KR100496999B1 - Structure and manvfactare method of pad electrode for plasma display panel - Google Patents

Abstract

The present invention relates to a pad structure and a method of forming a plasma display panel (PDP), and in particular, the operator easily aligns the connector between the connector and the pad electrode portion connected from the panel driving circuit to supply power to the discharge cells of the panel. To achieve this, and to reduce the time during the substrate manufacturing process.

In order to realize this, the present invention extends the electrode to the pad part, and when etching the barrier rib, the electrode is etched to the end of the pad part so that the pad electrode part is concave to be easily coupled to the contactor.

Description

Pad structure and method of forming plasma display panel {Structure and manvfactare method of pad Electrode for Plasma Display Panel}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel (PDP), and more particularly, to a structure and a method of forming a pad electrode portion connected from a panel driving circuit portion to a contactor for supplying power to discharge cells of a PDP panel.

The general color PDP is composed of an upper structure and a lower structure, as shown in FIG. 1, which is composed of a lower substrate 9 and an address electrode 2 formed on the lower substrate 9, The upper structure includes an upper substrate 1, a scan electrode 3 and a common electrode 4 formed on the upper substrate 1, a dielectric layer 5 for holding surface charges generated during the electrode discharge, Comprising a protective layer (6), forming a partition (7) for supporting between the upper substrate 1 and the lower substrate (2), and is formed by applying a phosphor (8) on the surface of the partition (7). .

The driver IC (IC) 10 for driving the PDP is connected to the pad portion 11 of the scan electrode 3 from the outside of the panel as shown in FIG.

At this time, the inert gas is enclosed in the space between the upper structure and the lower structure to form a discharge region.

Such a conventional discharge cell is discharged by applying a high voltage such that discharge occurs to all discharge cells on the panel between the common electrode 4 and the scan electrode 3 at the initial start-up. The charge formed on the surface is erased, and all the discharge cells have a uniform distribution of charge. That is, no charge is retained on the inner surface of the discharge space.

In the next addressing, when an address voltage is applied to cells to be discharged, a discharge occurs between the address electrode 2 and the scan electrode 3 to which the scan voltage is applied. At this time, wall charges are formed on the surface of the protective layer 6 by discharge.

Next, in the sustain period, a sustain voltage is applied between the common electrode 4 and the scan electrode 3, so that discharge continues in a cell in which wall charge is formed. On the other hand, in a cell where no wall charges are formed, a discharge cannot be generated even when a sustain voltage is applied.

Ultraviolet rays are generated in the cells in which discharge occurs, and the ultraviolet rays excite surrounding phosphors 8, and the phosphors generate visible light. The power supply for this operation is supplied to the discharge cells through the flexible wire 12 and the pad electrode 11 on the substrate from the driver IC 10 as a connector.

However, in the conventional PDP substrate structure, the pad electrode 11 is printed in the manufacturing process in order to apply a voltage to the panel, which is inconvenient to perform the printing → drying → firing process of the pad electrode, and the flexible wire 12 ) When the pad electrode 11 is combined, the operator must align it directly and fix it using a tape or the like, but the protrusions are aligned when they are connected to each other because of the protrusion between the flexible wire and the pad electrode. Difficult to align due to the bite occurs, and the contact surface is reduced due to the conductivity problem.

The present invention is invented to solve the problems of the prior art as described above, by etching to the end of the pad portion during the etching of the partition wall to form the pad electrode portion concave, to facilitate the alignment process with the flexible wire and mutually The purpose is to widen the contact surface of the liver and reduce the pad electrode printing process.

The present invention will be described in detail below with reference to the accompanying drawings.

First, referring to the structure of the present invention, as shown in FIG. 4, a flexible wire (not shown) is formed to concave a portion where the electrode 104 of the pad electrode portion 101 of the substrate is formed to transfer power from the driver IC ( 102 is inserted, and the conductive material 103 is filled therebetween so as not to be lifted up with the wire, and the flexible wire is connected to the pad electrode through the conductive material. To improve conductivity.

Looking at the manufacturing process of the substrate for implementing such a structure is to apply a partition wall to the entire surface of the substrate. In addition, the etching process of the partition wall material is performed. At this time, the etching part is extended to the pad electrode part 101 to be etched, and the electrode is simultaneously formed to the pad electrode part 101 which is the end of the substrate, followed by drying and baking. do.

This shortens the printing, drying, and firing process by not performing pad electrode printing, which is conventionally performed separately. When the flexible wire 102 and the pad electrode portion 101 are combined, the wire is inserted into the groove of the pad electrode portion. You can easily align with.

As described above, the pad electrode part structure of the present invention can easily align the flexible wire and the electrode by the operator, and has an effect of reducing the time during the manufacturing process.

1 is an exploded perspective view of a general upper and lower substrate.

2 is a schematic diagram of electrode formation on a panel;

Figure 3 is a conventional structure of the pad unit and the power supply unit combined.

4 is a structural view of the pad unit and the power supply unit combined according to the present invention.

*** Explanation of symbols for the main parts of the drawing ***

101: pad electrode portion 102: flexible wire

103 conductive material 104 electrode

Claims (3)

In the pad electrode connection structure is located on the outer periphery of the substrate, the pad electrode connection structure consisting of a connector coupled to the pad electrode for applying power on the substrate, The pad electrode portion is formed at the end of the substrate, The electrodes of the pad electrode portion are separated by a barrier rib formed on the substrate, and the end of the barrier rib portion is formed to have a curved surface by being concavely etched from the electrode end of the pad electrode portion. Pad electrode part structure. Plasma displays in which electrodes of a predetermined interval are formed on the substrate, barrier ribs are formed in parallel with the electrodes to prevent plasma diffusion between discharge cells adjacent to the electrodes, and pad electrodes are formed outside the substrate to apply power to the electrodes. In the manufacturing method of the panel, Applying a partition on the entire surface of the substrate; Etching the coated barrier rib end to have a curved surface at a portion where the electrode end of the pad electrode part is to be located; And forming the electrode up to an end of the concave etched pad electrode portion. The method of claim 2, The concave etched pad electrode portion is filled with a conductive material, characterized in that the pad electrode portion forming method of the plasma display panel.

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