KR20060084619A - Plasma display device - Google Patents

Abstract

In the plasma display device according to the present invention, an image is implemented, the sustain electrode pairs each consisting of a pair of common electrodes and scan electrodes spaced apart from each other by a discharge gap, and an address extending in a direction crossing the sustain electrode pairs. A plasma display panel having electrodes; A chassis base disposed at the rear of the plasma display panel; A circuit unit driving a plasma display panel; And a flexible printed cable provided at the circuit part to electrically connect them between the scan electrode driving substrate for applying the discharge pulse to the scan electrodes and the scan electrodes, and both ends of which are respectively connected to the scan electrode driving substrate and the scan electrodes. And scan side connection members each having at least one scan driving integrated circuit mounted on the flexible printed cable and arranged spaced apart from each other.

Description

Plasma display apparatus

1 is an exploded perspective view showing a plasma display device according to an embodiment of the present invention.

FIG. 2 is a partial perspective view illustrating an example of the plasma display panel shown in FIG. 1.

3 is a cross-sectional view taken along line III-III of FIG. 1;

<Brief description of the major symbols in the drawings>

110. Plasma display panel 140. Chassis base

150. Circuit part 151 Power board

152. Logic substrate 153 Drive substrate for common electrode

154. Drive substrate for scan electrodes 155 Drive substrate for address electrodes

161. Scanning side connection member 170. Cover member

The present invention relates to a plasma display device, and more particularly, to a plasma display device having an improved structure so that the number of printed circuit boards constituting a circuit part can be optimized.

Plasma display device is a flat panel display that displays images by using gas discharge phenomenon. It is excellent in various display ability such as display capacity, brightness, contrast, afterimage and viewing angle, and it is possible to replace cathode ray tube with thin and large display. It is in the spotlight as the next generation flat panel display.

The plasma display apparatus includes a plasma display panel, a chassis base disposed in parallel with the plasma display panel, a circuit unit mounted behind the chassis base to drive the plasma display panel, the plasma display panel, It is common to include a chassis base and a case for accommodating the circuit portion.

The circuit part is provided with printed circuit boards to drive the plasma display panel. The circuit part has a power supply board that functions to receive power from the outside and convert it into a power source of a required type, and a video signal supplied from the outside. Logic substrates that perform a function of generating a driving control signal by operation, and driving substrates for electrodes that are connected by electrodes and a connecting member and serve to apply a discharge pulse to the electrodes are included.

In addition, it is common to further include a buffer board that functions to temporarily store data between the driving substrate for the electrode and the electrodes. As the number of printed circuit boards increases, the cost accordingly This increases, and since the space for mounting the printed circuit board should be sufficiently secured, the number of printed circuit boards needs to be optimized.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and an object thereof is to provide a plasma display apparatus in which cost can be reduced by optimizing the number of printed circuit boards constituting a circuit unit.

Plasma display device according to the present invention for achieving the above object,

A plasma display panel in which an image is realized, the sustain electrode pairs each consisting of a pair of common electrodes and scan electrodes spaced apart from each other by a discharge gap, and address electrodes extending in a direction crossing the sustain electrode pairs; A chassis base disposed behind the plasma display panel; A circuit unit driving the plasma display panel; And a flexible printed circuit provided at the circuit unit and electrically connecting them between the scan electrode driving substrate for applying discharge pulses to the scan electrodes and the scan electrodes, and both ends of which are connected to the scan electrode driving substrate and the scan electrodes, respectively. And a scan side connection member each having a cable and at least one scan driving integrated circuit mounted on the flexible printed cable and arranged to be spaced apart from each other.

The driving electrode for the scan electrode provided in the circuit unit may include a power supply board that receives power from an external source and converts the power into a power source of a required type, and a driving control signal by performing a logical operation on an image signal connected to the power supply board and supplied from the outside. It is preferred to be connected to a logic substrate that generates a.

Here, the scan driving integrated circuit provided in the scan side connecting member is preferably covered by a cover member.

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

1 is an exploded perspective view of a plasma display device according to an exemplary embodiment of the present invention, and FIG. 2 is a partially separated perspective view of an example of the plasma display panel shown in FIG. 1.

Referring to FIG. 1, the plasma display apparatus 100 according to an exemplary embodiment includes a plasma display panel 110 in which an image is realized by gas discharge.

Any one of various plasma display panels may be employed as the plasma display panel 110. As an example, an AC plasma display panel having a surface discharge type 3-electrode structure as shown in FIG. 2 is employed. Can be.

As illustrated, the plasma display panel 110 includes a front panel 120 and a rear panel 130 which is coupled to face the front panel 120.

The front panel 120 includes a front substrate 121 disposed in front and a pair of common electrodes 123 and scan electrodes 124 formed on a rear surface of the front substrate 121 and spaced apart from each other by a discharge gap. Each of the sustain electrode pairs 122, a front dielectric layer 125 formed to cover the sustain electrode pairs 122, and a passivation layer 126 formed on a rear surface of the front dielectric layer 125. The common electrode 123 includes a common transparent electrode 123a and a common bus electrode 123b formed to be connected thereto. Similarly, the scan electrode 124 is also formed to be connected to the scan transparent electrode 124a. The scan bus electrode 124b is provided.

The back panel 130 is formed on a rear substrate 131 disposed at a rear side and an address electrode formed on a front surface of the rear substrate 131 and extending in a direction crossing the storage electrode pairs 122. 132, a back dielectric layer 133 formed to cover the address electrodes 132, barrier ribs 134 formed on the back dielectric layer 133 to define discharge spaces 135, and the discharge spaces. Phosphor layer 136 disposed in the 135 and discharge gas filled in the discharge spaces 135. The barrier ribs 134 extend in parallel with each other with at least one address electrode 132 interposed therebetween, so that the regions where the storage electrode pairs 122 and the address electrodes 132 intersect are respectively discharge spaces 135. It is formed to correspond to.

The chassis base 140 is disposed behind the plasma display panel 110. The chassis base 140 is formed of a material such as aluminum to support the plasma display panel 110 and receive heat generated from the plasma display panel 110 to release the heat to the outside. The chassis base 140 may be provided with a bent portion 141 formed such that the edge of the chassis base 140 is bent backward so that bending or bending deformation may be prevented.

As shown in FIG. 3, the chassis base 140 may be coupled to the plasma display panel 110 by an adhesive member 143 such as a double-sided tape. The chassis base 140 and the plasma display panel 110 may be combined with each other. The heat radiating member 144 is interposed therebetween so that heat generated from the plasma display panel 110 may be discharged to the outside.

The circuit unit 150 including various electronic components is installed at the rear of the chassis base 140 to drive the plasma display panel 110. The circuit unit 150 is the plasma display panel 110 and the chassis base 140. ) Is accommodated by a case provided with a front cover and a back cover, which are not shown, to configure the plasma display apparatus 100.

The circuit unit 150 includes a plurality of printed circuit boards 151, 152, 153, 154 and 155 electrically connected to each other to drive the plasma display panel 110. That is, the circuit unit 150 receives power from the outside and converts it into a power of a required type. A logic substrate 152 that is in operation to convert the driving control signal into a driving control signal in accordance with the driving method of the plasma display panel 110, and is connected to the power substrate 151 and the logic substrate 152, and has electrodes 123, 124, and 132. ) Includes a common electrode driving substrate 153, a scan electrode driving substrate 154, and an address electrode driving substrate 155.

As shown in the drawing, an upper portion of the chassis base 140 corresponds to the power substrate 151 and a lower portion of the chassis base 140 corresponds to the logic substrate 152. The right side at the edge of the chassis base 140 corresponds to the driving substrate 153 for the common electrode applying the discharge pulse to the common electrodes 123, and is located at the left side of the edge of the chassis base 140. This corresponds to the scan electrode driving substrate 154 that applies the discharge pulse to the scan electrodes 124, and the lower one at the edge of the chassis base 140 applies the discharge pulse to the address electrodes 132. This corresponds to the address electrode driving substrate 155. On the other hand, the position of the above-described printed circuit board is an example and is not necessarily limited to the illustrated.

According to an aspect of the present invention among the driving substrates 153, 154, and 155 for electrodes, the circuit unit 150 configured as described above may scan data by temporarily storing data from a driving substrate for scanning electrodes. Since the scan buffer substrate, which is provided to perform the function of transmitting to the substrate, is omitted, the scan electrodes 124 and the driving substrate for the scan electrodes 154 may be directly electrically connected by the scan side connecting members 161. It is supposed to be. Instead of omitting the scan buffer substrate as described above, a scan in which a scan driving integrated circuit 161b that is conventionally provided in the scan buffer substrate directly connects the scan electrodes 124 and the scan electrode driving substrate 154. At least one side connection member 161 is provided. That is, the scan side connecting member 161 electrically connecting the scan electrodes 124 and the driving substrate 154 for the scan electrodes has a scan driving integrated circuit 161b connected to the flexible printed cable 161a. At least one is mounted and packaged.

As described above, as the scan buffer substrate is omitted, the number of printed circuit boards 151, 152, 153, 154, and 155 provided in the circuit unit 150 may be reduced as compared with the related art, and thus cost reduction may be achieved. In addition, a sufficient space for mounting the printed circuit boards 151, 152, 153, 154, and 155 may be secured to facilitate installation of the printed circuit boards 151, 152, 153, 154, and 155, and design constraints of the printed circuit boards 151, 152, 153, 154, and 155 may be reduced. Can be.

The scan side connecting members 161 electrically connecting the scan electrodes 124 and the driving substrate 154 for the scan electrodes are arranged to be spaced apart from each other at the left edge of the chassis base 140. The scan driving integrated circuits 161b mounted on the members 161 may be arranged to be supported by the bent portion 141 formed by bending backward from the edge of the chassis base 140. The scan driving integrated circuits 161b of the scan side connection members 161 disposed as described above are coupled to the bent portion 141 of the chassis base 140 by a screw member 172 or the like and fixed to the cover member 170. Can be covered and protected. The cover member 170 may also receive and release heat generated from the scan driving integrated circuit 161b. The cover member 170 is opposite to the scan driving integrated circuits 161b as shown, while being bent forward from the edges of the opposing surfaces to cover the sides of the chassis base 140 and the plasma display panel 110. It may be made of a structure that can be wrapped, but is not limited thereto.

The scan driving integrated circuits 161b covered by the cover member 170 as described above may protrude from the flexible printed cable 161a toward the cover member 170. The scan driving integrated circuits protruding in this way may be disposed. As shown in FIG. 3, grooves 171 may be formed on a surface of the cover member 170 that faces the scan driving integrated circuits 161b so that the 161b may be accommodated and protected, respectively. Here, the grooves 171 may have a shape in which their inner surfaces are closed, and the grooves 171 may be maintained at predetermined intervals between the inner surfaces of the grooves 171 and the outer surfaces of the scan driving integrated circuit 161b. It can be formed in size. On the other hand, the groove is not limited to the illustrated, it may be provided in one structure having two elements are accommodated in both.

The first thermal conductive medium 181 may be disposed in the groove 171 having the above structure in a state where the scan driving integrated circuit 161b is accommodated. The first thermal conductive medium 181 may be a liquid or gel-type thermal conductivity such as grease to completely fill the space between the protruding outer surface of the scan driving integrated circuit 161b and the inner surface of the groove 171. The medium is preferably used, but is not limited thereto. A second heat conducting medium 182 may be further disposed on the opposite side of the scan driving integrated circuit 161b. That is, the second thermal conductive medium 182 is disposed between the opposite side of the scan driving integrated circuit 161b and the bent portion 141 of the chassis base 140, and the second thermal conductive medium 182 may cushion the shock. A sheet-type thermal conductive medium or a liquid or gel-type thermal conductive medium formed of a material which can be used may be used.

As the first and second thermal conductive mediums 181 and 182 are disposed on both sides of the scan driving integrated circuits 161b as described above, heat generated from the scan driving integrated circuits 161b passes through the first thermal conductive medium 181. The lower surface is transferred to the cover member 170, and then transferred to the chassis base 140 via the second thermal conductive medium 182, and then may be diverged by heat exchange with ambient air. Accordingly, the operational reliability of the scan driving integrated circuits 161b can be sufficiently secured.

Meanwhile, as illustrated, the common side connecting members 162 electrically connecting the common electrodes 123 and the driving substrate 153 for the common electrodes may be formed of flexible printed cables. In addition, the address side connecting members 163 electrically connecting the address electrodes 132 and the address electrode driving substrate 155 may be electrically connected between the scan electrode driving substrate 154 and the scan electrodes 124. Like the scan-side connecting member 161 connected to each other, the address driving integrated circuit 163b may be mounted on the flexible printed cable 162a, but is not necessarily limited thereto. The address side connecting members 163 as described above may be protected and dissipated by installing a cover member 170 ′ as installed in the scan side connecting members 161 described above.

As described above, according to the present invention, as the scan buffer substrate is omitted, the number of printed circuit boards provided in the circuit unit may be reduced as a whole, thereby reducing costs. In addition, a sufficient space for mounting the printed circuit boards may be secured. Accordingly, the printed circuit boards can be easily installed, and the design constraints of the printed circuit boards can be reduced.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, this is merely exemplary, and various modifications and equivalent other embodiments are possible to those skilled in the art. I can understand. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

Claims (11)

A plasma display panel in which an image is realized, the sustain electrode pairs each consisting of a pair of common electrodes and scan electrodes spaced apart from each other by a discharge gap, and address electrodes extending in a direction crossing the sustain electrode pairs; A chassis base disposed behind the plasma display panel; A circuit unit driving the plasma display panel; And A flexible printed cable provided at the circuit unit and electrically connected between the scan electrode driving substrate for applying the discharge pulse to the scan electrodes and the scan electrodes, the both ends being connected to the scan electrode driving substrate and the scan electrodes, respectively. And scan side connection members each having at least one scan driving integrated circuit mounted on the flexible printed cable and arranged to be spaced apart from each other. The method of claim 1, The driving electrode for the scan electrode provided in the circuit unit may include a power supply board that receives power from an external source and converts the power into a power of a required type, and generates a drive control signal by performing a logical operation on an image signal connected to the power supply board and supplied from the outside. And a logic substrate connected thereto. The method of claim 2, And the discharge electrodes are applied to the common electrodes and the address electrodes by a common electrode driving substrate and an address electrode driving substrate connected to a power substrate and a logic substrate in the circuit unit, respectively. The method of claim 3, wherein The common electrodes and the driving substrate for the common electrode are electrically connected by common side connecting members, and the address electrodes and the address electrode driving substrate are electrically connected by the address side connecting members. Plasma display device. The method of claim 4, wherein The address side connecting member includes a flexible printed cable having both ends connected to the address electrode driving substrate and the address electrodes, and at least one address driving integrated circuit mounted on the flexible printed cable. Device. The method of claim 1, And a scan driving integrated circuit provided in the scan side connecting member is covered by a cover member. The method of claim 6, And a groove in which the inner side of the cover member is closed to accommodate the scan driving integrated circuit. The method of claim 7, wherein And a first thermally conductive medium disposed between the groove formed in the cover member and the scan driving integrated circuit. The method of claim 8, The first thermal conductive medium is a plasma display device, characterized in that the liquid or gel-type thermal conductive medium. The method of claim 1, And a bent portion formed to be bent backwards at an edge of the chassis base, wherein the scan driving integrated circuit is disposed to support the bent portion. The method of claim 10, And a second thermal conductive medium disposed in the bent portion of the chassis base to correspond to the scan driving integrated circuit.

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