KR20050056739A - Device of the anti-crash in the plasma display panel glass - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel glass crack preventing apparatus, wherein a pattern of an image display on a display panel is provided in a panel glass so as to prevent a local temperature difference caused by a difference in illuminance so that the panel glass is not cracked or broken. A plurality of temperature sensors; A heat conductive sheet to which high temperature is transmitted from the glass of the panel; And an electronic cooling plate disposed between the thermal conductive sheet and the back plate, the electronic cooling plate having a plurality of thermoelectric modules for electronically dissipating the thermal conductive sheet to which the high temperature is transmitted. The temperature difference caused by the color temperature difference between the discharge area and the non-discharge area is locally radiated, thereby effectively preventing cracks or breakage of the panel, thereby improving reliability and durability of the plasma display television.

Description

Plasma display panel glass crack prevention device {Device of the anti-crash in the plasma display panel glass}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel glass crack prevention apparatus, and more particularly, to a plasma display panel glass crack prevention that prevents the panel glass from cracking or breaking due to a local temperature drop due to the color temperature difference of the display panel on which information is displayed. Relates to a device.

Plasma Display Panel (PDP) is an image display device that uses plasma discharge of gas by arranging at least two discharge electrodes, that is, an anode and a cathode, in a discharge space filled with gas. It is in the spotlight as the next generation imaging device.

Such plasma display panels are thin and easy to realize high image quality, and various similar devices are actively developed. Examples of such flat panel display devices include active display devices such as EL, LED, PDP, and LCD, ECD, etc. There is a passive display device of the present invention, and the device covered by the present invention is a PDP display device which is substantially one of the active devices.

As is well known, in the case of a PDP displaying an image signal using three electrodes, that is, a sustain electrode, a write / hold electrode, an addressing electrode, and a fluorescent material, one frame is obtained by sequentially scanning digital image data line by line. It is scanned in a non-interlaced manner to express and displayed on the panel.

Due to the driving characteristics for the display of such a video signal, a considerable amount of heat is generated in the panel, which may cause malfunctions and failures of circuit components and panels. Thus, by dissipating heat generated by panel driving in a general PDP, A cooling fan for cooling the panel is provided.

On the other hand, the PDP is arranged such that the anode and cathode patterns are orthogonal to each other in a matrix form, and display an image by discharge light emission by selective voltage application of the electrode, wherein mercury (Hg) is a means for reducing the sputtering of the electrode. This is because mercury electrons cover the surface of the anode, so sputtering is mercury, which extends the lifetime of the PDP because these particles are continuously returned to the anode.

However, in the PDP as described above, in some screens, the temperature does not increase so that the display cannot be confirmed in some panels, and the color temperature is relatively lowered, causing mercury particles to condense.

In addition, when the PDP receives the airwaves and displays the image P having a constant pattern as shown in FIG. 1 and having a darker color than the surroundings, in the panel 10 in which the dark image P is displayed, the temperature is relatively higher than the surroundings. Since it is lowered due to the condensation of the mercury particles as described above there is a problem that the short circuit between the electrodes is caused to damage the drive circuit and the electrode or crack the panel.

The present invention has been invented in view of the above problems, and an object of the present invention is to prevent the panel glass from cracking or breaking due to a local temperature difference caused by a difference in roughness of an image display pattern on a display panel. The present invention relates to a plasma display panel glass crack prevention device.

In order to achieve the above object, the present invention provides a plasma display television having a panel glass and a back plate, comprising: a plurality of temperature sensors provided in the panel glass; A heat conductive sheet to which high temperature is transmitted from the glass of the panel; The present invention provides a plasma display panel glass crack prevention apparatus including an electronic cooling plate disposed between a heat conduction sheet and a back plate and having a plurality of thermoelectric modules arranged to electrically dissipate a thermally conductive heat conduction sheet.

Particularly, according to the present invention, the temperature sensor may be arranged by dividing the panel glass into a plurality of zones for each zone, and the electronic cooling plate may be divided and operated for each zone in which the temperature sensor is installed.

The present invention has a characteristic of dissipating the glass of a high-temperature plasma display panel using a thermoelectric module by the Peltier effect that the endothermic action occurs from one side when the current is energized to the electronic semiconductor device and the heat absorbed heat from the other side will be.

Hereinafter, with reference to the accompanying drawings, the present invention having the features as described above will be described in detail.

2 is a schematic diagram illustrating a Peltier device, that is, a thermoelectric module 120 applied to the present invention, in which the thermoelectric module 120 is a different type of semiconductor or conductor, as is known, a p-type semiconductor p and an n-type semiconductor. When a current is conducted to the contact point (n), the cooling device module using the Peltier effect generates heat and absorption of heat at the contact point 110 at the same time.

As shown in the drawing, when a current flows in each of the semiconductors n and p, high temperature heat is absorbed from the lower endothermic portion 112. Therefore, in the present invention, a portion corresponding to the endothermic portion 112 is a high temperature plasma. Since the glass is installed adjacent to the glass of the display panel, heat is radiated through the upper insulator 114 and the heat sink 116.

3 is an exploded view of the plasma display television of the present invention in which the thermoelectric module having the above function is installed.

In Fig. 3, the inside of the plasma display television is provided with a mask front 15 that forms an appearance in front of the television, and inside the mask front 15 a screen is displayed and a panel glass 20 for generating high temperature is installed. do.

The panel glass 20 is a screen display means for displaying three image signals using a fluorescent material, in which three electrodes, typically a sustain electrode, a write / hold electrode, and an addressing electrode, are provided.

A back plate 50 is provided at the rear to support the panel glass 20, which is the screen display means, and a back cover 60 for the rear appearance of the plasma display television is provided at the back of the back plate 50. .

On the other hand, between the panel glass 20 and the back plate 50, a heat conductive sheet 30 is installed to absorb the high temperature of the panel glass 20, which is preferably made of an aluminum material, after which It is for constructing a closed circuit for the electronic flow of the thermoelectric module 120 of the electronic cooling plate 40 described.

An electronic cooling plate 40 is installed at the rear of the thermal conductive sheet 30 to electrically transmit and heat the high temperature of the thermal conductive sheet 30. This is the thermoelectric module 120 of the above-described principle is divided into predetermined areas. It is aligned.

An alignment position of the thermoelectric module 120 is to divide the panel glass 20 into a plurality of zones and to arrange the zones of the thermoelectric module 120. The panel glass 20 is configured to adjust the crosstalk of adjacent pixels between the electrodes. In order to prevent this, a partition (not shown) as an insulator is provided.

Based on the partition wall, according to the present invention, a plurality of temperature sensors 25 (refer to FIG. 4) are installed at the rear of the panel glass 20, which may be divided into zones based on the partition walls. It is.

Thus, the local temperature of the panel glass is sensed by the plurality of temperature sensors 25 arranged separately for each zone, and the electronic cooling plate 40 can be operated for each zone according to the sensed temperature. .

The thermoelectric module 120 is disposed on the electronic cooling plate 40, and as shown in FIG. 4, the semiconductor elements p and n constituting the pair of electrodes include the heat absorbing part 112 and the heat sink 116. The heat sink 116 is attached to the electronic cooling plate 40.

Since the electronic cooling plate 40 is configured with an electrode 130 for supplying power to the heat sink 116, the applied external power supplies heat and heat while conducting the thermoelectric module 120 through the electrode 130. As the action occurs, a closed circuit is configured in the thermal conductive sheet 30 so that a current can be conducted in the closed circuit.

The effect of this invention comprised as mentioned above is demonstrated.

When the plasma display television is driven and an image is displayed on the panel glass 20, the digital image data is lined up one line in the panel glass 20 which is generally composed of three electrodes: a sustain electrode, a write / hold electrode, and an addressing electrode. Scanning is sequentially performed to display on a panel by scanning in a non-interlaced manner representing one frame.

Due to the driving characteristics for the display of the video signal, a considerable amount of heat is generated in the panel glass 20.

The generated heat is sensed by the temperature sensor 25 provided for each zone as described above to detect a partial temperature for each zone of the panel glass 20. When the temperature is measured for each zone, the detected temperature information is A predetermined control means (not shown) calculates the mutual temperature difference between the zones based on the partition wall.

For the management of the conventional panel glass 20, if the temperature of a particular zone is more than 10 degrees difference from the surrounding, it is determined that the particular zone is in danger of breakage, and the temperature sensor 25 If a temperature difference between a specific zone occurring in the zone of the zone and its surrounding zone occurs by more than 10 degrees, the control means applies power to the thermoelectric module 120 installed in the electronic cooling plate 40.

In the thermoelectric module 120 to which power is applied, current is applied to the heat sink 116 through the electrode 130 to the thermal conductive sheet 30 through the pair of Peltier elements p and n and the heat absorbing portion 112. Is approved.

A current is conducted to the semiconductors n and p of the thermoelectric module 120 disposed between the heat absorbing part 112 and the heat sink 116, and a current is supplied to the semiconductors forming the pair of thermoelectric modules 120 different from each other. By backing each other, an endothermic phenomenon appears from the contact point 110 of the heat absorbing portion 112.

Due to the endothermic as described above, the high heat emitted from the panel glass 20 is absorbed through the heat conductive sheet 30 and conducted to the electronic cooling plate 40 through the thermoelectric module 120. The current is continuously conducted due to the constant current path formed by the thermal conductive sheet 30 and the thermoelectric module 120 so that the high heat in the panel glass 20 is reduced by the thermal conductive sheet 30 and the electronic cooling plate 40. By forming a cooling path through it will be heat dissipation.

As the current flows in the thermoelectric module 120 installed in each zone due to the local temperature difference sensed by the temperature sensor 25 as described above, the local high heat generated in the panel glass 20 causes the electronic cooling plate 40 to be removed. It is conducted through

The high heat conducted to the electronic cooling plate 40 is finally conducted through the back plate 50 to convection or radiate to the outside through the through hole 65 formed in the back cover 60 to radiate the high heat inside the television. Will be.

As described above, the present invention generates a local temperature difference of the panel glass 20 detected by the temperature sensor 25 disposed separately for each zone, thereby causing a temperature difference such that the panel glass 20 is cracked or broken. In this case, the temperature information sensed by the temperature sensor 25 energizes a current in the thermoelectric module 120 installed at a position corresponding to the temperature sensor 25 in the electronic cooling plate 40, and applies the current to the current. As a result, the thermoelectric module 120 absorbs high heat of the panel glass 20 through the heat conductive sheet 30 to radiate heat to the outside of the back cover 60 through the back plate 50.

By the plasma display panel glass crack prevention apparatus according to the present invention, the temperature difference caused by the color temperature difference between the discharge area and the non-discharge area in the plasma display panel is locally radiated, thereby effectively preventing cracks or breakage of the panel, thereby reducing the plasma display TV. The reliability and durability of the effect is to be improved.

1 is an external perspective view of a typical plasma display panel.

Figure 2 is a schematic diagram for explaining the principle of the Peltier element applied to the present invention.

3 is an exploded view of a plasma display television to which the present invention is applied;

4 is a partial detailed cross-sectional view of FIG. 3.

<Description of the symbols for the main parts of the drawings>

15: mask front 20: panel glass

25: temperature sensor 30: thermal conductive sheet

40: electronic cold plate 50: back plate

60: back cover 120: thermoelectric module

Claims (3)

In the plasma display television provided with the panel glass 20 and the back plate 50, A plurality of temperature sensors 25 provided in the panel glass 20; A heat conductive sheet 30 to which high temperature is transmitted from the panel glass 20; And The electronic cooling plate 40 is installed between the thermal conductive sheet 30 and the back plate 50, and a plurality of thermoelectric modules 120 are disposed to electrically dissipate the thermal conductive sheet 30 to which the high temperature is transmitted. Plasma display panel glass crack prevention apparatus comprising a. The thermoelectric module of claim 1, wherein the temperature sensor 25 divides the panel glass 20 into a plurality of zones, and the thermoelectric module 120 is mounted on the electronic cooling plate 40. Plasma display panel glass crack prevention apparatus, characterized in that installed in the corresponding position of the. 3. The glass display panel as claimed in claim 1 or 2, wherein the electronic cooling plate (40) is divided and operated for each region in which the temperature sensor (25) is installed.