KR100585530B1 - Plasma Display Equipment - Google Patents

Abstract

The present invention relates to a plasma display device that can improve production yield and reduce manufacturing costs according to the ease of a manufacturing process.

The present invention includes a plasma display panel in which a front panel and a rear panel are sealed to each other, an outer case including a front cabinet for protecting the plasma display panel, and a driving circuit board for driving and controlling the plasma display panel. In the plasma display device, the front panel has a film filter formed by stacking a plurality of functional film layers on a top surface thereof, and a panel length in a direction in which a ground plane for electromagnetic shielding is formed is equal to the length of the rear panel. Is formed identically.

Description

Plasma Display Equipment {Plasma Display Equipment}

1 is a schematic view showing the structure of a conventional plasma display device.

2 is a schematic view showing a filter structure of a conventional plasma display panel.

3 is a schematic view of a plasma display device in which a conventional film filter is formed.

4 schematically illustrates the structure of a plasma display device according to the present invention;

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

110,210: Case 120,220: PDP

130,230: driver circuit board 140,240: heat sink

150,250 Front filter 160 Finger spring gasket

170,270: filter support 180,280: module supporter

The present invention relates to a plasma display device, and more particularly, to a plasma display device having a different structure of a front panel.

In general, a plasma display device has a partition wall formed between a front panel and a rear panel of soda-lime glass, forming one unit cell, and in each cell, helium-xenon (He-Xe) and helium-neon. When an inert gas such as (He-Ne) is discharged by a high frequency voltage, vacuum ultraviolet rays are generated to emit an image of the phosphor formed between the partition walls.

1 is a structure schematically showing the structure of a conventional plasma display device. As shown, the plasma display device excites the phosphor with a case 110 including a front cabinet 111 and a back cover 112 for determining the appearance, and vacuum ultraviolet rays caused by gas discharge inside the case. Plasma Display Panel 120 (hereinafter referred to as PDP) for realizing an image, a driving circuit board 130 including a PCB to drive and control the PDP, and a plasma connected to the driving circuit board A filter (150) and the filter (150) formed by attaching a film to a transparent glass substrate (not shown) with a predetermined distance to the front surface of the PDP and a heat dissipation plate (140) for dissipating heat generated when the display device is driven. Finger spring gasket (160) and filter supporter (170), which are electrically connected to the metal back cover, and the PDP including the driving circuit board. It is composed of a module supporter (Module Supporter, 180).

The plasma display device having such a structure emits more electromagnetic waves to the front of the panel glass than the color cathode ray tube (CRT) or the liquid crystal display panel (LCD) because the image is generated by applying high voltage and high frequency for plasma discharge. There is this. In addition, the plasma display device emits near infrared rays (NIR) derived from an inert gas such as Ne and Xe. Such near infrared rays are very close to the wavelength of a remote controller of a home appliance, causing a malfunction. In addition, as in the CRT or LCD, there is a problem of glare of the user due to external light, and there are general problems such as contrast degradation, which is a quality characteristic of other display devices.

Therefore, in the conventional plasma display device, as shown in FIG. 2, a filter having a predetermined function is formed on the entire surface of the PDP.

2 shows a filter structure of a conventional plasma display device. As shown, a first functional film, that is, an antireflection film layer (AR Film) 152, is formed on the transparent glass substrate 151 formed at a predetermined distance from the PDP 120, and is adjacent to the transparent glass substrate. The second functional film, that is, the color die film layer (Color-dye) 153, the third functional film, that is, the electromagnetic shielding film layer (EMI Film, 154), which controls the NIR shielding and color, is sequentially It is formed to form a filter (150). In particular, the transparent glass substrate 151 serves as a base for forming a filter and also serves to protect the PDP from an external impact. Thus, the filter including the transparent glass substrate 151 in the filter of the plasma display device Is referred to as a 'glass filter'.

In the glass filter 150, when the viewers look at the screen, a portion other than the effective screen is processed to black on the transparent glass substrate 151 in order to increase the viewing effect. The black handled in this way is referred to as a black frame 151a.

On the other hand, the glass filter to protect the impact from the outside as described above is made larger than the size of the PDP front panel is not a big problem in the black frame formation to define the effective screen and the grounding process for shielding the electromagnetic waves.

However, since the film filter formed by stacking a plurality of functional film layers is manufactured to be the same size as the front panel of the PDP, difficulties arise in a black frame for defining an effective screen and a grounding process for shielding electromagnetic waves. This will be described with reference to FIG. 3.

3 is a diagram illustrating a schematic structure of a plasma display device having a conventional film filter. As shown, the plasma display device including the conventional film filter is directly attached to the film filter 150 formed by stacking a plurality of functional film layers on the PDP front panel 121, the film filter 150 is a conventional glass Like the filter, it includes an electromagnetic shielding film layer 154, a color die film layer 153, and an antireflective film layer 152.

Looking at the grounding process for shielding the black frame and electromagnetic waves of the plasma display device having such a structure is as follows.

First, the electromagnetic shielding film layer 154 is formed of a copper mesh type (Cu-Mesh Type) through a predetermined exposure process, the effective screen region divided into a black frame. Thereafter, the electromagnetic shielding film layer 154 of the effective screen portion is plated with a non-conductive material 154a and blackened. That is, instead of plating the entire surface of the electromagnetic wave shielding film layer, only a predetermined portion of the electromagnetic wave shielding film layer is plated to blacken to secure a ground plane.

However, since the blackening process has to be performed in a limited area, the difficulty of the process is high, and if the attention is not required, the electromagnetic shielding function due to the inability to secure the ground plane is not properly performed, thereby degrading the quality of the plasma display device.

On the other hand, the black frame 151a for defining the effective screen is formed by attaching a film type on the blackened electromagnetic shielding film layer 154, and the width of the black frame must be formed in a limited area. Too narrow, the outer case of the plasma display panel is designed according to the design constraints are also a problem that follows.

Therefore, in order to solve the above problems, the present invention provides a degree of freedom in designing an outer case by varying the front panel structure of the plasma display device to secure a sufficient ground plane for shielding electromagnetic waves and to widen the width of the black frame to define an effective screen. It is an object of the present invention to provide a plasma display device that can be increased.

The present invention for solving the above technical problem is the front panel and the rear panel is sealed to each other plasma display panel, an outer case including a front cabinet for protecting the plasma display panel, drive, control the plasma display panel In a plasma display device including a driving circuit board, the front panel has a film filter formed by stacking a plurality of functional film layers on a top surface thereof, and a panel in a direction in which a ground plane for electromagnetic shielding is formed. The length is formed equal to the length of the back panel.

An edge of the front cabinet that protects the plasma display panel is located outside the point where the front panel and the rear panel are sealed.

The length of the electromagnetic wave shielding film layer in the ground plane forming direction of the plurality of functional film layers is formed longer than the length of the other functional film layer in the ground plane forming direction.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

4 is a schematic view showing the structure of a plasma display device according to the present invention. Referring to FIG. 4, the plasma display device of the present invention includes a case 210 including a front cabinet 211 and a back cover 212 for determining an appearance, and a front panel and a rear panel coupled to the inside of the case. Plasma display panel 220 (hereinafter referred to as PDP) for exciting an phosphor by vacuum ultraviolet rays caused by gas discharge, and a driving circuit board 230 including a PCB to drive and control the PDP. ), A heat sink 240 for dissipating heat generated when the plasma display device is driven and connected to the driving circuit board, and a film filter formed by stacking functional film layers having a predetermined function on the front panel of the PDP. A filter supporter (270) for supporting the film filter 250 and the film filter 250 and an electrical connection with the metal back cover, and a PDP including the driving circuit board are supported. It consists of a module support (Module Supporter, 280).

In the plasma display device of the present invention having such a structure, in particular, the horizontal length of the front panel is longer than the horizontal length of the conventional front panel 221. That is, the length of the panel in the direction in which the ground plane is formed for the electromagnetic shielding is the same as the length of the rear panel 222 so as to be larger than the length of the front panel in the conventional horizontal direction.

Meanwhile, the film filter attached to the top surface of the front panel includes an electromagnetic shielding film layer 254, a color die film layer 253, an antireflection film layer 252, and the like, which are functional film layers, and the electromagnetic shielding film layer 254. ) Is longer than the length of the other functional film layer in the ground plane formation direction. This is to secure a ground plane for shielding electromagnetic waves in the plasma display device manufacturing method to be described later.

In this way, the film filter 250 is attached to the upper surface, the front panel 221 having the same length as the horizontal length of the rear panel can secure a sufficient ground plane for shielding the electromagnetic waves, the width of the black frame 251a It can be wider than the conventional one can also sufficiently increase the design freedom of the outer case for protecting the PDP.

A plasma display device manufacturing method of the present invention having such a structure will be described below.

As shown, first, the front panel 221 and the rear panel 222 having a soda-lime glass material are molded. At this time, the front panel 221 is molded so that the length of the panel in the direction in which the ground plane is formed for electromagnetic shielding to be the same as the length of the rear panel 222.

Separately, a plurality of functional film layers having a predetermined function to be attached to the PDP front panel are stacked to form a film filter 250. The film filter manufacturing process is as follows.

First, the electromagnetic shielding film layer 254 is formed in a film shape having the same width as that of the front panel 221 by using an electron beam deposition method, a sputtering method, a wet coating method, or the like on a matrix (PET) copper (Cu) material. At this time, the effective screen portion is formed in a mesh type through a predetermined exposure process to increase the transmittance, and the portion of the electromagnetic shielding film layer in which the same effective screen is determined as before is plated with a non-conductive material 254a and blackened. .

Therefore, securing the non-plated ineffective surface, that is, the ground plane for shielding electromagnetic waves can be secured more than in the prior art.

Subsequently, the color die film layer 253 and the anti-reflection film layer 252 which are shorter than the length of the electromagnetic wave shielding film layer in the ground plane formation direction of the electromagnetic wave shielding film layer 254 are sequentially laminated to the film filter. 250 is formed.

On the other hand, the black frame 251a for determining the effective screen is attached in the form of a film on the electromagnetic shielding film layer 254, the black frame 251a because the size of the film filter is wider than the conventional black frame The design freedom of the width is increased, so that it can be easily formed.

The film filter 250 including the black frame is attached to the PDP front panel 221 using a laminating method or the like.

Thereafter, the front panel 221 and the rear panel 222 on which the film filter is formed are aligned at a position and sealed 220a, and a grounding process is performed using a grounding means such as a filter support for shielding the remaining electromagnetic waves. The process of installing the driving circuit board 230 and the heat sink 240 for driving the PDP is performed in the same manner as in the related art. However, as described above, since the front cabinet 211 for protecting the PDP has a higher degree of freedom in designing the black frame width, the front frame 211 is formed to have a wider width and the bezel (211) of the front cabinet, that is, To reduce the width of the front cabinet edges. Accordingly, in the present invention, the edge 211a of the front panel of the plasma display device is positioned outside the ground plane formation direction at the point where the front panel 221 and the rear panel 222 are sealed.

As described above, according to the present invention, by changing the structure of the front panel, a predetermined process performed using the front panel can be made more easily, and the edge of the outer case for protecting the PDP is reduced, thereby reducing the overall plasma display. It is possible to reduce the manufacturing cost of manufacturing the device.

As described above, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features.

Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the appended claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

As described above, according to the present invention, it is possible to easily form a black frame for determining an effective screen of the plasma display device and to secure a ground plane for shielding electromagnetic waves, thereby improving production yield and reducing overall manufacturing cost. It has an effect.

Claims (3)

In a plasma display device including a plasma display panel having a front panel and a rear panel sealed to each other, an outer case including a front cabinet for protecting the plasma display panel, and a driving circuit board for driving and controlling the plasma display panel. , The front panel A film filter formed by laminating a plurality of functional film layers on the upper surface is directly attached; And a panel length in a direction in which a ground plane for shielding electromagnetic waves is formed is equal to the length of the rear panel. The method of claim 1, And an edge of the front cabinet which protects the plasma display panel is located outside in the direction of forming the ground plane at the point where the front panel and the rear panel are sealed. The method of claim 1, And a length of the electromagnetic wave shielding film layer in the ground plane forming direction of the plurality of functional film layers is longer than a length of the other functional film layer in the ground plane forming direction.

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