
and glass substrate
210
are sealed with each other as shown in FIG.
1
B.
If there is a warp in a negative direction on glass substrate
110
at the time of starting such sealing process, a gap g is undesirably created between separator walls
290
and the inner surface of the glass substrate
110
unless a warp in a positive direction to counter the warp of the glass substrate
110
is on the opposite glass substrate
210
having separator walls
290
. In the example of
FIGS. 1A and 1B
the gap g is created because glass substrate
210
is flat.
When a PDP is completed after a discharge gas is filled therein as shown in FIG.
1
(
c
), the warped state is such that the central portion of glass substrate
110
is depressed due to a low internal pressure of about 500 Torr. (=66,700 Pa), which is lower than the standard atmospheric pressure 760 Torr (=101,325 Pa). The gap g does not completely disappear even though the deformation of glass substrate
110
allows the gap to become smaller than that at the beginning of the sealing operation. Therefore, there was a problem in that the display fell into disorder by the generation of so-called cross-talk caused from an excessive spread of the electrical discharge through the gap g between the substrate and the top of separator walls.
Moreover, when the degree of the warp of the glass substrate was large, there was another problem in that the glass substrate cracked at the sealing process, or cracked afterwards during the step of connecting an external driving circuit thereto, that is connection of flexible cable by an application of mechanical pressure thereover.
In addition, even in the case having no gap g, if the PDP is used in an environment where the external air pressure is lower than the standard atmospheric pressure, the center surfaces of glass substrates
110
&
210
, defining the panel envelope, projected toward the outside to cause the increase in the substrates' gap, resulting in the gap g between the substrate and the top of separator wall. That is, the problem was also in that the atmospheric pressure range in which the PDP can properly operate was limited.
SUMMARY OF THE INVENTION
It is a general object of the present
Amatsu Masashi
Kanagu Shinji
Fujitsu Limited
Patel Nimeshkumar D.
Santiago Mariceli
Staas & Halsey , LLP
LandOfFree
Plasma display panels with convex surface does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with Plasma display panels with convex surface, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Plasma display panels with convex surface will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-3081137